Inspired by the "last inch" problem in robotic manipulation, the Kennedy group at Stanford has developed a tactile sensor and calibration method for machine-learning-based robotic manipulation.
The potency of cancer immunotherapies for solid tumors are often diminished by inadequate metabolic reprogramming and resulting immune evasion in cancer.
Researchers in the Mackall lab at Stanford have developed an adoptive cell therapy modification that enhances anti-tumor activity by disrupting a specific group of genes.
Researchers at Stanford have developed the first known fixed-frequency control method to enable piezoelectric based power converters to avoid spurious mode and operate across a full output power range while maintaining high efficiency.
Inventors at Stanford developed a method to leverage mass cytometry, a type of flow cytometry utilizing mass spectrometry, for the detection of heavy metals in leukocytes from individuals exposed to heavy metals in elevated air pollution.
Researchers at Stanford University's Curtis Laboratory have used gene expression to categorize the sensitivity and resistance of anthracycline chemotherapy in breast cancer patients with utmost precision.
Stanford inventors have developed and fabricated biodegradable and biocompatible polysaccharide hydrogel optical fibers for fiber optic sensing and light transmission in biomedical applications like antigen detection, tracking cellular events, and optogenetics.
Stanford researchers have formulated a statistical model to determine the risk of breast cancer recurrence with unprecedented accuracy in women 5 – 20 years after initial diagnosis.
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.
Chemical engineers at Stanford have developed miscible antifoams that are easy to incorporate and do not separate out from the target liquid during operation.
Stanford researchers have developed a patented microscopy method which can provide chemical identification of molecular structures with radiation spectroscopy at nanometer or near-atomic scales, which is one of the most challenging problems in microscopy.