Mice that are homozygous for the targeted mutation have a complete cleft of the secondary palate and die within 12 hours of birth. Heterozygotes are viable, fertile, normal in size and do not display any gross physical or behavioral abnormalities.
Stanford researchers at The Lee Lab have discovered a novel epidermal tumor suppressor to treat squamous cell carcinoma (SCC) by utilizing existing drug therapies.
Researchers in the Molecular Imaging Instrumentation Laboratory at Stanford University have developed a PET (positron emission tomography) detector and front end readout assembly that can operate in a high field MRI (magnetic resonance imaging) system.
Researchers at Stanford have developed a method for instructing the steering system of an autonomous vehicle to perform a lateral steering action, e.g., when changing lanes or repositioning within a lane.
Researchers at Stanford have developed a method using expressed genetic barcodes to enable simultaneous lineage tracing and single cell profiling. Intratumor heterogeneity fosters tumor evolution which is a key contributor to therapeutic failure and the lethality of cancer.
Researchers at Stanford have leveraged spatial proteomic analysis to identify biomarkers with immediate implications for HER2-positive breast cancer treatment decision making and patient stratification.
Researchers at Stanford have developed a new synthetic strategy for self-assembling layered heterostructures into large single crystals and films useful in microelectronics.
Researchers at Stanford have advanced the concept of an "Anticipatory Control Interface" that informs the driver of a partially automated vehicle of its lateral trajectory plan.
Stanford inventors have developed a rechargeable, fluid-based shock absorber material for use in space constrained environments. Foam is the most common form of shock absorption material, but its force exerted is proportional to the degree of displacement.
Researchers at Stanford have designed a new nanophotonic detector to reduce cost, size and power consumption compared to existing thermal infrared (IR) cameras.
The Zhenan Bao Research Group at Stanford University developed and manufactured a photo-curable, directly patternable, stretchable, and highly conductive polymer that is ideal for bioelectronic applications, and stretchable electronic devices.
Scientists in the Zhenan Bao Research Group at Stanford developed a process for direct photo-patterning of electronic polymers that improves device density of elastic circuits over 100x.
The Zhenan Bao Research Group at Stanford University has designed an intrinsically stretchable polymeric matrix that allows seamless integration with physically crosslinked PEDOT:PSS, while stabilizing its high stretchability, and high conductivity after all necessary fabricat