English
 NBRP Rat No: 0299 系統名 :    LEW-Tg(Gt(ROSA)26Sor-luc)11Jmsk 通称: LEW-<i>Tg(Rosa-luc)11Jmsk</i>,&nbsp;Luc11
 研究責任者:   小林英司
 所属機関名:  自治医科大学分子病態治療研究センター臓器置換研究部
  住所:   〒329-0498 

 栃木県 栃木県下野市薬師寺3311-1

  日本
 電話番号:  0285-58-7446  Fax: 0285-44-5365  eijikoba@jichi.ac.jp
 近交世代数:  F11(March 2012) 
   
 毛色:  
 保存状況:
 
 
  胚           精子          生体
  利用条件:  利用者は、研究成果の公表にあたって寄託者の指定する文献を引用する。 
 分類:   Inbred   Segregating   Congenic   Consomic    Recombinant 
  Coisogenic   Spont. Mutant    Transgene   Ind. Mutant    その他  
  コマーシャルブリーダー:   
 研究分野:   糖尿病・肥満    脳神経疾患   眼疾患    歯科疾患   循環器系疾患・高血圧
  がん・腫瘍   代謝、内分泌    耳鼻疾患   発生   感染症
   骨形態異常   消化器疾患   皮膚疾患    生殖器疾患   免疫・アレルギー疾患
   行動・学習   血液疾患   泌尿器疾患   薬理学   その他  
  対照動物   レポーター遺伝子動物  
 遺伝子: luc: luciferase, firefly
 由来: 自治医大で作製。
Tgラット作製には日本チャールス・リバーで購入したLEW(RT1l)を使用。 
 特性など:
遺伝子組換え生物
gene trap ROSA 26プロモーターの制御下で、全身性にLuciferaseを発現する。 
繁殖・維持方法: 繁殖成績良好。 
 遺伝診断法: 遺伝診断プロトコール Luc 
  参考文献: Hlad&#237;kov&#225; Z, Voglova B, P&#225;t&#237;kov&#225; A, Berkova Z, K&#345;&#237;&#382; J, Vojt&#237;&#353;kov A, Leontovyc I, Jir&#225;k D, Saudek F.
Bioluminescence Imaging In Vivo Confirms the Viability of Pancreatic Islets Transplanted into the Greater Omentum.
Mol Imaging Biol. 2021 Oct;23(5):639-649.

Galisova A, Herynek V, Swider E, Sticova E, P&#225;tikova A, Kosinova L, Kriz J, Hajek M, Srinivas M, Jirak D.
A Trimodal Imaging Platform for Tracking Viable Transplanted Pancreatic Islets In Vivo: F-19 MR, Fluorescence, and Bioluminescence Imaging.
Mol Imaging Biol. 2019 Jun;21(3):454-464.

Herynek V, Turnovcova K, Galisova A, Kaman O, Marekova D, Koktan J, Vosmanska M, Kosinova L, Jendelova P.
Manganese-Zinc Ferrites: Safe and Efficient Nanolabels for Cell Imaging and Tracking In Vivo.
ChemistryOpen. 2019 Jan 23;8(2):155-165.

G&aacute;lisov&aacute; A, F&aacute;bryov&aacute; E, Sticov&aacute; E, Kosinov&aacute; L, Jir&aacute;tov&aacute; M, Herynek V, Berkov&aacute; Z, K&#345;&iacute;&#382; J, H&aacute;jek M, Jir&aacute;k D.
The Optimal Timing for Pancreatic Islet Transplantation into Subcutaneous Scaffolds Assessed by Multimodal Imaging.
Contrast Media Mol Imaging. 2017 Dec 26;2017:5418495

G&aacute;lisov&aacute; A, F&aacute;bryov&aacute; E, Jir&aacute;k D, Sticov&aacute; E, Lodererov&aacute; A, Herynek V, K&#345;&iacute;&#382; J, H&aacute;jek M.
Multimodal Imaging Reveals Improvement of Blood Supply to an Artificial Cell Transplant Site Induced by Bioluminescent Mesenchymal Stem Cells.
Mol Imaging Biol. 2017 Feb;19(1):15-23.

Nakabayashi A, Kamei N, Sunagawa T, Suzuki O, Ohkawa S, Kodama A, Kamei G, Ochi M.
In vivo bioluminescence imaging of magnetically targeted bone marrow-derived mesenchymal stem cells in skeletal muscle injury model.
J Orthop Res.&nbsp;2013 May;31(5):754-9.

Kodama A, Kamei N, Kamei G, Kongcharoensombat W, Ohkawa S, Nakabayashi A, Ochi M.
In vivo bioluminescence imaging of transplanted bone marrow mesenchymal stromal cells using a magnetic delivery system in a rat fracture model.
J Bone Joint Surg Br. 2012 Jul;94(7):998-1006.

Hata T, Iwasaki J, Hishikawa S, Fujimoto Y, Uemoto S, Kobayashi E.
Development of a portocaval shunt using a small intestinal segment in rats.
Microsurgery. 2010 May;30(4):302-6.

Iwasaki J, Hata T, Hishikawa S, Fujimoto Y, Uemoto S, Murakami T, Kobayashi E.
Use of rat segmental intestine for fetal pancreatic transplantation.
Microsurgery. 2010 May;30(4):296-301.

Hakamata Y, Murakami T, Kobayashi E.
"Firefly rats" as an organ/cellular source for long-term in vivo bioluminescent imaging.
Transplantation. 2006 Apr 27;81(8):1179-84. 
 追加の系統情報:  LEW