Streptavidin Agarose Ultra Performance™ provides high biotin binding capacity at a low price. We used our ChromaLink bioconjugation technology to crosslink high activity streptavidin to uniform 35 micron, 6% highly crosslinked agarose. This ideal combination provides a biotin binding capacity of >330 nmol/mL of resin—the highest binding capacity in the industry. The base agarose beads support high flow rates and backpressures, which is ideal for automation in packed cartridges. Use TriLink's Streptavidin Agarose Ultra Performance™ for improved recovery of any biotinylated biomolecule with lower non-specific binding.
|Bead Size||35 µm|
|Loading Capacity||≥ 330 nmol/mL|
|Application||Antibody Labeling, Aptamers, In vitro Diagnostic (IVD), Laboratory Developed Tests (LDT) & Analyte Specific Reagents (ASR), Next-Generation Sequencing (NGS), Photocrosslinking Studies|
SoluLINK Bioconjugation For Research Use Only. Not for use in diagnostic procedures. For additional licensing restrictions, please see the license agreement at trilinkbiotech.com/solulink-research-license.
Products are for research use only, not for use in diagnostic or therapeutic procedures or for use in humans. Products are not for resale without express written permission of Seller. No license under any patent or other intellectual property right of Seller or its licensors is granted or implied by the purchase unless otherwise provided in writing.
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Kowalska, Ewa; Bartnicki, Filip; Fujisawa, Ryo; Bonarek, Piotr; Hermanowicz, Pawel; Tsurimoto, Toshiki; Muszynska, Klaudia; Strzalka, Wojciech . Inhibition of DNA replication by an anti-PCNA aptamer/PCNA complex.
Pusapati, Ganesh V.; Kong, Jennifer H.; Patel, Bhaven B.; Krishnan, Arunkumar; Sagner, Andreas; Kinnebrew, Maia; Briscoe, James; Aravind, L.; Rohatgi, Rajat . CRISPR Screens Uncover Genes that Regulate Target Cell Sensitivity to the Morphogen Sonic Hedgehog.
Zhang, Huixia; Zhang, Chao; Tang, Hong; Gao, Shanshan; Sun, Fang; Yang, Yuan; Zhou, Weiping; Hu, Yu; Ke, Changshu; Wu, Yu; Ding, Zeyang; Guo, Lin; Pei, Rongjuan; Chen, Xinwen; Sy, Man-Sun; Zhang, Bixiang; Li, Chaoyang . CD2-Associated Protein Contributes to Hepatitis C, Virus Propagation and Steatosis by Disrupting Insulin Signaling.
Gisbert Algaba, Ignacio; Verhaegen, Bavo; Jennes, Malgorzata; Rahman, Mizanur; Coucke, Wim; Cox, Eric; Dorny, Pierre; Dierick, Katelijne; De Craeye, Stéphane . Pork as a source of transmission of Toxoplasma gondii to humans: a parasite burden study in pig tissues after infection with different strains of Toxoplasma gondii as a function of time and different parasite stages.
Lian, Huan; Wei, Jin; Zang, Ru; Ye, Wen; Yang, Qing; Zhang, Xia-Nan; Chen, Yun-Da; Fu, Yu-Zhi; Hu, Ming-Ming; Lei, Cao-Qi; Luo, Wei-Wei; Li, Shu; Shu, Hong-Bing . ZCCHC3 is a co-sensor of cGAS for dsDNA recognition in innate immune response.
Sepulveda-Toepfer, J. A.; Pichler, Johannes; Fink, Kathrin; Sevo, Milica; Wildburger, Sonja; Mudde-Boer, Liesbeth Christiene; Taus, Christopher; Mudde, Geert Cornelius . TLR9-mediated activation of dendritic cells by CD32 targeting for the generation of highly immunostimulatory vaccines.