Stanford researchers have created a novel wearable device and system to assess fatigue on the user based on electrical activity associated with an eye blink of the subject.
We present a revolutionary advancement in ferroelectric materials that is set to redefine the landscape of embedded memories and semiconductor technologies.
Stanford researchers have developed a method for identifying the foveal center in the eye for high resolution retinal mapping in adaptive optics devices using artificial intelligence.
For the first time, researchers in Prof. Yan Xia's laboratory have synthesized a new ladder type microporous polymide (PIM) by linking an arene-norbornene building block to a Tröger's base which can be used for high-performance gas separation membranes.
This invention is an innovative breakthrough in cancer radiotherapy, offering a cutting-edge solution to address the challenges of radio-resistant and immunosuppressive tumors.
Researchers at Stanford have developed a porous biologics-loaded multimaterial construct, called Hybrid Tissue Engineering Construct (HyTEC), with applications in regenerative medicine and therapeutic delivery.
Based on their proprietary HyTEC tissue engineering platform, researchers at Stanford have developed an osteoinductive intramedullary implant (IM) device for improved bone healing.
Researchers at Stanford have developed a biodegradable device and platform carrier of biologics for promoting faster bone healing of large bone defects, fractures, and non-union.
Stanford researchers have developed chemically modified AAV vectors through an unnatural amino acid substitution on the capsid surface for post-production vector engineering through biorthogonal copper-free click chemistry.
Mature pancreatic islets are the gold standard for transplantation-based approaches for islet replacement in type 1 and type 3c diabetes mellitus (T1D and T3cD), but this feature is offset by the scarcity of human cadaveric pancreas donors.