The day after the 2014 Breakthrough Prize in Life Sciences winners are announced, the recipients – along with 2013 recipients, UCSF Nobel laureates and other luminaries in the field – will participate in a symposium on the state of research in cancer, genetics, neurobiology and stem cells.
December 10, 2013
July 19, 2013
Stem-cell researchers at UCSF have found a key role for a protein called BMI1 that may help scientists direct the development of tissues to replace damaged organs in the human body.
July 02, 2013
A UCSF-led team has discovered that vitamin C affects whether genes are switched on or off inside mouse stem cells, suggesting that it may play fundamental role in helping to guide normal development.
May 16, 2013
Raising hopes for cell-based therapies, UCSF researchers have created the first functioning human thymus tissue from embryonic stem cells in the laboratory.
April 18, 2013
UCSF scientists have discovered that muscle repair requires the action of two types of cells better known for causing inflammation and forming fat.
April 15, 2013
Specific DNA once dismissed as junk plays an important role in brain development and might be involved in several devastating neurological diseases, UCSF scientists have found.
April 03, 2013
Treating patients with cells may one day become as common as it is now to treat the sick with drugs made from engineered proteins, antibodies or smaller chemicals, according to UC San Francisco researchers who have outlined their vision of cell-based therapeutics as a “third pillar of medicine."
February 12, 2013
Stem cells of the aging bone marrow recycle their own molecules to survive and keep replenishing the blood and immune systems as the body ages, UCSF researchers have discovered.
October 10, 2012
For the first time, a clinical trial led by UCSF investigators and sponsored by Stem Cells Inc., has shown that transplanted neural stem cells appear to produce myelin in the brains of four young children with an early-onset, fatal disease.
September 13, 2012
Scientists at the UCSF-affiliated Gladstone Institutes have revealed the precise order and timing of hundreds of genetic “switches” required to construct a fully functional heart from embryonic heart cells — providing new clues into the genetic basis for some forms of congenital heart disease.