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iFluor 790酸

英文名称:iFluor® 790 acid
产品参数
Ex (nm)787Em (nm)812
分子量1347.45溶剂DMSO
存储条件在零下15度以下保存, 避免光照
产品概述

产品基本信息

产品名称:iFluor 790酸

储存条件:-15℃避光防潮

保质期:24个月

 

产品物理化学光谱特性

分子量:1279.29

溶剂:DMSO

激发波长(nm):787

发射波长(nm):812

 

产品介绍

我们的iFluor 790旨在通过近红外荧光标记蛋白质和其他生物分子。用iFluor 790制备的缀合物具有与吲哚菁绿(ICG)和IRDye®800染料相似的激发和发射光谱,大激发/发射光谱为783/814 nm。 iFluor 790染料的发射与常用的远红色荧光团(例如Cy5,Cy7或别藻蓝蛋白(APC))分离良好,从而促进了多色分析。该荧光团还可用于小型动物体内成像应用或需要近红外检测的其他成像应用,例如使用LI-COR®Odyssey®红外成像系统的双色应用。

点击查看光谱

 

适用仪器

荧光酶标仪  
Ex: 782nm
Em: 811nm
cutoff: 790nm
推荐孔板: 纯黑色孔板

 

试剂应用文献

Lipid nanoparticulate drug delivery system for the treatment of hepatic fibrosis
Authors: Mukherjee, Swarupananda and Dutta, Ayon and Ash, Dipanjana
Journal: Archives of Hepatitis Research (2021): 001--003
 
Lipid-based nanoparticle technologies for liver targeting
Authors: B{\"o}ttger, Roland and Pauli, Griffin and Chao, Po-Han and Fayez, Nojoud AL and Hohenwarter, Lukas and Li, Shyh-Dar
Journal: Advanced drug delivery reviews (2020): 79--101
 
Self-assembly and directed assembly of lipid nanocarriers for prevention of liver fibrosis in obese rats: a comparison with the therapy of bariatric surgery
Authors: Chen, Chun-Han and Chen, Chih-Jung and Elzoghby, Ahmed O and Yeh, Ta-Sen and Fang, Jia-You
Journal: Nanomedicine (2018)
 
Nanovesicle delivery to the liver via retinol binding protein and platelet-derived growth factor receptors: how targeting ligands affect biodistribution
Authors: Hsu, Ching-Yun and Chen, Chun-Han and Aljuffali, Ibrahim A and Dai, You-Shan and Fang, Jia-You
Journal: Nanomedicine (2017)
 

 

参考文献

A target cell-specific activatable fluorescence probe for in vivo molecular imaging of cancer based on a self-quenched avidin-rhodamine conjugate
Authors: Hama Y, Urano Y, Koyama Y, Kamiya M, Bernardo M, Paik RS, Shin IS, Paik CH, Choyke PL, Kobayashi H.
Journal: Cancer Res (2007): 2791
 
Fluorescence imaging in vivo: recent advances
Authors: Rao J, Dragulescu-Andrasi A, Yao H.
Journal: Curr Opin Biotechnol (2007): 17
 
Ex vivo fluorescence imaging of normal and malignant urothelial cells to enhance early diagnosis
Authors: Steenkeste K, Lecart S, Deniset A, Pernot P, Eschwege P, Ferlicot S, Leveque-Fort S, Bri and et R, Fontaine-Aupart MP.
Journal: Photochem Photobiol (2007): 1157
 
In vivo monitoring the fate of Cy5.5-Tat labeled T lymphocytes by quantitative near-infrared fluorescence imaging during acute brain inflammation in a rat model of experimental autoimmune encephalomyelitis
Authors: Berger C, Gremlich HU, Schmidt P, Cannet C, Kneuer R, Hiest and P, Rausch M, Rudin M.
Journal: J Immunol Methods (2007): 65
 
A protocol for imaging alternative splicing regulation in vivo using fluorescence reporters in transgenic mice
Authors: Bonano VI, Oltean S, Garcia-Blanco MA.
Journal: Nat Protoc (2007): 2166
 
In vivo imaging of the bronchial wall microstructure using fibered confocal fluorescence microscopy
Authors: Thiberville L, Moreno-Swirc S, Vercauteren T, Peltier E, Cave C, Bourg Heckly G.
Journal: Am J Respir Crit Care Med (2007): 22
 
In Vivo Fluorescence Microscopic Imaging for Dynamic Quantitative Assessment of Intestinal Mucosa Permeability in Mice
Authors: Szabo A, Vollmar B, Boros M, Menger MD.
Journal: J Surg Res. (2007)
 
In vivo spectral fluorescence imaging of submillimeter peritoneal cancer implants using a lectin-targeted optical agent
Authors: Hama Y, Urano Y, Koyama Y, Kamiya M, Bernardo M, Paik RS, Krishna MC, Choyke PL, Kobayashi H.
Journal: Neoplasia (2006): 607
 
In vivo imaging of green fluorescent protein-expressing cells in transgenic animals using fibred confocal fluorescence microscopy
Authors: Al-Gubory KH, Houdebine LM.
Journal: Eur J Cell Biol (2006): 837
 
In vivo near-infrared fluorescence imaging of integrin alphavbeta3 in an orthotopic glioblastoma model
Authors: Hsu AR, Hou LC, Veeravagu A, Greve JM, Vogel H, Tse V, Chen X.
Journal: Mol Imaging Biol (2006): 315