Stanford researchers have developed an intelligent graph-based system that automates clinical decisions through evidence-based protocols for chronic disease management.
Stanford scientists have developed a novel cardiac Ex-vivo Preservation System (EVPS) capable of maintaining hearts of any size warm and beating upon transport, expanding heart transplant options for pediatric populations.
Stanford scientists have developed a novel Nerve Decompression Brace capable of decompressing mild nerve compressions, which relieves forearm pain, numbness, and tingling symptoms associated with repetitive strain injuries.
Stanford scientists have developed DragonRNA, a novel method to produce DNA-capped RNA molecule by RNA polymerases, designed for enhanced stability and utility in RNA-based therapeutic and biotechnological applications.
Stanford scientists have developed methods to analyze mononuclear phagocyte system markers for detecting prosthetic joint infections that evade conventional neutrophil-based diagnostics.
Urethral catheterization is commonly performed during elective procedures, inpatient hospitalizations and long-term patient management, with more than 30 million indwelling catheters used annually in US.
Stanford researchers have developed an advanced method for accurately tracking and accumulating radiation dose in magnetic resonance-guided radiotherapy.
Code In Place is an innovative program from Stanford University that provides free, high-quality introductory courses in Python programming, utilizing volunteer tutors to reach a global audience.
Researchers at Stanford University have discovered that donor-specific anti-HLA antibodies can be used to detect and treat graft-versus-host disease (GVHD) in transplant recipients after allogenic transplantation.
Stanford researchers have developed a novel shortwave infrared (SWIR) sinuscope to noninvasively detect cerebrospinal fluid (CSF) leaks during skull base surgeries.
Researchers at Stanford University have identified EP300 modulators as effective treatments for reducing skin scarring, demonstrating significant regeneration of hair follicles, sweat glands, and connective tissue architecture.
Scientists in Dr. Howard Chang's lab have developed ESCAPE-seq (Enhanced Single Chain Antigen Presentation sequencing) to identify novel neoantigen sequences for the development of immunotherapies.
PirB (PIR-B) knockout mice are genetically modified mice in which the gene encoding the PirB receptor (paired immunoglobulin-like receptor B) has been disrupted or "knocked out." PirB is a member of the immunoglobulin superfamily and plays a role in regulating immune responses