Dr. Brian Zabel and Prof. Eugene Butcher have developed rat monoclonal antibodies (clones BZ2E3 and BZ5B8, rIgG2aκ isotype) to the mouse chemokine (CC motif) receptor-like 2 (CCRL2) protein.
Dr. Andrea Meredith and Dr. Richard Aldrich have generated a viable mouse knockout KCNMA1, the gene encodes the pore-forming subunit of the BK large conductance calcium-activated potassium channel (also called KCa1.1, SLO1, and MaxiK).
Researchers in Dr. Mark Davis' lab have developed a patented method to perform multi-parametric phenotypic analysis and T cell receptor (TCR) sequencing from single sorted T cells.
This invention is a system that allows labeling of radiological images based on anatomy, such that radiologists or other users can locate the images using anatomical names.
Researchers from Dr. Mark Kay's laboratory at Stanford University have merged desirable qualities of multiple natural AAV isolates by an adapted DNA family shuffling technology to create a complex library of hybrid capsids from eight different wild-type viruses.
Researchers in Dr. Michael Lin's lab have developed a fluorescent voltage sensor for non-invasive optical monitoring of electrical events in living cells in vitro and in vivo.
This L203 antibody may prove useful for research and diagnostic products in the detection of HLA, or on blood cells and/or in blood products such as plasma and serum; and the detection of soluable or cell associated HLA, or associated blood pathogens.
Hydrogel-based tissue engineering scaffolds are widely used for culturing cells in three dimensions (3D) due to their tissue-like water content, tunable biochemical and physical properties, and ease of cell encapsulation and distribution in 3D.
A team of Stanford researchers have identified a novel small molecule that could be used in vivo or ex vivo to enrich for submandibular salivary gland (SMG) stem cell (SC).
Researchers in Dr. Roeland Nusse's lab have developed a mouse monoclonal antibody to ROR2 (Nt 2535-2835). ROR2 is a membrane bound receptor tyrosine kinase that is activated by non-canonical Wnt signaling through its association with Wnt5.
Homodyne image reconstruction is combined with an iterative decomposition of water and fat from MR signals obtained from a partial k-space signal acquisition in order to maximize the resolution of calculated water and fat images.
Disclosed is x-ray cone beam scan data reconstruction of an imaged object with a reconstruction algorithm using shift invariant filtering and backprojection with the maximum tomographic capability of a circular scan larger than p plus cone angle, when CB data is not truncated