Researchers from Prof. Karl Deisseroth's laboratory have developed techniques for specifically modulating the activity of excitable cells in vivo. This approach introduces light-responsive proteins to create photo-sensitive cells.
Researchers from Prof. Karl Deisseroth's laboratory have developed techniques for specifically modulating the activity of excitable cells in vivo. This approach introduces light-responsive proteins to create photo-sensitive cells.
Researchers in Dr. Karl Deisseroth's laboratory at Stanford University have developed a novel suite of genetically-encodable, optically-activated modulators of second messengers (such as cAMP and IP3).
Researchers in Prof. Karl Deisseroth's laboratory have developed a portfolio of microbial opsin proteins that can be used for precise and modular photosensitization components that enable optical control of specific cellular processes.
Temporally precise, noninvasive control of neural circuitry is a long-sought goal of neuroscientists and biomedical engineers. Stanford University researchers in the laboratory of Dr.
Researchers in Prof. Karl Deisseroth's lab have discovered and engineered new microbial opsin proteins and cell trafficking tools to enable selective cell-type specific, light-sensitive switches for neuromodulation.
Stanford researchers have developed a simple optical device for low-power, active light tuning. The device tunes the color of light across the visible spectrum and at select wavelengths by electrical biasing an array of micron sized pixels or nanowires.
Histone acetyltransferase 1 (HAT1) is an enzyme which acetylates lysine on histone proteins and is intricately involved with regulating gene transcription.
Researchers in the Fan group have developed a method for epitaxial growth of double heterojunction semiconductor diodes capable of suppressing parasitic non-radiative recombination effects.
Two related technologies, a pipeline for generating a custom PathFX algorithm and a new algorithm named Mr. Rogers, are used to identify protein pathways around drug targets.
Researchers in the Sunwoo Lab have developed a method to differentiate intra-epithelial innate lymphoid cells type 1 (ieILC1s) from conventional peripheral natural kills cells for immunotherapeutic purposes.
Researchers in the Arbabian Lab have developed a system that uses a combination of radio frequency (RF) electromagnetic and ultrasound (US) waves to detect, localize, and identify multiple battery-free tags.
Stanford researchers have created an integrated cooling textile (called i-Cool) with an unique functional design for personal perspiration management (PPM).