Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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Zebrafish Retina Electrode Recommendation |
For Larval Zebrafish Retina (which is quite small, 10microns) it may not be possible to inject DNA buffer.  Accordingly, we suggest that electroporation is performed after the larval zebrafish eye is taken out. Once this is done and one intends… |
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Zebrafish Fin Electrode Recommendation |
… |
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Cancer Therapy & CUY21 |
The CUY21 EDIT and CUY21 SC electroporator range has been used to perform electro-chemotherapy on human skin cancer as a clinical test. Kindly note the article: ‘Electrochemotherapy for digital chondrosarcoma’. In this article, bleomycine is introduced… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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Zebrafish Brain Electrode Recommendation |
… |
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Zebrafish Fin Electrode Recommendation |
… |
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Zebrafish Retina |
For Larval Zebrafish Retina (which is quite small, 10microns) it may not be possible to inject DNA buffer.  Accordingly, we suggest that electroporation is performed after the larval zebrafish eye is taken out. Once this is done and one intends… |
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In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
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Xenopus Tadpole - Tail |
Kindly note that the article titled: ‘Matrix metalloproteinase expression and function during fin regeneration in zebrafish: Analysis of MT1-MMP, MMP2 and TIMP2*.' This article cites the use of the CUY21EDIT electroporator and the CUY650P3 electrode… |
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Mouse Embryo – Entire Brain |
… |
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Mouse/Rat Adult – Brain (Cerebellum) |
Alternatively, one could use the CUY567 electrode. It too is a needle electrodes but it cannot be used to inject plasmid. Accordingly, one must first inject genes into the brain and then insert the needle electrodes into the target where the plasmid… |
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Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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Mouse Embryo – Entire Brain |
… |
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Mouse/Rat – Knee Joint |
… |
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Mouse/Rat – Knee Joint |
… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
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Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
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Technical Drawing: CUY650 series |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse Embryo – Eye |
… |
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Technical Drawing: CUY650 series |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Technical Drawing CUY650P0.5 |
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Technical Drawing CUY650P1 |
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Electroporation Protocol; Technical Drawing of CUY651, CUY650P1, P3, CUY650-5, P5, 7, P7 Electrodes and Mouth-controlled Micropipette System Photo |
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Technical Drawing CUY650P3 |
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Technical Drawing: CUY650P Series |
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Technical Drawing: CUY650P7 |
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Technical Drawing: CUY650 series |
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Technical Drawing: CUY650P10 |
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Technical Drawing: CUY650P5 |
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Technical Drawing: CUY650-5 & CUY650-10 |
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Technical Drawing: CUY650P5 |
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Adult Mouse and Rat (In vivo) - Kidney |
For Adult Mouse and Rat (in vivo) Kidney applications we recommend:
CUY650P5
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Technical Drawing: CUY650P5 |
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Photo: CUY650P5 |
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Technical Drawing: CUY650P5 |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (E12.5) |
… |
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Adult Mouse and Rat (In Vivo) - Brain |
For Adult Mouse and Rat (in vivo) Brain applications we recommend the following electrode:
CUY200S
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Adult Mouse and Rat (In vivo) - Knee Cartilage |
For Adult Mouse and Rat (in vivo) Knee Cartilage applications we recommend the following electrode:
CUY650P5 and CUY650P10
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Photo: CUY650P5 |
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Photo CUY650P10 |
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Adult Mouse and Rat (In vivo) - Synovial Membrane |
… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Adult Mouse and Rat (In vivo) - Vessel |
For Adult Mouse and Rat (in vivo) Vessel applications we recommend the following electrode:
CUY250
Â
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Adult Mouse and Rat (In vivo) - Bladder |
For Adult Mouse and Rat (in vivo) Bladder applications we recommend the following electrode:
CUY647P5x10
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (>E13.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, Specific Areas (>E13.5) |
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Photo: CUY650P3 |
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Photo: CUY650P5 |
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Photo: CUY650P7 |
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Mouse Embryo (In Utero) - Cerebral Cortex, Specific Areas (>E13.5) |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
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Photo: CUY650P0.5-3 |
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Photo: CUY650P1-5 |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
… |
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Photo: CUY650P1-5 |
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Mouse Embryo (In Utero) - Spinal Cord (E10.5) |
For Mouse Embryo (in utero) Spinal Cord (E10.5) applications we recommend the following electrode:
CUY651P
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Mouse and Rat (Whole Embryo Culture) - Neural Tube (Mouse E9.5, Rat 11.5) |
For Mouse and Rat (whole embryo culture) Neural Tube (Mouse E9.5, Rat 11.5) applications we recommend the following electrode:
CUY520P15, P20, P25
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Mouse and Rat (Whole Embryo Culture) - Neural Plate Metencephalon, Somite (Mouse E7-13) |
For Mouse and Rat (whole embryo culture) Neural Plate Metencephalon, Somite (Mouse E7-13) applications we recommend the following electrode:
CUY520P15, P20, P25
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Mouse and Rat (Whole Embryo Culture) - Telencephalon (Mouse E7-13) |
For Mouse and Rat (whole embryo culture) Telencephalon (Mouse E7-13) applications we recommend the following electrode:
CUY650P3, CUY650P5 CUY650P10
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Photo: CUY650P3, CUY650P5 |
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Photo: CUY650P10 |
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New Born Mouse and Rat (In Vivo) - Retina (P0-P3) |
For New Born Mouse and Rat (in vivo) - Retina (P0-P3) applications we recommend the following electrode:
CUY675P3 CUY675P5
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New Born Mouse and Rat (In Vivo) - Cornea |
For New Born Mouse and Rat (in vivo) - Cornea applications we recommend the following electrode:
CUY670 CUY671P1
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P0-P3) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P0-P3) applications we recommend the following electrode:
CUY650P3
CUY650P5
See also:
Brain Ventricle (P4-P8)
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Photo: CUY650P3 |
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P4-P8) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P4-P8) applications we recommend the following electrode:
CUY650P7
See also
Brain Ventricle (P0-P3)
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P4-P8) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P4-P8) applications we recommend the following electrode:
CUY650P7
See also
Brain Ventricle (P0-P3)
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Photo: CUY650P5 |
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Photo: CUY650P7 |
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Adult Mouse, Rat, Rabbit and Dog (In Vivo) - Skin (Epidermus, Dermus, Hypodermus) |
For Adult Mouse, Rat, Rabbit and Dog (in vivo) - Skin (Epidermus, Dermus, Hypodermus) applications we recommend the following electrodes:
CUY663 series
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Chick Embryo (Organ Culture) - Digestive Organ Epithelial Cell (HH Stage 3-7) |
For Chick Embryo (organ culture) - Digestive Organ Epithelial Cell (HH Stage 3-7) applications we recommend the following electrode:
CUY520P5
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Chick Embryo (New Culture) - Gastrulation, Neural Plate (HH Stage 3-7) |
For Chick Embryo (new culture) - Gastrulation, Neural Plate (HH Stage 3-7) applications we recommend the following electrodes:
CUY701 seris (pair)
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Chick and Quail Embryo (in ovo) - Neural Tube, Mesencephalon, Diencephalon (HH* Stage 10 |
Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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Bee (In Vivo) |
For Bee (in vivo) - Brain applications we recommend the following electrode:
CUY567
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Silkworm - Egg |
For Silkworm - Egg applications we recommend the following electrode:
CUY495P10
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Xenopus Embryo (In Vivo) - Stage 12.5 |
For Xenopus Embryo (in vivo) - Stage 12.5 applications we recommend the following electrodes:
CUY700P20E, P20L CUY195P0.3
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Fish - Egg |
For Fish - Egg applications we recommend the following electrodes:
CUY535 CUY536 CUY537P0.3, P0.5
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Plant (In Vivo) - Seed Embryo |
For Plant (in vivo) - Seed Embryo applications we recommend the following electrode:
CUY495P10
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Tissue Fragment (Ex Vivo) - Brain Slice |
For Tissue Fragment (ex vivo) - Brain Slice applications we recommend the following electrode:
CUY701 series
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Tissue Fragment (Ex Vivo) - Tissue Slice |
For Tissue Fragment (ex vivo) - Brain Slice applications we recommend the following electrode:
CUY701 series
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Tissue Fragment (Ex Vivo) - Skin Slice |
For Tissue Fragment (ex vivo) - Brain Slice applications we recommend the following electrode:
CUY701 series
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Adult Mouse, Rat, Rabbit, Dog and Monkey (DNA Vaccine) |
… |
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Photo:CUY650P3, P5 |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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Adult Mouse and Rat (In vivo) - Bladder |
For Adult Mouse and Rat (in vivo) Bladder applications we recommend the following electrode:
CUY647P5x10
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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Zebrafish Fin |
… |
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Zebrafish Fin |
… |
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Mouse Embryo – Entire Brain |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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Adult Mouse and Rat (In Vivo) - Brain |
For Adult Mouse and Rat (in vivo) Brain applications we recommend the following electrode:
CUY200S
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Cancer Therapy & CUY21 |
The CUY21 EDIT and CUY21 SC electroporator range has been used to perform electro-chemotherapy on human skin cancer as a clinical test. Kindly note the article: ‘Electrochemotherapy for digital chondrosarcoma’. In this article, bleomycine is introduced… |
|
Cancer Therapy & CUY21 |
The CUY21 has also been used to perform electroporation on hepatocellular carcinoma (HCC). Kindly note the paper titled: ‘Electroporation-mediated Interleukin-12 Gene Therapy for Hepatocellular carcinoma in Mice Models'. In this paper, genes which… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
|
Cancer Therapy & CUY21 |
The CUY21 has also been used to perform electroporation on hepatocellular carcinoma (HCC). Kindly note the paper titled: ‘Electroporation-mediated Interleukin-12 Gene Therapy for Hepatocellular carcinoma in Mice Models'. In this paper, genes which… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
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Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
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Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
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Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
IntroductionSonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
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Cancer Therapy & CUY21 |
The CUY21 has also been used to perform electroporation on hepatocellular carcinoma (HCC). Kindly note the paper titled: ‘Electroporation-mediated Interleukin-12 Gene Therapy for Hepatocellular carcinoma in Mice Models'. In this paper, genes which… |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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In Utero Electroporation |
As evident from the review by H Tabata and K Nakajima in their book ‘Electroporation and Sonoporation in Developmental Biology’, (Chapter 14, In Utero Electroporation: Assay System for Migration of Cerebral Cortical Neurons, p 143 – 152), the optimal… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
… |
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Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
|
Combined acupuncture and sonoporation for intradermal gene delivery |
Sonoporation or ultrasound-mediated cell membrane permeabilisation is proving to be an effective alternative to viral gene transfer [1].  Because of its non-invasive nature sonoporation also offers a number of advantages over alternative non-viral… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse/Rat – Knee Joint |
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Mouse Embryo – Entire Brain |
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Mouse Embryo – Entire Brain |
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Mouse Embryo – Eye |
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Mouse/Rat – Knee Joint |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Bee (In Vivo) |
For Bee (in vivo) - Brain applications we recommend the following electrode:
CUY567
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Cables for Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Mouse/Rat Adult – Brain (Cerebellum) |
Alternatively, one could use the CUY567 electrode. It too is a needle electrodes but it cannot be used to inject plasmid. Accordingly, one must first inject genes into the brain and then insert the needle electrodes into the target where the plasmid… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21 Publications by Research Interest |
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CUY21 Publications by Research Interest |
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CUY21 Publications by Research Interest |
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CUY21 Publications by Research Interest |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The CUY21SC measures and displays the delivered current immediately after an EP event. This data is crucial to enable the researcher to verify (on the basis of V=IR) that the correct electroporation protocol has been delivered. As the CUY21SC can measure… |
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CUY21SC - Square Wave Electroporator |
The resistance of an EP target varies according to physical experimental factors such as the volume of the sample, the buffer used and the distance between the electrodes. Fluctuations in resistance impact on delivered current values and this negatively… |
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Gene transfer into embryonic brains using in utero electroporation technique |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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Gene transfer into embryonic brains using in utero electroporation technique |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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Gene transfer into embryonic brains using in utero electroporation technique |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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Gene transfer into embryonic brains using in utero electroporation technique |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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Cancer Therapy & CUY21 |
The CUY21 EDIT and CUY21 SC electroporator range has been used to perform electro-chemotherapy on human skin cancer as a clinical test. Kindly note the article: ‘Electrochemotherapy for digital chondrosarcoma’. In this article, bleomycine is introduced… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Cables for Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Cables for Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
C) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
C) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
a) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
a) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
a) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P0-P3) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P0-P3) applications we recommend the following electrode:
CUY650P3
CUY650P5
See also:
Brain Ventricle (P4-P8)
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P0-P3) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P0-P3) applications we recommend the following electrode:
CUY650P3
CUY650P5
See also:
Brain Ventricle (P4-P8)
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P0-P3) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P0-P3) applications we recommend the following electrode:
CUY650P3 CUY650P5
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P4-P8) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P4-P8) applications we recommend the following electrode:
CUY650P7
See also
Brain Ventricle (P0-P3)
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P4-P8) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P4-P8) applications we recommend the following electrode:
CUY650P7
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New Born Mouse and Rat (In Vivo) - Brain Ventricle (P4-P8) |
For New Born Mouse and Rat (in vivo) - Brain Ventricle (P4-P8) applications we recommend the following electrode:
CUY650P7
See also
Brain Ventricle (P0-P3)
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (>E13.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (>E13.5) |
For Mouse Embryo (in utero) Cerebral Cortex, All Areas (>E13.5) applications we recommend the following electrode:
CUY650P5 and CUY650P7
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (>E13.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (E12.5) |
For Mouse Embryo (in utero) Cerebral Cortex, All Areas (E12.5) applications we recommend the following electrode:
CUY650P3
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (E12.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, Specific Areas (>E13.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, Specific Areas (>E13.5) |
For Mouse Embryo (in utero) Cerebral Cortex, Specific Areas (>E13.5) applications we recommend the following electrode:
CUY650P0.5-3 and CUY650P1-5
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Mouse Embryo (In Utero) - Cerebral Cortex, Specific Areas (>E13.5) |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
For Mouse Embryo (in utero) Forebrain Ventricle (E14) applications we recommend the following electrode:
CUY650P1-5
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Zebrafish Brain Electrode Recommendation |
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Zebrafish Brain Electrode Recommendation |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
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NEPA21_In_Vivo_Tumor_EP |
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Mouse Embryo (In Utero) - Forebrain Ventricle (E14) |
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Zebrafish Brain |
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Zebrafish Brain |
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Zebrafish Retina Electrode Recommendation |
For Larval Zebrafish Retina (which is quite small, 10microns) it may not be possible to inject DNA buffer.  Accordingly, we suggest that electroporation is performed after the larval zebrafish eye is taken out. Once this is done and one intends… |
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Zebrafish Retina Electrode Recommendation |
For Larval Zebrafish Retina (which is quite small, 10microns) it may not be possible to inject DNA buffer.  Accordingly, we suggest that electroporation is performed after the larval zebrafish eye is taken out. Once this is done and one intends… |
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Zebrafish Retina Electrode Recommendation |
For Larval Zebrafish Retina (which is quite small, 10microns) it may not be possible to inject DNA buffer.  Accordingly, we suggest that electroporation is performed after the larval zebrafish eye is taken out. Once this is done and one intends… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
The resistance of an EP target varies according to physical experimental factors such as the volume of the sample, the buffer used and the distance between the electrodes. Fluctuations in resistance impact on delivered current values and this negatively… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21SC - Square Wave Electroporator |
Because in vivo impedance (electrical resistance) is generally less stable than in vitro impedance, an accurate measurement of the target sample resistance prior to the electroporation event is the most important critical success factor for accurate… |
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CUY21 Publication List, Electrode Recommendations and Protocol Information |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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Gene transfer into embryonic brains using in utero electroporation technique |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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In vivo gene transfer into the adult honeybee brain by using electroporation |
a) Schematic representation of the micropipette and electrodes placed in the honeybee brain. Purple indicates micropipette filled with DNA solution, blue indicates electrodes. AN, antennae; C, compound eyes; MB, mushroom bodies; Oc, ocelli; OL, optic… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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Adult Mouse, Rat, Rabbit and Dog (In Vivo) - Skin (Epidermus, Dermus, Hypodermus) |
For Adult Mouse, Rat, Rabbit and Dog (in vivo) - Skin (Epidermus, Dermus, Hypodermus) applications we recommend the following electrodes:
CUY663 series
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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NEPA21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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NEP21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
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NEPA21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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NEPA21_Retina_EP |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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NEPA21_Retina_EP |
 Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEP21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
… |
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NEPA21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
|
Connector Cables for CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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NEPA21_In_Vivo_Tumor_EP |
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Electroporation Protocols - In Vitro, In Ovo, In Utero, In Vivo, Ex Vivo and New Culture |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Connector Cables for NEPA21 / CUY21 Electroporator and Electrodes |
If one uses the tweezers-type electrode with the ECM830 the C117 is not required. The C117 is used to hook a needle-type electrode such as the CUY611 series and the CUY613 series. Tweezers-type electrodes such as the CUY650 series have the required… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Mouse Embryo – Eye |
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Mouse Embryo – Eye |
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Mouse Embryo – Eye |
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In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
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Chick and Quail Embryo (in ovo) - Neural Tube, Mesencephalon, Diencephalon (HH* Stage 10 |
Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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Chicken and Quail Embryo (In Ovo) - Neural Tube, Mesencephalon, Diencephalon (HH* Stage 10) |
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Chick and Quail Embryo (in ovo) - Neural Tube, Mesencephalon, Diencephalon (HH* Stage 10 |
Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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Chicken and Quail Embryo (In Ovo) - Neural Tube, Mesencephalon, Diencephalon (HH* Stage 10) |
Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
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Zeebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zeebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zeebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zeebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zeebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryos-E13.5_with_CUY650P5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryos-E13.5_with_CUY650P5 |
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In_Utero-Mouse_Embryos-E13.5_with_CUY650P5 |
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In_Utero-Mouse_Embryos-E13.5_with_CUY650P5 |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (E12.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (E12.5) |
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Mouse Embryo (In Utero) - Cerebral Cortex, All Areas (>E13.5) |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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NEPA21_In_Vivo_Tumor_EP |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
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Mouse/Rat – Muscle |
The first method involves injecting a pair of needle electrodes CUY560-5/-10 into the muscle above skin. Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion… |
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NEPA21_Retina_EP |
 Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
 Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
 Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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|
Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
|
Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
|
Mouse/Rat – Muscle |
Since no surgery is involved, the researcher can easily perform electroporation and do so consecutively in a short period of time. In our opinion, this is the best method. However, as the volume of muscle affects the resistance value, and thus, actual… |
|
Mouse/Rat Adult – Brain (Cerebellum) |
Alternatively, one could use the CUY567 electrode. It too is a needle electrodes but it cannot be used to inject plasmid. Accordingly, one must first inject genes into the brain and then insert the needle electrodes into the target where the plasmid… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
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Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
|
Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
|
Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
|
Mouse/Rat - Skin |
For your further information, some clients prefer to use the CUY650P electrode series for the same application. The CUY650P series is also a tweezers type electrode but it incorporates disk electrodes. With the CUY650P series, skin is picked up and… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Adult Mouse and Rat (In vivo) - Liver |
For Adult Mouse and Rat (in vivo) Liver applications we recommend the following electrode:
CUY650P5
CUY650P10
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Adult Mouse and Rat (In vivo) - Liver |
For Adult Mouse and Rat (in vivo) Liver applications we recommend the following electrode:
CUY650P10
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Adult Mouse and Rat (In vivo) - Liver |
… |
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Adult Mouse and Rat (In vivo) - Liver |
… |
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Adult Mouse and Rat (In vivo) - Liver |
… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
|
Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
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In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
|
In Ovo Electroporation |
Some clients, however, who have to contend with a large number of samples on a daily basis find it difficult to manipulate a pair of electrodes vertically. Such clients prefer to move the pair of electrodes horizontally. The CUY613 series was designed… |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
… |
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In_Utero-Mouse_Embryo-Cortex-Cerebellum- E12.5 |
… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
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Cultured Mouse Embryos and Large Tissue |
For smaller tissue of less than 0.5mm, we do not recommend the CUY520 series. The reason for this is practical; most clients want to minimize the required volume of DNA as much as possible and do not want to waste DNA. For such applications we believe… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
|
Adult Mouse and Rat (In vivo) - Liver |
Zang  et al.Inhibition  of  nuclear  delivery  of  plasmid  DNA  and  transcription  by  interferon  γ: hurdles to be overcome for sustained gene  therapy.Gene  Ther. 2011 Sep;18(9):891-7. doi: 10.1038/gt.2011.35. Epub 2011 Mar 31… |
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Please also note the following links and attached articles for further information on the NEPA21’s In Ovo capacity. (Please note where a reference is made in the resource material to the CUY21 systems (EDIT or SC), the NEPA21 replaces them and can… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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Adult Mouse and Rat (In vivo) - Testis, Ovary |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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In Utero Electrode Recommendation |
… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Zebrafish_Electroporation |
Please note the Zebrafish video referred to above demonstrates the NEPA21 technique used in the article: ‘Direct Delivery of MIF Morpholinos Into the Zebrafish Otocyst by Injection and Electroporation Affects Inner Ear Development (Katie E. Holmes1… |
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Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
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Mouse/Rat – Knee Joint |
… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Mouse_Rat_In_Vivo_Spinal_Cord_Electroporation |
… |
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Intestine-Gut Electroporation |
… |
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Mouse/Rat Adult – Brain (Cerebellum) |
Alternatively, one could use the CUY567 electrode. It too is a needle electrodes but it cannot be used to inject plasmid. Accordingly, one must first inject genes into the brain and then insert the needle electrodes into the target where the plasmid… |
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Mouse/Rat – Knee Joint |
… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
|
NEPA21_Retina_EP |
Arrangement of electrodes for in vivo electroporation for RPE transfection.(A) Tweezer-type electrodes were placed on the corneal surface of either eye of a 1-month-old Sprague-Dawley rat.(B) The current was applied with the positive electrode contralateral… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
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NEPA21_In-Vivo_EP-Cerebellum-Pups_between_3-8_days_old |
… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
High-performance and reliable site-directed in vivo genetic manipulation of mouse and rat brain by in utero electroporation with a triple-electrode probe, Joanna Szczurkowska, Andrzej W. Cwetsch, Marco dal Maschio, Diego Ghezzi, Gian Michele… |
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Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700P_L type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700PL type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700P_L type-electrodes in combination with the following electrodes… |
|
Postnatal_Cerebellum_EP_with_the_CUY699P7x6 |
However, our preferred and recommended electrode configuration for postnatal cerebellum electroporation does not combine three electrodes in an awkward single unit but instead uses our CUY700P_L type-electrodes in combination with the following electrodes… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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Mouse Embryo – Eye |
Rather, our recommendation is for the CUY650P7 electrode. It has a full round electrode that set of paddles and therefore covers a larger area of the target. In addition, this electrode has a much wider application range and can be used, for example… |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
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Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
|
NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 / CUY21 Illustrated Applications |
A 2 cm midline incision is then made in the abdominal wall along the linea alba using a set of forceps and scissors. A piece of sterile gauze with a hole cut in the center is placed over the incision, and one uterine horn is drawn out through the hole… |
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Hints and Tips iGONAD Procedure |
Recent progress in of the CRISPR/Cas9 system has been shown to be an efficient gene-editing technology in various organisms. We recently developed a novel method called Genome-editing via Oviductal Nucleic Acids Delivery (GONAD); a novel in vivo genome… |
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Hints and Tips iGONAD Procedure |
Recent progress in of the CRISPR/Cas9 system has been shown to be an efficient gene-editing technology in various organisms. We recently developed a novel method called Genome-editing via Oviductal Nucleic Acids Delivery (GONAD); a novel in vivo genome… |
|
Hints and Tips iGONAD Procedure |
Recent progress in of the CRISPR/Cas9 system has been shown to be an efficient gene-editing technology in various organisms. We recently developed a novel method called Genome-editing via Oviductal Nucleic Acids Delivery (GONAD); a novel in vivo genome… |
|
NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
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NEPA21 Publications |
Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan Touboul, Olivier Pourqui… |
|
NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
NEPA21_Retina_EP |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
For your information:With respect to gene delivery into Mouse Embryo Eye (and Brain) one can use the tungsten needle type electrode. However, as the mouse embryo is very small it is often hard to inject DNA into the embryo's eye.Some clients have reported… |
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Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
Mouse Embryo – Eye |
(B) The current was applied with the positive electrode contralateral to the injected eye. After prior injection of plasmid DNA into the subretinal space of the right eye, this arrangement electrophoresed the negatively-charged DNA toward the RPE layer… |
|
NEPA21 Publications |
bioRxiv February 25, 2020Margarete Diaz-Cuadros, Daniel E Wagner, Christoph Budjan, Alexis Hubaud, Oscar A Tarazona, Sophia Donelly, Arthur Michaut, Ziad Al Tanoury, Kumiko Yoshioka-Kobayashi, Yusuke Niino, Ryoichiro Kageyama, Atsushi Miyawaki, Jonathan… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publications |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publications |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publications |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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Test line spacing |
… |
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Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Test line spacing |
… |
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Test line spacing |
- The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are electroporated… |
|
Test line spacing |
- The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are electroporated… |
|
Test line spacing |
-Â Â Â Â The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are… |
|
Test line spacing |
-Â Â Â Â The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are… |
|
Test line spacing |
The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are electroporated… |
|
Test line spacing |
The finer control over the delivered energy available with the NEPA21 offers specific and important advantages for organoid electroporation. As the thrust of NEPA21 protocols is to minimise delivered energy, this means that the targets are electroporated… |
|
Test line spacing |
… |
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Test line spacing |
… |
|
Test line spacing |
… |
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Test line spacing |
… |
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Test line spacing |
… |
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Test line spacing |
… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
Organoid Electroporation Email |
With this market-leading control and (user-independent) reproducibility of the technique, it is now possible to apply electroporation techniques to applications previously considered too sensitive for electroporation methodologies. One such application… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publications |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug plasmid DNA linearized in 1.5 uL TE buffer, and 30.5 uL C medium… |
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ELEP021 Square Wave Electroporation |
The efficiency of transformation is not very high; the average transformation efficiency following selection in 0.3 μgml-1 phleomycin was 5.5 9 10-6 cells or 0.03 transformants μg–1 DNA (Abe et al., 2011). Therefore, many cells must be prepared… |
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ELEP021 Square Wave Electroporation |
The efficiency of transformation is not very high; the average transformation efficiency following selection in 0.3 μgml-1 phleomycin was 5.5 9 10-6 cells or 0.03 transformants μg–1 DNA (Abe et al., 2011). Therefore, many cells must be prepared… |
|
ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials)                                        1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEPO21 Results |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
Materials :                    1.5 ug plasmid DNA linearized (The total volume is 40uL/2mm gap cuvettes: 8 uL Opti-MEM, 1.5 ug                                     … |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
|
ELEPO21 Results |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEPO21 Results |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
|
ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
|
NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publication List |
Stem Cells Transl Med. 2021 Jan;10(1):115-127.Takafumi Yumoto, Misaki Kimura, Ryota Nagatomo, Tsukika Sato, Shun Utsunomiya, Natsue Aoki, Motoji Kitaura, Koji Takahashi, Hiroshi Takemoto, Hirotaka Watanabe, Hideyuki Okano, Fumiaki Yoshida, Yosuke Nao… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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NEPA21 Publication List |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Pub new |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
|
Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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Test spacing |
Peter Gee, Mandy S Y Lung, Yuya Okuzaki, Noriko Sasakawa, Takahiro Iguchi, Yukimasa Makita, Hiroyuki Hozumi, Yasutomo Miura, Lucy F Yang, Mio Iwasaki, Xiou H Wang, Matthew A Waller, Nanako Shirai, Yasuko O Abe, Yoko Fujita, Kei Watanabe, Akihiro Kagita… |
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ELEP021 Square Wave Electroporation |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
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ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
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ELEPO21 Publications |
Kotaro Kiga, Xin-Ee Tan, Rodrigo Ibarra-Chávez, Shinya Watanabe, Yoshifumi Aiba, Yusuke Sato'o, Feng-Yu Li, Teppei Sasahara, Bintao Cui, Moriyuki Kawauchi, Tanit Boonsiri, Kanate Thitiananpakorn, Yusuke Taki, Aa Haeruman Azam, Masato Suzuki, José R… |
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ELEPO21 Results |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
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ELEPO21 Results |
With particle bombardment, the transformants are often contaminated by bacteria and/or fungi, making it necessary to wash and isolate single cells using glass capillaries under a microscope (Pringsheim, 1946). This operation sometimes results in additional… |
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