|
Search by product code, name or application:
|
|
|
Search for the most appropriate electrode by research application:
|
|
Product Code: SONIDEL MB101
| | Desc: | Microbubble for Ultrasound-mediated Transfection |
| Applic: | Sonoporation Aid |
|
|
Product Code: CUY5000P0.5
|
Application:
Electrodes for Electro Cell Fusion |
Description:
Platinum wire electrodes on petridish, 0.5mm gap |
|
|
» » »
|
 |
| 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 |
| 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… | | |
| 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… | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 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… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (A) EGFP-expression vector was electroporated into E11.5 rat telencephalon. The electroporated embryo was cultured in the whole embryo culture system (WEC). (B) 24 hours after electroporation, EGFP-expression was specifically detected at the dorsal part… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (A) EGFP-expression vector was electroporated into E11.5 rat telencephalon. The electroporated embryo was cultured in the whole embryo culture system (WEC). (B) 24 hours after electroporation, EGFP-expression was specifically detected at the dorsal part… | | |
| Chick embryo Electroporation using News culture gastrula |
| GFP gene was introduced to the prospective neural plate at HH4, and the embryo was cultured for about 34 hours (HH17 equivalent). GFP expression was occasionally monitored under a fluorescent dissecting microscope. GFP fluorescence was detectable as… | | |
| Chick embryo Electroporation using News culture gastrula |
| GFP gene was introduced to the prospective neural plate at HH4, and the embryo was cultured for about 34 hours (HH17 equivalent). GFP expression was occasionally monitored under a fluorescent dissecting microscope. GFP fluorescence was detectable as… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| Direct Gene Transfer into Mature Seeds via Electroporation |
| Fertile transgenic plants were regenerated and self-fertilized seeds were obtained in rice and wheat. Transgene integration was confirmed by Southern hybridization. Transmission of the transgene into the next generation (T1) was indicated by PCR analysis… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| … | | |
| ag teacht abhaile200219992*s |
| We are developing a technology to monitor protein synthesis in living cells by transfecting them with fluorescent labeled tRNA. This is planned for commercialization during 2011. We are currently using several of the popular, commercially available reagents… | | |
| ag teacht abhaile200219992*s |
| We are developing a technology to monitor protein synthesis in living cells by transfecting them with fluorescent labeled tRNA. This is planned for commercialization during 2011. We are currently using several of the popular, commercially available reagents… | | |
| ag teacht abhaile200219992*s |
| We are developing a technology to monitor protein synthesis in living cells by transfecting them with fluorescent labeled tRNA. This is planned for commercialization during 2011. We are currently using several of the popular, commercially available reagents… | | |
| ag teacht abhaile200219992*s |
| We are developing a technology to monitor protein synthesis in living cells by transfecting them with fluorescent labeled tRNA. This is planned for commercialization during 2011. We are currently using several of the popular, commercially available reagents… | | |
| 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… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (A) EGFP-expression vector was electroporated into E11.5 rat telencephalon. The electroporated embryo was cultured in the whole embryo culture system (WEC). (B) 24 hours after electroporation, EGFP-expression was specifically detected at the dorsal part… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Electroporation for mammalian embryos in the whole embryo culture system |
| (B-E) Time-lapse analysis of neuroepithelial cells in the slice culture system. Histon-EGFP- and DsRed2-expression vectors were co-electroporated into the E12.0 rat spinal cord. The electroporated embryo was cultured for 24 hours in the WEC, then the… | | |
| Photo comparison of NEPA21 with CUY21EDIT |
| … | | |
| Photo comparison of NEPA21 with CUY21EDIT |
| … | | |
| Photo comparison of NEPA21 with CUY21EDIT |
| … | | |
| Photo comparison of NEPA21 with CUY21EDIT |
| … | | |
| 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… | | |
| NEP21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
| … | | |
| 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… | | |
| 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… | | |
| NEP21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| Heat-induced expansion of liquid in a sealed capillary generates high pressure, which enables injection by capillaries with the tip diameter around 0.1μm (Knoblauch et al., Nature Biotech., 1999). As the heat source, we chose a laser beam which enables… | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| Heat-induced expansion of liquid in a sealed capillary generates high pressure, which enables injection by capillaries with the tip diameter around 0.1μm (Knoblauch et al., Nature Biotech., 1999). As the heat source, we chose a laser beam which enables… | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| New Products |
| New Products
Please note the following New Products brought to you by SONIDEL Limited
| | |
| New Products |
| … | | |
| New Products |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| NEPA21, CUY21SC and CUY21EDIT Multiple Applications and Electrode Recommendations |
| … | | |
| 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… | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| NSSB Mechanical Vitrabtion Instruments |
| … | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
|
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| In a test tube spontaneous fusing of two different somatic cells occurs less than 1 in 1,000,000 times. Though this is good if you are a living organism, it is sometimes desirable to fuse cells for specialized applications. Historically, a chemical… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive AC and… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Somatic cell fusion is an involved technique traditionally used for making hybridomas for monoclonal antibodies. This technique fuses an immortal myleloma cell line with a spleen-derived antibody-producing B-cell. The hybridoma cell line produced will… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Somatic cell fusion is an involved technique traditionally used for making hybridomas for monoclonal antibodies. This technique fuses an immortal myleloma cell line with a spleen-derived antibody-producing B-cell. The hybridoma cell line produced will… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Additionally, inactivated viruses have been used for the same effect . More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive AC and… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive AC and… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining successive… | | |
| ECFG21 Super Electro-Cell Fusion Generator |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies combining… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently, methodologies… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently,… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21 Super Electro-Cell Fusion Generator for hybridoma production and nuclear transfer |
| Traditionally, a chemical method such as PEG has been used to fuse cells together (to an equivalent 2 or 3 orders of magnitude). Â Inactivated viruses have also been used for the same effect. More recently… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (Nepa Gene, Japan) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (Nepa Gene, Japan), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer was composed… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer was composed… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| ECFG21-LF201-LF101 Illustrated Applications |
| Electrofusion was performed using the ECFG21 and LF201 Electro Cell Fusion Generator (SONIDEL/Nepa Gene) and the CUY497P2 MS Stand Model Chamber Type Platinum Electrode, L80mm x W2mm x H5mm, 0.8ml (SONIDEL/Nepa Gene), (Fig. 1). The electrofusion buffer… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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 |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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_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_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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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_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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 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 |
| 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 |
| 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 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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… | | |
| 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 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… | | |
| LTM-1000 : Laser Thermal Microinjector |
| … | | |
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 |
|
 |
|
|