标签归档:dbco

荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO] 货号2070-AAT Bioquest荧光染料

发表于

上海金畔生物科技有限公司代理AAT Bioquest荧光染料全线产品,欢迎访问AAT Bioquest荧光染料官网了解更多信息。

荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO]

荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO]

荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO] 货号2070 货号 2070 存储条件 在零下15度以下保存, 避免光照
规格 1 mg 价格 3612
Ex (nm) Em (nm)
分子量 1158.49 溶剂 DMSO
产品详细介绍

简要概述

产品基本信息

货号:2070

产品名称:荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO]

规格:1mg

储存条件:-15℃避光防潮

保质期:12个月

 

产品物理化学光谱特性

分子量:1158.49

外观:固体

溶剂:DMSO

 

产品介绍

TQ4WS 是一种优于 ROX、TF4、iFluor 594、Alexa Fluor® 594 和 Texas Red® 的淬灭剂。 TQ4WS 具有 (a)更强的吸收; (b)更高的淬火效率;(c)具有所需溶解度的多功能反应形式,用于标记寡核苷酸和肽。这种 TQ4WS-DBCO 产品在无铜条件下与叠氮化物发生反应,可用于点击化学。 DBCO 可能是菌株促进的炔-叠氮化物环加成 (SPAAC) 中最常见的炔烃,也称为无铜点击反应。环辛炔和叠氮化物仅能有效地相互反应,同时对天然存在的官能团(如胺)保持惰性。 SPAAC 通过形成稳定的三唑,在水性和其他复杂化学环境中无需任何辅助试剂即可标记各种生物分子。 DBCO(二苯并环辛炔)化合物包含一类在水性缓冲液中具有相当快的动力学和良好稳定性的试剂。在生理温度和 pH 范围内,DBCO 基团不会与许多生物分子中天然存在的胺或羟基反应。此外,DBCO 基团与叠氮化物基团的反应明显快于与巯基(-SH,硫醇)的反应。金畔生物是AAT Bioquest的中国代理商,为您提供最优质的荧光淬灭剂。 

点击查看光谱

 

参考文献

A copper-free and enzyme-free click chemistry-mediated single quantum dot nanosensor for accurate detection of microRNAs in cancer cells and tissues.
Authors: Wang, Zi-Yue and Li, Dong-Ling and Tian, Xiaorui and Zhang, Chun-Yang
Journal: Chemical science (2021): 10426-10435

CEBA: A new heterobifunctional reagent for plasmid DNA functionalization by click chemistry.
Authors: Gao, Haifei and Gonçalves, Cristine and Maze, Delphine and Pichon, Chantal and Midoux, Patrick
Journal: International journal of pharmaceutics (2021): 120566

Cancer cell-targeted cisplatin prodrug delivery in vivo via metabolic labeling and bioorthogonal click reaction.
Authors: Liu, Xun and Wu, Fan and Cai, Kaimin and Zhao, Ziyin and Zhang, Zhimin and Chen, Yongbing and Liu, Yong and Cheng, Jianjun and Yin, Lichen
Journal: Biomaterials science (2021): 1301-1312

Covalent Cell Surface Conjugation of Nanoparticles by a Combination of Metabolic Labeling and Click Chemistry.
Authors: Lamoot, Alexander and Uvyn, Annemiek and Kasmi, Sabah and De Geest, Bruno G
Journal: Angewandte Chemie (International ed. in English) (2021): 6320-6325

Cytosolic protein delivery via metabolic glycoengineering and bioorthogonal click reactions.
Authors: Zhao, Ziyin and Zhang, Zhimin and Duan, Shanzhou and Liu, Xun and Zhou, Renxiang and Hou, Mengying and Sang, Yonghua and Zhu, Rongying and Yin, Lichen
Journal: Biomaterials science (2021): 4639-4647

Development of a Cancer Vaccine Using In Vivo Click-Chemistry-Mediated Active Lymph Node Accumulation for Improved Immunotherapy.
Authors: Qin, Hao and Zhao, Ruifang and Qin, Yuting and Zhu, Jin and Chen, Long and Di, Chunzhi and Han, Xuexiang and Cheng, Keman and Zhang, Yinlong and Zhao, Ying and Shi, Jian and Anderson, Gregory J and Zhao, Yuliang and Nie, Guangjun
Journal: Advanced materials (Deerfield Beach, Fla.) (2021): e2006007

In vivo vocal fold augmentation using an injectable polyethylene glycol hydrogel based on click chemistry.
Authors: Kwon, Soonmin and Choi, Hyunsu and Park, Changhee and Choi, Sangkee and Kim, Eunha and Kim, Sung Won and Kim, Choung-Soo and Koo, Heebeom
Journal: Biomaterials science (2021): 108-115

Interventional nuclear medicine: “click” chemistry as an in vivo targeting strategy for imaging microspheres and bacteria.
Authors: Welling, M M and Duszenko, N and van Willigen, D M and Hensbergen, A W and Buckle, T and Rietbergen, D D D and Roestenberg, M and van Leeuwen, F W B
Journal: Biomaterials science (2021): 1683-1690

Liposome Click Membrane Permeability Assay for Identifying Permeable Peptides.
Authors: Desai, Tanvi J and Habulihaz, Bahanu and Cannon, Joe R and Chandramohan, Arun and Kaan, Hung Yi Kristal and Sadruddin, Ahmad and Yuen, Tsz Ying and Johannes, Charles and Thean, Dawn and Brown, Chris J and Lane, David P and Partridge, Anthony W and Evers, Raymond and Sawyer, Tomi K and Hochman, Jerome
Journal: Pharmaceutical research (2021): 843-850

Understanding selectivity of metabolic labelling and click-targeting in multicellular environments as a route to tissue selective drug delivery.
Authors: Tan, Angel and Liu, Qingtao and Septiadi, Dedy and Chu, Shuiling and Liu, Tianqing and Richards, Sarah-Jane and Rothen-Rutishauser, Barbara and Petri-Fink, Alke and Gibson, Matthew I and Boyd, Ben J
Journal: Journal of materials chemistry. B (2021): 5365-5373

说明书
荧光淬灭剂Tide Quencher 4WS-DBCO [TQ4WS-DBCO].pdf

trFluor™Eu DBCO 货号1446-AAT Bioquest荧光染料

发表于

上海金畔生物科技有限公司代理AAT Bioquest荧光染料全线产品,欢迎访问AAT Bioquest荧光染料官网了解更多信息。

trFluor™Eu DBCO

trFluor™Eu DBCO

trFluor™Eu DBCO 货号1446 货号 1446 存储条件 在零下15度以下保存, 避免光照
规格 100 ug 价格 3732
Ex (nm) 346 Em (nm) 617
分子量 1765.72 溶剂 DMSO
产品详细介绍

简要概述

产品基本信息

货号:1446

产品名称:trFluor™Eu DBCO

规格:100ug

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:1765.72

外观:固体

溶剂:DMSO

激发波长(nm):346

发射波长(nm):617

 

产品介绍

存在于细胞,血清或其他生物流体中的许多生物化合物都是天然荧光的,因此,由于要测定的生物分子的自发荧光引起的高背景,使用常规的快速荧光团会严重限制测定灵敏度。长寿命荧光团与时间分辨检测(激发和发射检测之间的延迟)的结合使用可最大程度地减少即时荧光干扰。我们的trFluor™Eu探针可用于需要高灵敏度测定的时间分辨荧光(TRF)。与诸如Alexa Fluor或花青染料等更传统的荧光团相比,这些trFluor™Eu探针具有较大的斯托克斯位移和极长的发射半衰期。与其他TRF化合物相比,我们的trFluor™Eu探针具有相对较高的稳定性,高发射率和与生物分子连接的能力。此外,当与生物聚合物(例如抗体)偶联时,我们的trFluor™Eu探针对荧光猝灭不敏感。在无铜条件下,trFluor™Eu DBCO可以容易地单击成含有叠氮基的分子。金畔生物是AAT Bioquest的中国代理商,为您提供最优质的trFluor™I DBCO。 

点击查看光谱

 

参考文献

Comparative Analysis of High-Throughput Assays of Family-1 Plant Glycosyltransferases.
Authors: McGraphery, Kate and Schwab, Wilfried
Journal: International journal of molecular sciences (2020)

Discovery and Characterization of Peptide Inhibitors for Calcium and Integrin Binding Protein 1.
Authors: Puhl, Ana C and Bogart, Jonathan W and Haberman, Victoria A and Larson, Jacob E and Godoy, Andre S and Norris-Drouin, Jacqueline L and Cholensky, Stephanie H and Leisner, Tina M and Frye, Stephen V and Parise, Leslie V and Bowers, Albert A and Pearce, Kenneth H
Journal: ACS chemical biology (2020)

Integrating Ligand and Target-Driven Based Virtual Screening Approaches With in vitro Human Cell Line Models and Time-Resolved Fluorescence Resonance Energy Transfer Assay to Identify Novel Hit Compounds Against BCL-2.
Authors: Tutumlu, Gurbet and Dogan, Berna and Avsar, Timucin and Orhan, Muge Didem and Calis, Seyma and Durdagi, Serdar
Journal: Frontiers in chemistry (2020): 167

Revisit ligand-receptor interaction at the human vasopressin V2 receptor: A kinetic perspective.
Authors: Liu, Chunji and Xia, Leyi and Fu, Kequan and Cao, Xudong and Yan, Wenzhong and Cheng, Jianjun and Roux, Thomas and Peletier, Lambertus A and Yin, Xiaoxing and Guo, Dong
Journal: European journal of pharmacology (2020): 173157

A General TR-FRET Assay Platform for High-Throughput Screening and Characterizing Inhibitors of Methyl-Lysine Reader Proteins.
Authors: Rectenwald, Justin M and Hardy, P Brian and Norris-Drouin, Jacqueline L and Cholensky, Stephanie H and James, Lindsey I and Frye, Stephen V and Pearce, Kenneth H
Journal: SLAS discovery : advancing life sciences R & D (2019): 693-700

A high-throughput screen of pharmacologically active compounds for inhibitors of UHRF1 reveals epigenetic activity of anthracycline derivative chemotherapeutic drugs.
Authors: Giovinazzo, Hugh and Walker, David and Wyhs, Nicolas and Liu, Jianyong and Esopi, David M and Vaghasia, Ajay M and Jain, Yash and Bhamidipati, Akshay and Zhou, Jianya and Nelson, William G and Yegnasubramanian, Srinivasan
Journal: Oncotarget (2019): 3040-3050

Development of a High-Throughput Cul3-Keap1 Time-Resolved Fluorescence Resonance Energy Transfer (TR-FRET) Assay for Identifying Nrf2 Activators.
Authors: Poore, Derek D and Hofmann, Glenn and Wolfe, Lawrence A and Qi, Hongwei and Jiang, Ming and Fischer, Michael and Wu, Zining and Sweitzer, Thomas D and Chakravorty, Subhas and Donovan, Brian and Li, Hu
Journal: SLAS discovery : advancing life sciences R & D (2019): 175-189

LFRET, a novel rapid assay for anti-tissue transglutaminase antibody detection.
Authors: Rusanen, Juuso and Toivonen, Anne and Hepojoki, Jussi and Hepojoki, Satu and Arikoski, Pekka and Heikkinen, Markku and Vaarala, Outi and Ilonen, Jorma and Hedman, Klaus
Journal: PloS one (2019): e0225851

Quantitative high-throughput screening assays for the discovery and development of SIRPα-CD47 interaction inhibitors.
Authors: Miller, Thomas W and Amason, Joshua D and Garcin, Elsa D and Lamy, Laurence and Dranchak, Patricia K and Macarthur, Ryan and Braisted, John and Rubin, Jeffrey S and Burgess, Teresa L and Farrell, Catherine L and Roberts, David D and Inglese, James
Journal: PloS one (2019): e0218897

Development of a Broadly Applicable Assay for Measurement of Glycan-Directed Enzymatic Activity.
Authors: Bresciani, Alberto and Cecchetti, Ottavia and Missineo, Antonino and Pacifici, Pier Giorgio and Tomei, Licia and Rodems, Steven
Journal: SLAS discovery : advancing life sciences R & D (2018): 941-950

说明书
trFluor™Eu DBCO.pdf