Research Begun by WHRY Continues to Show Possible Pathway to Derail Dementia
Research is revealing the mechanisms that underlie the role of estradiol in memory so that next generation treatments for Alzheimer's disease and other dementias can specifically target these mechanisms and avoid the potential for negative side effects of systemic estrogen therapy.
Alzheimer's Disease Research Center will hold a research day on Feb. 12
The Alzheimer's Disease Research Center will be hosting a Research Day, which will include a series of lectures on current research studies on Alzheimer's Disease. The following Investigators will be presenting: Christopher van Dyck, MD; Jason Cai, PhD; Amy Arnsten, PhD; Morgan Levine, PhD; Nenad Sestan, MD,PhD; In Hyun Park, PhD; and Flora Vaccarino, MD.
MRI's Motivated by Mom
A lifetime resident of New Haven County, Kathy (71) is also a longtime supporter of clinical research at Yale. She has volunteered for many studies involving MRI (Magnetic Resonance Imaging) machines, a technique used for visualizing the brain without radiation, so scientists can learn more about the brain and clinicians will be better equipped to treat the many diseases associated with it. One of these, Alzheimer’s disease, is what first inspired Kathy to participate in research when she lost her mother to the condition.
How do we lose memory? A STEP at a time, researchers say
In mice, rats, monkeys, and people, aging can take its toll on cognitive function. A new study by researchers at Yale and Université de Montréal reveal there is a common denominator to the decline in all of these species — an increase in the level of the molecule striatal-enriched phosphatase, or STEP.
Brain’s ‘insulation’ continues to form throughout life
Myelin acts as insulation for millions of brain cells, allowing for swift and efficient transmission of signals across brain regions. Despite its crucial role, little is known about how stable this structure is in the adult brain and what impact aging has on its maintenance. Yale neurologists Robert Hill, Alice Li, and Jaime Grutzendler devised techniques to track and precisely image myelin throughout the lifetime of the mouse. They discovered that myelin continues to form and restructure in the adult brain — indicating the potential for lifelong change. They also learned that during aging, myelin begins to deteriorate and myelin debris accumulate over time.
Barrier Function: TREM2 Helps Microglia to Compact Amyloid Plaques
New research bolsters the case that brain-derived microglia need TREM2 to essentially wall off amyloid plaques, but exactly how they do that remains up for debate. As reported in the May 18 Neuron, scientists led by Jaime Grutzendler at Yale University, New Haven, Connecticut, used confocal and super-resolution microscopy to show that TREM2-positive microglia surround and encase amyloid fibrils, protecting neurons in the process. Yet TREM2 itself appears to lend little support to phagocytosis of Aβ. The technical caliber of the work and the quality of the microscopy led researchers in the AD field to call the study “stunning.” It comes on the heels of another paper, in the April 18 Journal of Experimental Medicine, which suggests the microglia that surround plaques are brain-derived, not peripheral myeloid cells as others had suggested previously.Source: Barrier Function: TREM2 Helps Microglia to Compact Amyloid Plaques
Immune cells may act as ‘trash compactors, protecting against Alzheimer’s
In the battle against Alzheimer’s disease, inflammation may be an ally, not a foe, a new study has found. Immune cells in the brain previously blamed for Alzheimer’s actually protect against the disease by corralling the damage-causing amyloid plaques, according to the Yale University study, published Wednesday in the journal Neuron. The findings suggest that inflammation byproducts of these immune cells, known as microglia, probably don’t cause Alzheimer’s, nor are they as effective as previously believed at “gobbling up” the plaques, both of which have been hypothesized, said Jaime Grutzendler,associate professor of neurology and neuroscience and the study’s lead author. Rather, he said, the cells act as a physicalbarrier that encloses the spiky plaques, preventing outward expansion and making them less toxic. “They’re sort of like garbage compactors,” he said. “They tightly surround the plaques and make them inert and less damaging . . . by creating a capsule.”
Research in the news: Hyperactive neurons may be culprit in Alzheimer’s
A long-term reduction in neuronal activity reduces amyloid plaques associated with Alzheimer’s disease, Yale University researchers have found. The study, using mouse models of Alzheimer’s, found the opposite is also true — triggering an increase in neuronal activity spurs creation of plaques and toxic amyloid beta peptides believed to trigger the disease.