Long-wavelength traveling waves of vasomotion modulate the perfusion of cortex

Thomas Broggini, Jacob Duckworth, Xiang Ji, Rui Liu, Xinyue Xia, Philipp Mächler, Iftach Shaked, Leon Paul Munting, Satish Iyengar, Michael Kotlikoff, Susanne J. van Veluw, Massimo Vergassola, Gal Mishne, David Kleinfeld

Research output: Contribution to journalArticlepeer-review

Abstract

Brain arterioles are active, multicellular complexes whose diameters oscillate at ∼ 0.1 Hz. We assess the physiological impact and spatiotemporal dynamics of vaso-oscillations in the awake mouse. First, vaso-oscillations in penetrating arterioles, which source blood from pial arterioles to the capillary bed, profoundly impact perfusion throughout neocortex. The modulation in flux during resting-state activity exceeds that of stimulus-induced activity. Second, the change in perfusion through arterioles relative to the change in their diameter is weak. This implies that the capillary bed dominates the hydrodynamic resistance of brain vasculature. Lastly, the phase of vaso-oscillations evolves slowly along arterioles, with a wavelength that exceeds the span of the cortical mantle and sufficient variability to establish functional cortical areas as parcels of uniform phase. The phase-gradient supports traveling waves in either direction along both pial and penetrating arterioles. This implies that waves along penetrating arterioles can mix, but not directionally transport, interstitial fluids.

Original languageEnglish
Pages (from-to)2349-2367.e8
JournalNeuron
Volume112
Issue number14
DOIs
StatePublished - 17 Jul 2024
Externally publishedYes

Keywords

  • adaptive optics
  • brain blood flow
  • functional hyperemia
  • gymphatics
  • interstitial fluids
  • neurovascular
  • penetrating arterioles
  • peristalsis
  • pial arterioles
  • two-photon microscopy

All Science Journal Classification (ASJC) codes

  • General Neuroscience

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