Stanford researchers have engineered yeast strains for de novo biosynthesis of tetrahydropapaverine (THP) and a semi-synthetic production of papaverine with high efficiency.
Multiplexed analysis of biological components is critical for classifying molecular subtypes of heterogeneous tumors to provide patient-specific therapies.
Stanford researchers have discovered that ribonucleoside vanadyl complexes can be used as an additive in transcription reactions resulting in ~2-fold increased yield.
Researchers in Prof. Elizabeth Sattely's laboratory have developed a high-yield, scalable plant-based protein expression system to produce lignin-degrading enzymes for converting waste lignin into useful carbon-based platform chemicals.
Current injectable hydrogel materials have fast erosion and limited tunability of their mechanical properties at different stages of applications, limiting their biomedical applications.
Stanford researchers have invented a fully water-soluble, orange hydrazine sensor that can robustly quantify the toxin hydrazine in liquids such as drinking water, waste water (treated and untreated), and bodily fluids.
Enzymatically active hydrogenase is synthesized in a cell-free reaction. The hydrogenases are synthesized in a cell-free reaction comprising a cell extract derived from microbial strains expressing at least one hydrogenase accessory protein.
Stanford researchers developed a method to increase microbial fermentation gas transfer – a limiting factor in the production of bio products such as polyhydroxyalkanoates (PHAs).
Researchers in Prof. Juan Santiago's laboratory have developed a novel isotachophoresis (ITP) method to easily and seamlessly integrate various electrophoresis-based detection techniques with ITP preconcentration.