Stanford researchers at the Lee Lab have developed a method to understand whole-brain circuit mechanisms underlying neurological disease and its application to predict the outcome of therapeutic interventions.
The Stanford Sarafan ChEM-H Medicinal Chemistry Knowledge Center has developed a novel aqueous solubilizing promoiety (Sol-moiety) that can be readily attached to a wide-range of functional groups and undergo controlled cleavage to improve the pharmacokinetic profile of a desi
Stanford researchers have developed novel designs for 3D-printed microarray patches (MAPs) that can improve intradermal drug delivery and sampling. These designs support the use of microneedles for minimally invasive therapy administration and diagnostics.
Stanford researchers have developed a patient classification method (healthy, idiopathic, diabetic, etc.) based on a quantitative assessment score derived from autonomic and gastric electrocardiogram (ECG) and electrogastrogram (EGG) data.
Stanford researchers have developed an expanded catalog of compact transcription effector domains and fused them onto DNA binding domains to engineer synthetic transcription factors.
Stanford researchers in the Lin Lab have identified kinase-modulated bioluminescent indicators (KiMBIs) which can assess real time kinase inhibition in target tissues in vivo.
Researchers at Stanford and the University of Helsinki discovered that a human secretoglobin protein found in sweat gland cells acts as a novel host defense mechanism against Lyme disease.
Stanford scientists in Chris Garcia's lab have developed leptin analogs that have potentially more favorable pharmacokinetic and pharmacological signaling properties for use as diabetes and obesity drugs.
Stanford researchers in the Bao Lab have designed hydrophobic perfluoropolyether (PFPE) polymers that can be applied in underwater conditions, at room temperature, without any solvent or curing steps, and can be reused and recycled.
Researchers in the Zhenan Bao Group and the Yi Cui Group have developed a Salt-Philic, Solvent-Phobic (SP2) Li anode polymer coating that dramatically out performs state of the art Li anode coatings/electrolyte strategies battery cycle life.
Researchers at Stanford University have developed gas diffusion layers with engineered surface roughness within the gas pathway of electrochemical devices that improves catalyst utilization.
Stanford researchers at the Zare Lab, Department of Chemistry, have developed a simple and eco-friendly method that could potentially produce substantial amounts of ammonia and urea, both of which are primarily used in fertilizer.