Stanford researchers have invented a C-Aperture Nano-Tip which provides a new way to further enhance the optical resolution down to smaller than 15 nm.
Researchers at Stanford and their colleagues have developed easily expressed Wnt agonist and antagonists. Wnts are central mediators of development as they influence cell proliferation, differentiation and migration.
Stanford researchers have developed a lanthanide-doped upconverting nanoparticle (UCNP) that emits very photostable and non-blinking light, and is bright enough to delineate tumor boundaries to the naked eye during surgery.
Stanford engineers have developed and tested a nanostructured thin film material that upconverts infrared to visible light and combines electrical and non-linear optical properties in the same layer.
Researchers in the Stanford Genome Technology Center have developed a robust, high-throughput, high-efficiency functional genomics platform to generate precisely edited genome variant libraries and then readily isolate and identify thousands of individual strains en masse
This invention is a simple, versatile, high density grid designed to enable rapid X-ray crystallography by greatly reducing the time spent exchanging and positioning samples.
Researchers in Prof. Hemamala Karunadasa's laboratory have developed inexpensive, robust, high capacity hybrid materials for reversible or irreversible capture of halogens (chlorine, bromine, and iodine gas).
Stanford researchers at the Airan Lab have developed a new method for robust and spatiotemporally precise non-invasive neuromodulation that could transform both basic and clinical neuroscience.
Stanford chemists have developed a scalable synthetic process to create a new class of viscous, stable phospholipid bilayer vesicles with tunable properties.
Researchers at Stanford have developed a dual modality imaging probe to provide improved atherosclerosis detection and evaluation. Atherosclerosis is a disease in which plaque builds up inside arteries.
Researchers in Prof. Hongjie Dai's laboratory have combined graphene with metals and other inorganic elements to create a variety of hybrid materials that can be used for high performance electrocatalytic or electrochemical devices such as batteries and fuel cells.
Researchers in Prof. Hongjie Dai's laboratory have developed nanocarbon/inorganic nanoparticle hybrid materials for various electrocatalytic and electrochemical applications, such as batteries and fuel cells. Three types of hybrid materials have been created:
W.E. Moerner and Adam Cohen have patented the Anti-Brownian ELectrokinetic trap (ABEL trap) which can trap, measure, and manipulate sub-micron objects (e.g. single molecules) in solution at ambient temperature.
Researchers in Prof. James Swartz' laboratory have developed a rapid bioluminescence method for detecting and enumerating circulating tumor cells (CTCs) and other rare cells. This invention utilizes novel nanoparticle reagents which can specifically bind to cells of interest.