DNA looping, or folding, directs a cell's developmental fate. Harnessing this 'DNA origami' could help researchers generate specific tissues for therapies.
Is extensive regeneration possible in humans? Stanford researchers show skeletal stem cells can move backward developmentally when major repairs are needed.
A Stanford team has developed an algorithm that uses data about tumors to identify new classifications that can provide information about patient outcomes
A Stanford-designed computer algorithm helps doctors predict the lifespan of patients with metastatic cancer by looking for clues in their own exam notes.
Stanford researchers have learned that cancer cells can batter their way into new territory, rather than relying on dissolving chemicals.
'Mitotic catastrophe' hampers the ability of aged muscle stem cells to repair damage. Manipulating this process could lead to new therapies for old muscle.
Hiding mRNA messages in CARTs — positively charged degradable vehicles —smuggles them across the cell membrane and can 'vaccinate' against cancer in mice.
Discovery of the human skeletal stem cell opens the way to regenerate cartilage and bone to repair damaged tissues, say Stanford scientists.
Online outreach and low-cost testing can encourage relatives of cancer patients to assess their own cancer risk through 'cascade' testing.
Mapping the geography of the immune response in triple negative breast cancers predicts patient survival and sheds light onto new aspects of tumor biology.
Heart muscle cells from people with cardiomyopathies have shorter-than-normal telomeres -- the protective caps on chromosomes associated with aging.
Monitoring changes in the levels of circulating bits of tumor DNA may help some lymphoma patients avoid unnecessary chemotherapy, Stanford researchers find.
Humans' big brains may increase the risk of psychiatric disorders. Stanford researchers identify previously hidden DNA region that could be to blame.
People who develop abnormal numbers of skin cancers called basal cell carcinomas may be at increased risk of other, unrelated internal cancers.
A genetic test may predict at an early age those likely to develop osteoporosis. Knowing your risk may allow easy interventions to prevent future fractures.
Stanford researchers identify a new protein that can fully substitute for one of the key "Yamanaka factors" to reprogram adult stem cells.