Stanford researchers have developed an innovative method for efficiently generating robust lymphatic endothelial cells (iLECs) from human induced pluripotent stem cells (hiPSCs) through transcription factor-based protocols.
Stanford scientists have designed a passive and active polarization-insensitive grating coupler that enables consistent fiber-to-chip light coupling regardless of input polarization state.
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 Robert Lowsky and Samuel Strober have developed a strategy for maintaining normal graft function without immune suppression medication. Kidney transplant recipients require lifelong use of immunosuppressants to minimize rejection risk.
Stanford researchers have patented methods to improve phagocytosis, the process by which macrophages clear protein aggregates, dying cells, and debris, to treat age-related diseases.
Researchers in the Wyss-Coray Lab are investigating a potential therapeutic antibody to treat lysosomal storage disorders and other related neurodegenerative diseases.
Stanford researchers have developed an innovative, non-invasive therapeutic strategy to treat myocardial fibrosis (MF), a key driver of arrhythmia and heart failure in LMNA-related dilated cardiomyopathy (LMNA-DCM).
Stanford researchers have developed Screen-GPT, an AI-powered multi-agent platform that automates CRISPR genetic screening by integrating diverse biological data to design libraries and prioritize targets through transparent, explainable, and scalable workflows.
SARS-CoV2 is known to gain entry into epithelial cells through the association of its viral spike protein with the ACE2 receptor, which is widely expressed on epithelial cell types.
Stanford researchers have developed a neuromonitoring-guided cognitive intervention that enhances working memory by dynamically identifying and reinforcing engagement of individualized brain networks in real time.
Stanford researchers have invented techniques to adaptively tune the operation of a wireless full-duplex node. To enable full-duplex operation, the receiver circuit needs to be able to cancel the transmitter's signal in order to receive data from other nodes.
Engineers in Prof. Sachin Katti's laboratory have developed a 3 X 3 in-band full duplex MIMO radio, that can simultaneously transmit and receive on the same channel using standard WiFi 802.11n PHY for 20 Mhz bandwidth.
Engineers in Prof. Sachin Katti's laboratory have developed a full duplex wireless system designed to double throughput by simultaneously transmitting and receiving signal on a standard single inband antenna.