Stanford researchers in the Fan Lab have developed a photonic device optimizer that generates designs with hard geometric constraints to guarantee device fabricability.
Stanford researchers have developed a time efficient and safer algorithm for autonomous cars that combines game theory and risk awareness. This algorithm computes approximate feedback Nash equilibria where all agents are risk aware, a novel approach.
Activation of hedgehog signaling pathway can facilitate stem cell proliferation and holds great promise in regenerative medicine for a variety of indications.
Collagen-based hydrogels behave similarly to the native tissue microenvironment, thus are widely used as scaffolds for encapsulating cells or molecules like growth factors. Collagen solution is an injectable liquid until it crosslinks at 37 C and physiological pH.
Stanford researchers have developed a novel technique to control proton beams for radiation therapy to deliver a very high, full dose across a tumor in less than one second.
Tracking in vivo cell distribution, migration, and engraftment using conventional techniques including MRI, PET/CT and conventional optical imaging is often hindered by low resolution, radioactive risks, and limited tissue penetration depth.
Stanford researchers have developed a technique to interpret contact events between a human and a device equipped with a force sensor. It can detect and classify distinct touch interactions such as tap, touch, grab, and slip.
Researchers at Stanford, the University of Massachusetts and the Chan Zuckerberg Biohub have developed methods to increase or decrease RNA interference target cleavage rates.
Researchers at Stanford and the Chan Zuckerberg Biohub have developed a methodology to monitor cell expansion and differentiation following targeted genomic modification.
Researchers at Stanford and the Chan Zuckerberg Biohub have developed a platform for characterizing a population of microbes using spectrally encoded beads.
The Dai lab has developed an ionic liquid (IL) electrolyte for lithium metal batteries that eliminates electrolyte flammability concerns without sacrificing performance.
Stanford researchers at the Okamura Lab have prototyped a computerized "pillow" that fits in the hand and uses air pressure to measure involuntary grip force (spastic hypertonia).