Abstract
We examined the diameter responses of isolated and pressurized posterior cerebral artery branches to various static and dynamic pressure alterations. These vessels, dissected from an anatomically identifiable location in the rat brain, developed tone when placed in a normal calcium physiological salt solution (1.6 mM Ca-PSS). Following a series of transmural pressure steps (Δp) of 25 or 50 mm Hg completed in 1–2 s and made every 5 min, they attained additional tone resulting in a mean luminal diameter of 139 μm at 100 mm Hg which was 35% less than their relaxed size measured in 1 mM EGTA-PSS. Continuous measurements of wall thickness and lumen diameter were obtained using a video electronic system in 1–2 mm long arterial segments, and autoregulatory gain factors calculated. Myogenic responses were obtained from each of 6 vessels taken from 6 WKY rats. Diameters following the step pressure changes were usually stable within 2–4 min. The data defined a myogenic regulatory pressure range from 49–145 mm Hg. Gain values averaged about 17% of that necessary for these arteries to maintain perfect flow autoregulation. Our results for myogenicity are comparable with the pressure range for blood flow autoregulation reported by others for the rat. We conclude that myogenic mechanisms, at least in this size artery, are partly responsible for flow autoregulation, and that they are supplemented by metabolic mechanisms operative in the intact rat brain.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barry, D.I., S. Strandgaard, D.I. Graham, O. Braendstrup, U.G. Svendsen, S. Vorstrup, R. Hemmingsen and T.G. Bolwig. Cerebral blood flow in rats with renal and spontaneous hypertension: Resetting the lower limit of autoregulation.J. Cerebral Blood Flow and Metabolism 2:347–353, 1982.
Brann, L., W. Halpern and S. Mongeon. Spontaneous contractions and intrinsic tone in small cerebral arteries of the hypertensive rat. (Abstract).Fed. Proc. 40:340, 1981.
Folkow, B. Description of the myogenic hypothesis.Circ. Res. XIV and XV (Suppl.):I—279—287, 1964.
Fujishima, M. and T. Omae. Lower limit of cerebral autoregulation in normotensive and spontaneously hypertensive rats.Experientia 32:1019–1021, 1976.
Gross, P.M., A.M. Harper and D.I. Graham. Cerebral blood flow in rats during physiological and humoral stimuli.Stroke 12:345–352, 1981.
Halpern, W., S.A. Mongeon and D.T. Root. Stress, tension and myogenic aspects of small isolated extraparenchymal rat arties. InSmooth Muscle Contraction, edited by N.L. Stephens. New York: Dekker, 1984.
Halpern, W., G. Osol and G.S. Coy. Mechanical behavior of pressurized in-vitro pre-arteriolar vessels determined with a video system.Annals Biomed. Eng. 12:463–482, 1984.
Harper, S.L., H.G. Bohlen and M.J. Rubin. Arterial and microvascular contributions to cerebral cortical autoregulation in rats.Am. J. Physiol. 246:H17-H24, 1984.
Heistad, D.D. and H.A. Kontos. Cerebral circulation. InHandbook of Physiology. Peripheral Circulation and Organ Blood Flow, edited by J.T. Shepard and F.M. Abboud. Am. Physiol. Soc. The Cardiovascular System III, 137–182, 1983.
Heistad, D.D., M.L. Marcus and F.M. Abboud. Role of large arteries in regulation of cerebral blood flow in dogs.J. Clin. Invest. 62:761–768, 1978.
Hernandez, M.J., R.W. Brennan and G.S. Bowman. Cerebral blood flow autoregulation in the rat.Stroke 9:150–155, 1978.
Johnson, P.C. The myogenic response. InHandbook of Physiology. The Cardiovascular System, edited by D.F. Bohr, A.P. Somlyo and H.V. Sparks, Jr. Am. Physiol. Soc., Sect. 2, Vol. II, pp. 409–442, 1980.
Kontos, H.A., E.P. Wei, R.M. Navari, J.E. Levasseur, W.I. Rosenblum and J.L. Patterson, Jr. Responses of cerebral arteries and arterioles to acute hypotension and hypertension.Am. J. Physiol. 234:H371–383, 1978.
Koo, A. and K.K. Cheng. Cerebral microvascular volume flow: Its measurement and responses to hemorrhagic hypotension in the rat.Microvascular Res. 8:151–155, 1974.
Nakayama, K. Calcium-dependent contractile activation of cerebral artery produced by quick stretch.Am. J. Physiol. 242:H760-H768, 1982.
Norris, C.P., G.E. Barnes, E.E. Smith and H.J. Granger. Autoregulation of superior mesenteric flow in fasted and fed dogs.Am. J. Physiol. 237:H174-H177, 1979.
Root, D.T. and W. Halpern. Demonstration of myogenic responses in isolated pre-arteriole cerebral vessels of the rat. (Abstract).Fed. Proc. 40:381, 1981.
Sadoshima, S. and D.D. Heistad. Regional cerebral blood flow during hypotension in normotensive and stroke-prone spontaneously hypertensive rats: Effect of sympathetic denervation.Stroke 14:575–579, 1983.
Sadoshima, S., D.W. Busija and D.D. Heistad. Mechanisms of protection against stroke in stroke-prone spontaneously hypertensive rats.Am. J. Physiol. 244:H406-H412, 1983.
Stromberg, D.D. and J.R. Fox. Pressures in the pial arterial microcirculation of the cat during changes in systemic arterial blood pressure.Circ. Res. XXXI:229–239, 1972.
Vinall, P.E. and F.A. Simeone. Cerebral autoregulation: An in vitro study.Stroke 12:640–642, 1981.
Wei, E.P. and H.A. Kontos. Responses of cerebral arterioles to increased venous pressure.Am. J. Physiol. 243:H442-H447, 1982.
Author information
Authors and Affiliations
Additional information
Research supported by grant HL 17335 from the NHLBI.