As the largest resource of information specific to women's brain health, we are sure you will find what you are looking for, and promise that you will discover new information.
Published on: June 25, 2019
by Leigh Hopper for USC Health:
USC researchers have discovered a secret sauce in the brain’s vascular system that preserves the neurons needed to keep dementia and other diseases at bay.
The finding, in a mouse model of the human brain, focuses on a specific cell called a pericyte and reveals that it plays previously unknown role in brain health. Pericytes secrete a substance that keeps neurons alive, even in the presence of leaky blood vessels that foul brain matter and result in cognitive decline.
The study, which appears today in Nature Neuroscience, helps explain the cascade of problems that lead to neurodegeneration after stroke or traumatic brain injury, as well as in diseases like Alzheimer’s and Parkinson’s — and suggests a potential strategy for therapy.
“What this paper shows is if you lose these vascular cells, you start losing neurons. The link with neurodegeneration was really not that clear before,” said senior author Berislav Zlokovic, director of the Zilkha Neurogenetic Institute at the Keck School of Medicine of USC.
The discovery comes at a time when scientists are beginning to understand Alzheimer’s disease as the result of multiple processes that begin long before memory loss sets in. Many researchers are shifting their focus from the amyloid plaques that accumulate in the brain later in life toward other targets earlier in the timeline.
Zlokovic, for example, studies the layers of cells that make up blood vessels in the brain. His previous research shows that the more permeable — or leaky — a person’s brain capillaries are, the more cognitive disability they have.
How these findings may help prevent Alzheimer’s
For this new experiment in mice, Zlokovic zeroed in on pericytes in the brain’s blood vessels. Pericytes help regulate blood flow and keep blood vessel walls sealed tight. When researchers artificially removed pericytes, they saw rapid degeneration of the blood-brain barrier, a slowdown of blood flow and the loss of brain cells.
To further understand their role, the scientists infused mice with a protein, or growth factor, secreted by pericytes in the brain and not found elsewhere in the body. They found that, even with pericyte cells artificially removed, the growth factor protected neurons and the brain cells didn’t die. The results persisted even with constricted blood flow.
Because these pericytes are implicated in many diseases — including Huntington’s, Parkinson’s, stroke, brain trauma and amyotrophic lateral sclerosis — the research offers intriguing possibilities for further investigation.
“This opens up an entirely new view of the possible pathogenesis of Alzheimer’s disease,” Zlokovic said.
Source: https://news.usc.edu/158535/study-pericytes-prevent-alzheimers-brain-health/
Having a paying job might shield women from memory loss decades later, according to a new study. That’s because paid work may offer mental stimulation, financial benefits and social connections that could limit declines in...
New research reported at the Alzheimer’s Association International Conference (AAIC) 2019 in Los Angeles evaluates drug and non-drug treatments to improve sleep patterns in persons with Alzheimer’s disease or other dementias. Sleep disruption is a common behavioral challenge that...
Sharon Stone, Rumer Willis, Andie MacDowell and Jane Seymour all gathered at the Eric Buterbaugh Gallery on Wednesday night for an event to discuss Women’s Brain Health Initiative, a charitable organization dedicated to...
The material presented through the Think Tank feature on this website is in no way intended to replace professional medical care or attention by a qualified practitioner. WBHI strongly advises all questioners and viewers using this feature with health problems to consult a qualified physician, especially before starting any treatment. The materials provided on this website cannot and should not be used as a basis for diagnosis or choice of treatment. The materials are not exhaustive and cannot always respect all the most recent research in all areas of medicine.
