Abstract 12907: Aging Drives Cerebrovascular Network Remodeling and Functional Changes in the Mouse Brain

Abstract

Introduction: Cerebrovascular dysfunction has been implicated in age-related cognitive decline and dementia, but the underlying vascular mechanisms are not well understood. An improved understanding of the nature of normal cerebrovascular aging is needed to help to establish the role that vascular dysfunction might play in cognitive decline and dementia. Methods: Here, we asked how normal aging differentially impacts the vascular structure and function in different brain areas in mice. We investigated structural changes in aged cerebrovascular networks and pericytes utilizing serial two-photon tomography (STPT). To further investigate potential remodeling of different vascular compartments and pericyte subtypes, we utilized tissue clearing, 3D immunolabeling, and light sheet fluorescence microscopy (LSFM) imaging. We also assessed how healthy aging impacts brain hemodynamics in response to voluntary locomotion and whisker stimulation in awake, head-fixed mice using wide field optical signal imaging and two-photon imaging. We tested mice of both sexes at 2-month, 18-month (early aging), and 24-month (late aging) of age. Results: Whole-brain vascular tracing using STPT showed an overall ~10% decrease in vascular length and branching density, and LSFM imaging with 3D immunolabeling further revealed increased arteriole tortuosity in aged brains. We also uncovered a selective vascular and pericyte loss in deep cortical layers, basal forebrain regions, and the hippocampal network. This may contribute to their regional vulnerabilities in neurodegenerative disorders. Moreover, our in vivo imaging in awake, head-fixed mice identified delayed neurovascular coupling response and inefficient oxygen delivery in aged brains. Conclusions: Our study reveals aging-related brain-wide changes in vascular and mural cell types that can explain vulnerability and resilience of different brain areas in normal aging. Moreover, we identified an age-related decrease in brain oxygenation and delayed neurovascular coupling responses which can be linked with cognitive impairment in aged brains. These aging-related changes will serve as a common factor to understand many neurodegenerative disorders and cognition decline in the elderly population.