Stanford scientists have invented a new suite of adaptable hydrogel biomaterials that are optically transparent and injectable for cell encapsulation, tissue engineering, and drug delivery.
A major barrier in CAR-T cell therapies has been T cell exhaustion, which affects the durability and effectiveness of treatments, particularly for solid tumors.
The Hu Lab at Stanford has developed a neuroprotective gene therapy for treating glaucoma and other optic neuropathies. Their gene therapy AAV vector expresses NMNAT2 operably linked to a retinal ganglion cell-specific promoter (mSngc).
Stanford inventors in the lab of Dr. Katrin Svensson have discovered an endogenous peptide hormone that shows promise in treating obesity and diabetes.
Researchers at Stanford have developed a methodology for deep learning-based image reconstruction by incorporating the physics or geometry priors of the imaging system with deep neural networks.
SparseGMM, is a new algorithm which is a novel statistical approach for identifying drug targets in cancer patients and other diseases by more accurately modeling biological pathways.
Stanford researchers have developed a novel approach to make a stable and active platinum-alumina catalyst that maintains high activity under harsh conditions.
Stanford researchers have developed a new controllable methodology for molecularly targeted ultrasound contrast agent production with pre-formed ligand-phospholipid bioconjugates.
Stanford researchers have developed an integrated printer/scanner platform to screen biofluids for bacterial pathogens and other cells of interest at the single cell level.
Vibrational spectroscopy, including infrared and Raman optical spectroscopy, is an instrumental technique for fingerprinting molecular structures and the chemical compositions of different materials.
Researchers led by Stanford University's Stephen Tsai have developed new design and manufacturing approaches for glueless/boltless joining of metallic grid and carbon composite skins.
Stanford researchers have designed a new 3-dimensional (3D) hydrogel cell culture system that models native tissue environment with precise control over gelation and degradation properties.