Researchers at Stanford have developed a platform to design and screen novel chimeric large serine recombinases (LSRs), enzymes capable of inserting large DNA payloads into precise locations in the genome.
Stanford researchers developed an electrochemical reactor process that combines electrodialysis and membrane stripping, reduces the chemical inputs needed and expands recovered product portfolio to alkaline ammonia (for cleaning products) in ratios customized to a user's speci
Stanford researchers have developed an "electrocatalyst-in-a-box" that extracts wastewater nitrate and converts it into ammonia. Nitrogen pollution threatens water security and human health, and demand for ammonia continues to grow.
Stanford researchers have developed an Electrodialysis and Nitrate Reduction Process (EDNR) that produces high-purity ammonia from agricultural runoff.
Stanford scientists have developed a platform that combines Raman spectroscopy, nanomaterials, and machine learning to rapidly identify bacteria in wastewater without chemical labels.
Stanford researchers have patented a system for precise genetic modification of human embryonic stem cells (ECSs) and induced pluripotent stem cells (iPSCs).
Stanford researchers have produced 5 varieties of Gold Bantum, a one hundred year old public sweet corn variety, which have new colors and gloss, including:
Many applications in cell therapy, synthetic biology, and gene therapy require extensive cell engineering, often with multiple vectors due to limitations in packaging capacity.
Stanford Plasma Physics Lab researchers have developed a scalable system to manufacture fertilize water, or plasma fixated nitrogen (PFN) in water, using cold nonequilibrium plasma.
Researchers at Stanford have developed a frequency-selective MHz power amplifier for generating dielectric barrier discharge (DBD) plasma. Commercial applications include plasma-assisted nitrogen fixation for fertilizer production.
Stanford inventors have developed a cell-free method for carbon-negative biosynthetic production of commodity biochemicals by using hydrogen gas as a source of reducing equivalents.
Stanford researchers in the Swartz lab have proposed a method to synthesize metabolic cofactors from inexpensive substrates for protein synthesis and commodity production applications.
Stanford researchers in the Swartz lab have developed a method for improving the productivity of biosynthetic processes via enzymatic detoxification of aberrant forms of NAD(P)H.