Capillary regression leads to sustained local hypoperfusion by inducing constriction of upstream transitional vessels

Proc Natl Acad Sci U S A. 2024 Sep 10;121(37):e2321021121. doi: 10.1073/pnas.2321021121. Epub 2024 Sep 5.

Abstract

In the brain, a microvascular sensory web coordinates oxygen delivery to regions of neuronal activity. This involves a dense network of capillaries that send conductive signals upstream to feeding arterioles to promote vasodilation and blood flow. Although this process is critical to the metabolic supply of healthy brain tissue, it may also be a point of vulnerability in disease. Deterioration of capillary networks is a feature of many neurological disorders and injuries and how this web is engaged during vascular damage remains unknown. We performed in vivo two-photon microscopy on young adult mural cell reporter mice and induced focal capillary injuries using precise two-photon laser irradiation of single capillaries. We found that ~59% of the injuries resulted in regression of the capillary segment 7 to 14 d following injury, and the remaining repaired to reestablish blood flow within 7 d. Injuries that resulted in capillary regression induced sustained vasoconstriction in the upstream arteriole-capillary transition (ACT) zone at least 21 days postinjury in both awake and anesthetized mice. The degree of vasomotor dynamics was chronically attenuated in the ACT zone consequently reducing blood flow in the ACT zone and in secondary, uninjured downstream capillaries. These findings demonstrate how focal capillary injury and regression can impair the microvascular sensory web and contribute to cerebral hypoperfusion.

Keywords: capillary; cerebral blood flow; microbleed; pericyte; two-photon imaging.

MeSH terms

  • Animals
  • Arterioles / physiopathology
  • Brain / blood supply
  • Capillaries* / physiology
  • Cerebrovascular Circulation* / physiology
  • Male
  • Mice
  • Mice, Inbred C57BL
  • Vasoconstriction / physiology
  • Vasodilation / physiology