Stanford researchers have developed a personalized arrhythmia risk prediction tool for dilated cardiomyopathy (DCM) patients using patient-derived induced pluripotent stem cells (iPSCs) to replicate heart biology and accurately predict arrhythmia risk, enabling timely interven
Stanford University researchers in the Bamm and Durmus Labs have developed the Dynamic AI-Driven Raman Techniques (DART) platform, which integrates electrochemical enhancement with surface-enhanced Raman spectroscopy for real-time, sensitive, specific, reproducible biomarker d
Stanford scientists have developed a lightweight, wearable multichannel NMES system that provides real-time, AI-driven gait assistance and muscle strengthening — with a particular focus on children with walking disabilities.
Stanford researchers have designed a electrochemical sensor system for continuous analyte measurement and tracking in complex biological samples (i.e. blood and serum) with a wide range of clinical and non clinical applications.
Stanford researchers have developed an innovative metasurface-enabled, CMOS-compatible platform for high-density, on-chip oligonucleotide synthesis that enables precise, site-selective DNA production without mechanical scanning or complex photolithographic alignment.
Diagnosis and sub-typing of inflammatory bowel disease (IBD) subsets, such as Crohn's disease (CD) and ulcerative colitis (UC), often require the use of repeated, invasive, and expensive endoscopy procedures, which are not without risk.
Researchers in Professor Justin Sonnenburg's laboratory have developed genetic tools for manipulating Bacteroides, a prominent genus of gut bacteria, for imaging, diagnostics, and therapeutic drug delivery.
Stanford researchers have developed a system that assesses altered mental states in both human and animal subjects using neural biomarkers, allowing for repeatable cross-species studies of potential treatments for psychiatric and neurological disorders.
Stanford researchers have developed a novel blood-based diagnostic platform that leverages circulating bacteriophage DNA (phage cfDNA) to enable sensitive and highly specific detection of both overt and subclinical bacterial infections, while effectively discriminating them fr
Necrotizing enterocolitis is a life-threatening illness almost exclusively affecting the gastrointestinal tract of neonates. It's caused by bacterial invasion of the intestinal wall, which leads to inflammation and cellular destruction of the wall of the intestine.
Stanford scientists have developed methods to analyze mononuclear phagocyte system markers for detecting prosthetic joint infections that evade conventional neutrophil-based diagnostics.
Stanford researchers have demonstrated clinical proof of concept that a real-time biofeedback system can reduce pain and slow joint degeneration in patients with movement disorders such as knee osteoarthritis.
Stem cells are generally influenced by a microenvironmental niche, typically comprised of epithelial and mesenchymal cells and extracellular substrates. Many attempts have been made to produce culture systems that mimic normal intestinal epithelial growth and differentiation.
Patients with celiac disease have a pathological reaction to gluten and have either HLA-DQ2+ (90%) or HLA-DQ8+, but expression of these MHC class II haplotypes is not sufficient and other factors are necessary for the development of celiac sprue.