Region-specific and Agent-specific Dilation of Intracerebral Microvessels by Volatile Anesthetics in Rat Brain Slices
Overview
Affiliations
Background: Volatile anesthetics are potent cerebral vasodilators. Although the predominant site of cerebrovascular resistance is attributed to intracerebral arterioles, no studies have compared the actions of volatile anesthetics on intraparenchymal microvessels. The authors compared the effects of halothane and isoflurane on intracerebral arteriolar responsiveness in hippocampal and neocortical microvessels using a brain slice preparation.
Method: After Institutional Review Board approval, hippocampal or neocortical brain slices were prepared from anesthetized Sprague-Dawley rats and placed in a perfusion-recording chamber, superfused with artificial cerebrospinal fluid. Arteriolar diameters were monitored with videomicroscopy before, during, and after halothane or isoflurane were equilibrated in the perfusate. PGF2alpha preconstricted vessels before anesthetic administration. A blinded observer using a computerized videomicrometer analyzed diameter changes.
Results: Baseline microvessel diameter and the degree of preconstriction were not different between groups. In the hippocampus, the volatile agents produced similar, concentration-dependent dilation (expressed as percent of preconstricted control +/- SEM) of 68 +/- 6% and 79 +/- 9% (1 MAC) and 120 +/- 3% and 109 +/- 5% (2 MAC) (P < 0.05) during halothane and isoflurane, respectively. In the cerebral cortex, isoflurane caused significantly less vasodilation than did similar MAC levels of halothane (84 +/- 9% vs. 42 +/- 5% dilation at 1 MAC; 121 +/- 4% vs. 83 +/- 5% dilation at 2 MAC halothane vs. isoflurane, respectively).
Conclusion: Halothane and isoflurane differentially produce dose-dependent dilation of intraparenchymal cerebral microvessels. These findings suggest that local effects of the volatile anesthetics on intracerebral microvessel diameter contribute significantly to alterations in cerebrovascular resistance and support previously described heterogeneous actions on cerebral blood flow produced by these agents.
Zhou H, Neudecker V, Perez-Zoghbi J, Brambrink A, Yang G Commun Biol. 2024; 7(1):1519.
PMID: 39548262 PMC: 11568297. DOI: 10.1038/s42003-024-07200-7.
Short-term hyperoxia-induced functional and morphological changes in rat hippocampus.
Hencz A, Magony A, Thomas C, Kovacs K, Szilagyi G, Pal J Front Cell Neurosci. 2024; 18:1376577.
PMID: 38686017 PMC: 11057248. DOI: 10.3389/fncel.2024.1376577.
The impact of vasomotion on analysis of rodent fMRI data.
Lambers H, Wachsmuth L, Lippe C, Faber C Front Neurosci. 2023; 17:1064000.
PMID: 36908777 PMC: 9998505. DOI: 10.3389/fnins.2023.1064000.
Shumkova V, Sitdikova V, Rechapov I, Leukhin A, Minlebaev M Sci Rep. 2021; 11(1):9567.
PMID: 33953244 PMC: 8099888. DOI: 10.1038/s41598-021-88461-8.
Ultra-high field (10.5 T) resting state fMRI in the macaque.
Yacoub E, Grier M, Auerbach E, Lagore R, Harel N, Adriany G Neuroimage. 2020; 223:117349.
PMID: 32898683 PMC: 7745777. DOI: 10.1016/j.neuroimage.2020.117349.