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.
Stanford researchers have developed a process for synthetic palm oil production that is environmentally friendly and can be implemented locally by farmers.
Stanford researchers at the Zare Lab, Department of Chemistry, have developed a simple and eco-friendly method that could potentially produce substantial amounts of ammonia and urea, both of which are primarily used in fertilizer.
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 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.
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 Kanan group have developed a electrolysis cell for generating and extracting liquid and gas product streams from CO and CO2.
Stanford researchers in The Tang Group have developed a reproducible, high throughput device that dices tissue into uniformly sized sub-millimeter sample fragments.
Stanford inventors have discovered a single plant protein, FLOE1, that controls a variety of processes that are crucial to timely and robust germination of seeds.
Stanford researchers have shown how to use fluorescent and phosphorescent materials to provide plants with photons in the photosynthetically active radiation (PAR) range for increased crop yields and CO2 fixation.
A novel method for dissociating plant tissues for biochemical and genomic analysis that accommodates harsher digestion conditions with increased tissue dissociation efficiency and quality of isolated RNA.