Stanford scientists have developed an optical imaging system that enables simultaneous monitoring of multiple neural signals across large brain regions with high temporal and spatial resolution.
Stanford researchers have developed an innovative wearable respiratory monitoring device that provides continuous, real-time detection of airflow obstruction during sedation, anesthesia, and recovery, which is an issue frequently missed by current monitoring technologies.
Stanford researchers at the Ferrara Lab have developed a method to select receptor targets for molecular imaging and therapies by applying spatial transcriptomics, proteomics, and machine learning.
Stanford researchers have developed a specialized bone graft delivery device that can efficiently transport and implant fragmented bone grafts or therapeutics into narrow bone tunnels without disintegration.
Researchers at Stanford have developed a novel endoscopic system for electrical stimulation and signal recording of olfactory tissue through a minimally invasive nasal approach.
Stanford Medicine researchers in The Stuart Goodman Lab have developed a bone anchor system for surgical tracking that is easier to use and decreases complications caused by conventional knee or hip replacement bone pin anchors.
Stanford Artificial Retina Project researchers have developed an ASIC Retina Chip that interfaces with retinal ganglion cells to restore vision in patients with retinal degeneration.
Stanford researchers have developed an innovative wearable device that enhances mindfulness training by augmenting the user's real-time auditory environment.
Stanford researchers have developed EphrinA3 technology to strengthen epithelial barriers by increasing expression of cell-cell adhesion molecules, particularly desmoglein-1 (DSG1) and desmocollin-1 (DSC1).
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.
The Stanford team developed a groundbreaking approach to measure single molecules by precisely measuring the forces induced by the absorption of electromagnetic radiation.
Stanford researchers have developed a technology for the automated separation of arteries and veins in single-phase brain CT angiography (CTA) using graph neural networks, enabling precise collateral scoring and improved stroke prognosis.
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.