The purpose of this study was to investigate the receptor subtypes that mediate the dilation of rat intracerebral arterioles elicited by adenosine. Penetrating arterioles were isolated from the rat brain, cannulated with the use of a micropipette system, and luminally pressurized to 60 mmHg. Both adenosine and the A2A receptor-selective agonist CGS-21680 induced dose-dependent vasodilation (-logEC(50): 6.5 +/- 0.2 and 8.6 +/- 0.3, respectively). However, adenosine, which is capable of activating both A2A and A2B receptors, caused a greater maximal dilation than CGS-21680. The A2A receptor-selective antagonist ZM-241385 (0.1 microM) only partially inhibited the dilation induced by adenosine but almost completely blocked CGS-21680-induced dilation. Neither 8-cyclopentyl-1,3-dipropylxanthine (0.1 microM), an A1 receptor-selective antagonist, nor MRS-1191 (0.1 microM), an A3 receptor-selective antagonist, attenuated adenosine dose responses. Moreover, ZM-241385 had no effect on the dilation induced by ATP (10 microM) or acidic (pH 6.8) buffer. We concluded that the A2A receptor subtype mediates adenosine-induced dilation of intracerebral arterioles in the rat brain. Furthermore, our results suggest that A2B receptors may also participate in the dilation response to adenosine.
We determined whether cerebral arterioles in vitro adjust their diameters in response to changes in intraluminal flow rate and pressure. Intracerebral arterioles (38- to 55-microns diameter) were isolated from Sprague-Dawley rats and cannulated with a perfusion system that permitted separate control of intraluminal pressure and flow rates. Increasing pressure at 0 flow, in 20 mm Hg steps from 20 to 100 mm Hg, resulted in myogenic constriction, which was greatest at 60 mm Hg (approximately 20%). Increasing flow rate at a constant pressure of 60 mm Hg elicited a biphasic response. At flow rates of up to 10 microL/min, the arterioles dilated by up to 14.5 +/- 2.2% of their control diameter. At higher (> 10 microL/min) flow rates, however, a progressive restoration of resting diameter was observed. Application of the nitric oxide synthase inhibitor NG-mono-methyl-L-arginine (L-NMMA, 0.1 mmol/L) caused a 15.4 +/- 1.7% decrease in control diameter (at 60 mm Hg, zero flow). Although L-NMMA did not affect the responses to increases in pressure or to vasodilators (adenosine and pH 6.8 buffer), it abolished the dilator responses to flow rate increases and to acetylcholine. In contrast, inhibition of prostaglandin synthesis by indomethacin (10 mumol/L) had no effect on flow-induced dilation. These results show that changes in intraluminal flow rates and pressure can independently influence cerebral arteriolar tone and suggest that the flow-induced dilator responses of cerebral arterioles are mediated by an arginine metabolite, such as nitric oxide.
The present study documents the microvascular response of the pial circulation in sensory hindlimb cortex to sciatic nerve stimulation. Rats, anesthetized with alpha-chloralose and urethan, were equipped with closed cranial windows, and pial arteriolar diameter was measured during stimulation of the contralateral sciatic nerve. The effects of varying stimulus frequency, intensity, and duration were examined. Optimal stimulus frequency was 5 Hz, but response diminished significantly beyond 10 Hz. Optimal stimulus intensity was 0.2 V. At higher stimulus strength, arteriolar dilation was reduced, but systemic blood pressure rose significantly. At low stimulus frequency and intensities, pial arterioles responded to stimulation with a consistent pattern: initial delay of 1.4 s followed by abrupt dilation to a peak magnitude, subsequent decline to a lesser but still dilated state, and recovery to a resting diameter after the cessation of stimulation. No consistent response profile was discernible at high stimulus intensity and/or frequency. This vasodilatory response was discretely restricted to a limited number of arterioles, confined to the hindlimb somatosensory cortex as confirmed by sensory evoked response. The response of the pial circulation provides a well-characterized model for analysis of brain microcirculation, which presumably is linked to cerebral metabolism.
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