RESUMO
To enhance early diagnosis and treatment of Alzheimer·s disease (AD), understanding the pathological changes before symptoms arise is crucial. The continuum model of AD suggest that Aß beta (Aß) accumulation precedes symptoms by at least 15 years, with vascular changes detectable around this time. Disturbances in capillary flow dynamics have been linked to reduced oxygen delivery to brain tissue, but evidence in presymptomatic AD remains elusive. We examined capillary flow dynamics in presymptomatic Tg-SwDI mice and the capacity of carbonic anhydrase inhibitors (CAIs) to prevent capillary flow disturbances. Our study revealed capillary flow disturbances associated with alterations in capillary morphology, adhesion molecule expression, and Aß load in cognitively normal 9-10-month-old Tg-SwDI mice. Treated mice showed ameliorated capillary flow disturbances, enhanced oxygen availability, and reduced Aß load. These findings underscore the importance of capillary flow disturbances in presymptomatic AD and highlight CAIs· potential for preserving vascular integrity in early AD.
RESUMO
Systemic inflammation affects cognitive functions and increases the risk of dementia. This phenomenon is thought to be mediated in part by cytokines that promote neuronal survival, but the continuous exposure to which may lead to neurodegeneration. The effects of systemic inflammation on cerebral blood vessels, and their provision of adequate oxygen to support critical brain parenchymal cell functions, remains unclear. Here, we demonstrate that neurovascular coupling is profoundly disturbed in lipopolysaccharide (LPS) induced systemic inflammation in awake mice. In the 24 hours following LPS injection, the hyperaemic response of pial vessels to functional activation was attenuated and delayed. Concurrently, under steady-state conditions, the capillary network displayed a significant increase in the number of capillaries with blocked blood flow, as well as increased duration of 'capillary stalls'-a phenomenon previously reported in animal models of stroke and Alzheimer's disease pathology. We speculate that vascular changes and impaired oxygen availability may affect brain functions following acute systemic inflammation and contribute to the long-term risk of neurodegenerative changes associated with chronic, systemic inflammation.