Stanford researchers have developed an innovative optical architecture that enables projection-based vat photopolymerization (VP) 3D printers to significantly expand the printable area without sacrificing resolution, speed, or structural integrity.
Stanford researchers have developed novel AsCas12a-expressing mouse models for simultaneous editing of multiple genomic loci in vivo with unique targeting capabilities relative to traditional Cas9 models, enabling the rapid creation of complex genotypes in somatic cells and ca
Stanford scientists have developed a lateral flow diagnostic platform that detects pathogen DNA without nucleic acid amplification, delivering results visible to the naked eye in under 30 minutes.
Stanford scientists have developed a method and apparatus for simultaneously measuring mucus rheology and cilia activity on live airway cells without removing mucus or inhibiting cilia function.
Stanford scientists have discovered that theta oscillations in the anterior cingulate cortex can detect empathic states, and that targeting the upstream orexin circuit can modulate empathy-related behaviors.
Researchers at Stanford have developed a general software framework that reconstructs high-resolution spatial fields from sparse, irregular, or noisy measurements.
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 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 scientists have developed innovative methods for safely collecting, preserving, imaging, and molecularly profiling human brain tissue that remains on explanted intracranial electrodes used in neurosurgical procedures.
Stanford scientists have discovered that Guanidinylated Serinol Charge-altering Releasable Transporters (GSer-CARTs) can be tuned for selective mRNA delivery to the lung and spleen in a predictable fashion.
Stanford researchers in Prof. Michelle Monje's lab have developed a method for treating cognitive impairment (aka brain fog) caused by cancer immunotherapy.