Medford / Piscataway / Valencia / Ithaca / Louis / Cambridge / Rockford / St. Louis / /
Company
IgG / LG / Sigma-Aldrich / Amersham / Biomimetic / Thermo Fisher Scientific Inc. / Qiagen / PLOS ONE / Hess / Creative Commons / GE Healthcare / Suzuki / Cass AE / /
Country
United States / / /
Facility
College of Veterinary Medicine / College of Nanoscale Science / Baker Institute / State University of New York / Cornell University / Brandeis University / Through Cornell University / University of Pennsylvania / /
IndustryTerm
chemical immobilization / chemical approaches / hybrid organicinorganic devices / chemical attachment strategies / ethanol solution / in vitro applications / chemical approach / energy-producing platform technology / mitochondrial oxidative energy production / Protein solutions / implantable medical devices / enzyme chip / energy / classical chemical binding / energy production / prepared chips / chemical reagents / electricity / hybrid device / defined binding site / hybrid organic-inorganic devices / hybrid devices / insights into device / desired product / energy-generating systems / enterokinase cleavage site / control chips / bioenergy-producing platform technology / hybrid systems / hybrid material systems / /
Organization
College of Veterinary Medicine / Brandeis University / College of Nanoscale Science and Engineering / the University of Pennsylvania / State University of New York / Albany / New York / Cornell University / NYSTAR Center for Life Science Enterprise / NHS / Baker Institute for Animal Health / /
Biomimicry Enhances Sequential Reactions of Tethered Glycolytic Enzymes, TPI and GAPDHS Chinatsu Mukai1, Lizeng Gao1, Magnus Bergkvist2, Jacquelyn L. Nelson1, Meleana M. Hinchman1, Alexander J. Travis1* 1 Baker Institute