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.
These dual-function nanoparticles improve selectivity of myeloid treatment via identification and reduction of tumor progression in a two-step process: initial accumulation in tumor microenvironments, followed by targeted delivery of a therapeutic payload.
Researchers at Stanford have developed a new water-based disinfectant with the potential to destroy a wide variety of pathogens and significantly improve healthcare settings.
Researchers at Stanford and their colleagues have developed new antibiotic compounds that could be used to treat staph infection (caused by Staphylococcus aureus) and TB infection (caused by Mycobacterium tuberculosis).
Researchers in Prof. Richard Zare's laboratory have developed a fast, accurate mass spectrometry technique for distinguishing an individual's gender, age or ethnicity based on the chemical composition of sweat.
Researchers in Prof. Richard Zare's laboratory have developed a low-cost, thin, flexible, reusable polymer matrix to be utilized as an ionization vehicle for ambient mass spectrometry.
Richard Zare's lab at Stanford University has developed a ground-breaking drug release system in which injected medication can be controlled externally with excellent spatial, temporal, and dosage control.
Researchers in Dr. Richard Zare's lab have developed solid lipid nanoparticles (SLNPs) that provide sustained in vivo delivery of small interfering RNAs (siRNAs). siRNAs can silence genes responsible for disease, which makes them promising tools for gene therapy.
Dr. Richard Zare and colleagues have developed an inexpensive, fast and simple method for treating polyethylene terephthalate (PET) blood collection tubes (BCTs) to remove bias and interference in various blood analysis procedures.
Researchers in Prof. Dick Zare's laboratory have developed an efficient, label-free platform to separate and detect cells, bacteria, or other particles in fluid samples. This method employs cell/particle cavities created in a polymeric film (imprinted polymeric film, IPF).