Tuesday, April 1, 2025
4/1/2025
Hypoperfusion, Hemodynamic Control Domains and Neurovascular Dysregulation in AD brain pathology - Alzheimer’s Disease [AD] is a progressive degenerative disorder of unclear etiology and disease-modifying treatments remain elusive. Abnormal neurovascular regulation can lead to reduced substrate supply to brain, including capillary and small vessel pericyte regulation with neuronal activity, conduction from small vessels to larger scale vessels, and hemodynamic responses to neuronal activity. Neurovascular regulation mechanisms in the context of the aging brain can be differentiated from the premature aging and progressive neurodegeneration associated with AD and dementia syndrome. Early pathological neurovascular and metabolic alterations can reduce substrate delivery to the AD brain. Though brain metabolism is altered during aging, AD demonstrates more severe and premature metabolic insufficiency in comparison to age-matched controls, attributable to neurovascular dysregulation at multiple levels. We will analyze mechanisms of neurovascular regulation occurring in age-matched control genotypes (both wildtype C57Bl/6 and mNOS2-/-) compared to the progressive degeneration noted in the CVN-AD animal model of Alzheimer’s disease (APPSwDI +/+ mNos2−/−). This unique mouse model closely mirrors human phenotypic changes, particularly amyloid plaques around blood vessels, phosphorylated tau, and severe neurodegeneration. Our hypothesis is that degeneration, as noted in both human AD and the relevant CVN-AD animal model, is worsened by premature aging changes in substrate supply at the capillary, pericyte, conduction, and hemodynamic levels. Metabolic insufficiency can arise particularly from abnormal neurovascular coupling and conduction from small to larger vessels, blunting the hemodynamic response to dynamic neuronal activity. The CVN-AD model mirrors human AD phenotypes with a predictable time course of behavioral, vascular and circuit degeneration in relation to aging changes hence provides an appropriate pre- clinical, translational model for analyzing these concepts. We will study novel approaches to evaluating mechanisms of neurovascular regulation including chemogenetic approaches at the pericyte, mural wall cell level, assessing activity and conduction to larger capacity cerebral vessels, neurovascular coupling and hemodynamic responses, to understand dynamic mechanisms of hypoperfusion at critical times of substrate need, in both hippocampus and neocortex as a function of genotype, gender, and age.
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