Hydrogen is becoming increasingly important as a clean energy fuel source. Accurate measurement of hydrogen concentration is essential, as it impacts fuel pricing and ensures safety during production, refinement, and transportation.
Stanford researchers in the KC Huang Lab have patented a method that identifies functionally conserved protein regions with recurrent genomic alterations in cohort studies using natural variations in genomic sequences, which allows for the discovery and further understanding o
Stanford scientists have developed a gene integration system that uses human-derived helicases paired with CRISPR technology to enable precise insertion of long DNA sequences at targeted genomic locations.
Stanford scientists in Lacramioara Bintu's lab have developed a high-throughput system to identify regulatory domains in human RNA-binding proteins, presenting a new set of tools that could greatly enhance control over gene regulation at the RNA level for therapeutic and synth
Mice heterozygous for the targeted allele are viable and fertile. This polyubiquitin B (Ubb) mutation is characterized by a GFP-puror fusion protein "knock-in" allele that also abolishes endogenous gene function.
Stanford scientists in Prof. Steven Boxer's lab have invented a quantum cascade laser (QCL)-based IR spectrometer and assay for the sensitive detection of drug-protein interactions in live cells.
Stanford scientists have developed a high throughput screening method to identify therapeutics known as translational activators to treat protein synthesis disorders and ribosomopathies.
Undulator magnet cores are essential for advanced applications such as synchrotron radiation sources, advanced chip manufacturing, and fusion technology. SLAC researchers have a new manufacturing approach that achieves greater precision at significantly lower costs.
Hydrogen that is free of greenhouse gas (GHG) emissions is a key vector to fuel a net-zero emissions economy, but today's H2 is sourced from fossil fuels mostly by the highly emissions-intensive processes of steam methane reforming (SMR) or coal gasification.
Scientists in the Carette Lab at Stanford have developed AAV-Titer cell lines that enable (1) improved and standardized in vitro potency assays (2) determination of a functional titer of AAV vectors of different serotypes and containing different promotors.
Stanford researchers have developed a novel methodology for the high-throughput expression and kinetic characterization of numerous enzyme variants in parallel using microfluidic droplet arrays.
The recognition of peptide-MHC (pMHC) complexes by T cells is the cornerstone of cellular immunity, enabling the elimination of infected or tumoral cells. pMHC can thus be leveraged as a detection tool for T cells.