To help spur economic development and assist in the battle against COVID-19, PNNL is making available its entire portfolio of patented technologies on a research trial basis—at no cost—through the end of 2020.
A new study using proteogenomics to compare cancerous tissue with normal fallopian tube samples advances insights about the molecular machinery that underlies ovarian cancer.
A new study focusing on the proteins involved in endometrial cancer, commonly known as uterine cancer, offers insights about which patients will need aggressive treatment and which won’t.
A detailed analysis of blood samples from Ebola patients in Sierra Leone is providing clues about the progression of the effects of the virus and potential treatment pathways. The findings point to a critical role for a molecular pathway.
Pacific Northwest National Laboratory and Washington State University researchers have developed a novel way to deliver drugs and therapies into cells at the nanoscale without causing toxic effects that have stymied other such efforts.
PNNL scientists have captured the most information about proteins from a single human cell, giving scientists one of their clearest looks yet at the molecular happenings inside a human cell.
Fifteen PNNL scientists are part of a team that has identified a set of biomarkers that indicate which patients infected with the Ebola virus are most at risk of dying from the disease.
PNNL scientists are part of a nationwide effort to learn more about the role of proteins in cancer biology and to use that information to benefit cancer patients.
PNNL scientists have gotten one of the most in-depth looks ever at the developing lung, characterizing hundreds of lipids and thousands of proteins from samples as small as just 4,000 cells.
Working with researchers with Tokyo Tech's World Research Hub Initiative in Japan and Canada, Xantheas will combine laboratory methods with computational explorations to study the biological functions of serotonin and nicotine.
Rick Corley has been honored for his work modeling the full chain of human respiration, from organ, to tissue, to cell, and down to individual molecule.