Precise amplification of selected portions of genomic DNA is highly desirable for many DNA analysis purposes, for example the sequencing of multiple genes involved in a certain disease.
Although organic thin film transistors (OTFTs) made from organic semiconductors are valued for their transparency, flexibility and low cost attributes, their sluggish response time due to slow carrier mobility limits their applications.
An interdisciplinary team of Stanford researchers have developed MagSweeper, a patented robotic liquid biopsy device that efficiently isolates and purifies live CTCs (circulating tumor cells) from blood while removing 100% of contaminating blood cells.
Stanford researchers successfully purified highly enriched semiconducting single-walled carbon nanotubes (SWNT) free of any dispersing agent via an easy, fast and scalable method.
Stanford researchers have developed a simple and effective method to sort semiconducting from metallic single walled carbon nanotubes (SWNT). This scalable technique uses semiconducting polymers to wrap around individual semiconducting SWNTs dispersed in a solution.
Researchers in Dr. Leonore Herzenberg's lab at Stanford have developed this technology and another (see Stanford Docket S15-009) to improve the ease and accuracy of flow cytometry experiments.
Researchers in Dr. Leonore Herzenberg's lab at Stanford University have developed a portfolio of data management, storage, and analysis technologies that may be used for large data sets.
Stanford researchers at the Shenoy Lab have tested a method that can detect and predict the outcome of brain machine interface (BMI) tasks using motor cortical brain activity.
Researchers in Dr. Karl Deisseroth's lab have engineered a channelrhodopsin variant that can be stimulated by red light and has fast stimulation frequencies. In neurons, channelrhodopsins are light activated protein channels that induce action potential firing.
A team of Stanford and MIT researchers developed a perovskite/silicon multijunction solar cell designed to surpass the photovoltaic efficiency limits of silicon while utilizing existing manufacturing capabilities.
Circulating levels of Neuromedin U (NMU) peptide are correlated with insulin resistance and obesity and dynamically regulated to suppress insulin secretion.