Researchers at Stanford have developed a dielectric diffraction grating that provides high (near-unity) diffraction efficiencies in an ultra-compact volume.
Stanford researchers at the Thakor Lab have developed methods for kidney tissue regeneration using pulsed focused ultrasound (pFUS) therapy with mesenchymal stromal cells (MSCs) and/or MSC-derived extracellular vesicles (e.g., exosomes or microvesicles).
Genetic engineering of biological systems is a fundamental tool for both basic and translation research, where up- and down-regulation of gene expression is necessary to drive cellular phenotypes and evaluate gene function.
Our researcher has developed a mouse model of 16p11.2 deletion syndrome. A copy number variation on human chromosome 16p11.2 is among the most common genetic variations found in autism spectrum disorders.
The emergence of SARS-CoV-2 variants during the COVID-19 pandemic has demonstrated a need for broad immunization, such as provided by multivalent vaccines.
Researchers in the Appel lab have developed hydrogels for tumor inoculation that improve precision and statistical power in preclinical mouse models of cancer.
Radiation is often an effective treatment modality for cancer, but its effects are limited to the targets that are directly irradiated. Regions of tumor outside the radiation field do not experience direct radiation-induced DNA damage and cellular apoptosis.
Stanford inventors have discovered a single plant protein, FLOE1, that controls a variety of processes that are crucial to timely and robust germination of seeds.
Jennifer Cochran and Carolyn Bertozzi have collaborated to develop a bifunctional molecule called a polyspecific integrin-binding peptide (PIP)-LYTAC that can bind to integrins expressed on the surface of cancer cells and trigger their degradation via the lysosome.
Many industries rely on the ability to predict and understand changes over time. Such changes include understanding the economical trend, emergence of infectious disease, and patterns in human behavior.
Researchers at Stanford have developed methods for evaluating the position of a micro-electromechanical system (MEMS) device in terms of phase and/or amplitude characteristics.