Computational network model prediction of hemodynamic alterations due to arteriolar remodeling in interval sprint trained skeletal muscle

OBJECTIVES: Exercise training is known to enhance skeletal muscle blood flow capacity, with high-intensity interval sprint training (IST) primarily affecting muscles with a high proportion of fast twitch glycolytic fibers. The objective of this study was to determine the relative contributions of new arteriole formation and lumenal arteriolar remodeling to enhanced flow capacity and the impact of these adaptations on local microvascular hemodynamics deep within the muscle. METHODS: The authors studied arteriolar adaptation in the white/mixed-fiber portion of gastrocnemius muscles of IST (6 bouts of running/day; 2.5 min/bout; 60 m/min speed; 15% grade; 4.5 min rest between bouts; 5 training days/wk; 10 wks total) and sedentary (SED) control rats using whole-muscle Microfil casts. Dimensional and topological data were then used to construct a series of computational hemodynamic network models that incorporated physiological red blood cell distributions and hematocrit and diameter dependent apparent viscosities. RESULTS: In comparison to SED controls, IST elicited a significant increase in arterioles/order in the 3A through 6A generations. Predicted IST and SED flows through the 2A generation agreed closely with in vivo measurements made in a previous study, illustrating the accuracy of the model. IST shifted the bulk of the pressure drop across the network from the 3As to the 4As and 5As, and flow capacity increased from 0.7 mL/min in SED to 1.5 mL/min in IST when a driving pressure of 80 mmHg was applied. CONCLUSIONS: The primary adaptation to IST is an increase in arterioles in the 3A through 6A generations, which, in turn, creates an approximate doubling of flow capacity and a deeper penetration of high pressure into the arteriolar network.     

Regional Changes in Capillary Supply in Skeletal Muscle of Interval-Sprint and Low-Intensity,Endurance-Trained Rats

Objective: Exercise training produces regional increases in blood flow capacity among muscle fibers that experience increased activity during exercise. We tested the hypothesis that this increase is partially due to capillary angiogenesis among muscle fibers with large increases in activity during exercise training bouts. Methods: Two training programs were evaluated: a program consisting of 10–12 weeks of exposure to low-intensity (30 m/min, 0 incline, 60 min/day) (LET) exercise bouts, 5 days/week, and a second program consisting of 8–10 weeks of exposure to repetitive bouts (6/day) of sprint (60 m/min, 15% incline) exercise, alternating running (2.5 min) and recovery (4.5 min), 5 days/week (IST). Cage-confined rats were utilized (SED) as controls. After training was completed, rat hindquarters were perfusion-fixed with modified Karnovsky's fixative. Transverse sections from soleus (Sol), and red (G_R), mixed (G_M), and white (G_W) portions of gastrocnemius muscle were prepared to evaluate capillarization. Sections were analyzed using the Olympus Cue 2 Image Analyzer to determine capillary/muscle fiber ratio (C/F), number of capillary profiles per square millimeter of muscle area (CND), capillary surface area per volume of tissue, and capillary volume density. Results: Average area per muscle fiber and sarcomere length did not differ among groups. LET did not affect capillarization of the G_W, whereas increasing C/F in G_M (2.3 ± 0.1 versus 2.1 ± 0.1 for SED) and G_R (3.0 ± 0.1 versus 2.6 ± 0.1 for SED). IST increased C/F and CND in G_W (1.6 ± 0.1 versus 1.3 ± 0.0 for SED and 657 ± 74 versus 418 ± 53 for SED, respectively) and increased C/F ratio in G_M (2.3 ± 0.1 versus 2.1 ± 0.1 for SED). IST did not increase capillarization of the G_R. The capillarization of the soleus muscle was not affected by either exercise training program. Conclusions: IST increased capillarization in muscle tissue composed of a high percentage of fast glycolytic fibers (G_W and G_M) and LET increased capillarization of muscle tissue composed of a high percentage of fast oxidative-glycolytic fibers (G_M and G_R).     

Decreased arteriolar sensitivity to shear stress in adult rats is reversed by chronic exercise activity

OBJECTIVE: We tested the hypothesis that the decline in endothelium-dependent arteriolar dilation in adult rats is reversed by chronic exercise activity. METHODS: Rats were divided into young (8-10 weeks)-sedentary (SED(Y)), adult (29-32 weeks)-sedentary (SED(A)), and adult-exercised (EX(A), treadmill exercise for 18-20 weeks) groups. Responses of isolated arterioles ( approximately 50 microm at 80 mm Hg) of gracilis muscle were assessed to increases in perfusate flow and vasoactive agents. RESULTS: With no differences in basal tone, maximal flow-induced dilations were not different between arterioles of SED(Y) and SED(A) rats (71 +/- 2 and 72 +/- 2% of passive diameter, respectively), yet the sensitivity of arterioles to shear stress (WSS(50)) was significantly less in SED(A) than in SED(Y) rats (35 +/- 4 vs. 23 +/- 3 dyne/cm(2), respectively). In vessels of EX(A) rats, maximal flow-induced dilation was significantly augmented (88 +/- 2% of passive diameter) and WSS(50) (15 +/- 1 dyn/cm(2)) was significantly reduced. Dilation to acetylcholine was enhanced in arterioles of EX(A), whereas dilation to sodium nitroprusside was not different in vessels of the three groups. CONCLUSION: Chronic exercise activity reverses age related reduction in sensitivity of arterioles to increases in wall shear stress.     

Endothelin and prostaglandin H(2)/thromboxane A(2) enhance myogenic constriction in hypertension by increasing Ca(2+) sensitivity of arteriolar smooth muscle

The myogenic response of skeletal muscle arterioles is enhanced in hypertension because of the release of endothelin (ET) and prostaglandin H(2) (PGH(2))/thromboxane A(2) (TxA(2)) from the endothelium. We hypothesized that ET and PGH(2)/TxA(2) modulate Ca(2+) signaling in arteriolar smooth muscle and thereby enhance myogenic constriction. Thus, simultaneous changes in intracellular Ca(2+) concentration in smooth muscle ([Ca(2+)](i)), measured by fura 2 microfluorometry (expressed as Ca(2+) fluorescence ratio [R(Ca)]), and diameter were obtained as a function of intraluminal pressure (P(i)) in isolated cannulated gracilis muscle arterioles (diameter approximately 120 micrometer) of normotensive Wistar rats (WR) and spontaneously hypertensive rats (SHR). In the absence of extracellular Ca(2+), increases in P(i) from 20 to 160 mm Hg increased the passive diameter of arterioles without changes in R(Ca). In the presence of extracellular Ca(2+) and endothelium, increases in P(i) elicited similar increases in R(Ca) (30+/-7% for control and 33+/-8% for SHR at 160 mm Hg) but a significantly (P<0.05) greater constriction of SHR arterioles compared with WR arterioles (at 160 mm Hg, 55+/-4% versus 38+/-2%, respectively, of passive diameter). In the absence of the endothelium, P(i)-induced changes in the R(Ca) and diameter of SHR and WR arterioles did not differ significantly. Also, a step increase in P(i) (from 80 to 140 mm Hg) elicited a similar increase in R(Ca) but greater constrictions in SHR versus WR arterioles. In the presence of the TxA(2) receptor inhibitor SQ29,548 and the ET(A) receptor inhibitor BQ123, there was no difference between responses of SHR and WR arterioles. In WR arterioles, increasing concentrations of KCl elicited a significant increase in R(Ca) (38+/-7% at 80 mmol/L) and completely constricted the arterioles. In contrast, constrictions to ET (52+/-7% at 3x10(-12) mol/L) and the TxA(2) agonist U46619 (40+/-8% at 3x10(-9) mol/L) were not accompanied by increases in R(Ca) at submaximal concentrations. Collectively, these findings suggest that in hypertension, endothelium-derived ET and PGH(2)/TxA(2) increase the Ca(2+) sensitivity of the contractile apparatus of arteriolar smooth muscle; thus, the similar increases in [Ca(2+)](i) in response to the elevation of intraluminal pressure elicit greater myogenic constriction.     

Endothelial K(ca) channels mediate flow-dependent dilation of arterioles of skeletal muscle and mesentery

The role of Ca(2+)-activated potassium channels (K(Ca)) in flow-initiated intracellular events in microvessels is not known. We hypothesized that K(Ca) channels in the arteriolar endothelium are responsible for the mechanotransduction of flow/shear stress-induced arteriolar dilation in skeletal muscle and mesentery of rats. The active diameter of arterioles isolated from gracilis (80 mm Hg) and cremaster (60 mm Hg) muscles and mesentery (80 mm Hg) at a constant intraluminal pressure was 53 +/- 3, 77 +/- 5, and 72 +/- 6 microm, respectively. Their passive diameter (in Ca(2+)-free solution) was 113 +/- 3, 152 +/- 12, and 121 +/- 7 microm, respectively. At a constant intraluminal pressure stepwise increases in perfusate flow (25, 40, and 14 microL/min in 5, 10, and 2 microL/min steps) elicited a gradual increase in diameter of all three groups of arterioles up to 93 +/- 5, 137 +/- 11, and 102 +/- 7 microm, respectively. Flow-induced dilations of arterioles were eliminated by intraluminal administration of iberiotoxin (ibTX 10(-9) M), an inhibitor of high conductance K(Ca) channels (BK(Ca)). In contrast, arteriolar dilations to acetylcholine and sodium nitroprusside were not altered by this agent, indicating that BK(Ca) channels are not involved in the receptor-mediated endothelial synthesis of nitric oxide (NO) and that the inhibitor did not affect the action of NO on smooth muscle. Abluminal application of ibTX (10(-8) M) did not affect flow-dependent dilation. We conclude that in arterioles of several tissues activation of endothelial BK(Ca) channels is an obligatory step in the transduction of the signal initiated by changes in intraluminal flow/shear stress, leading to the release of endothelial factors evoking dilation.     

Effects of an angiotensin-converting enzyme inhibitor and a beta-blocker on cerebral arterioles in rats

We examined the effects of an angiotensin-converting enzyme inhibitor, perindopril, and a beta-blocker, propranolol, on cerebral arterioles in stroke-prone spontaneously hypertensive rats (SHRSP). The structure and mechanics of cerebral arterioles were examined in untreated Wistar-Kyoto rats (WKY) and SHRSP that were untreated or treated for 3 months with a high (2 mg/kg per day) or a low (0.3 mg/kg per day) dose of perindopril or propranolol (250 mg/kg per day) alone or in combination with the low dose of perindopril. We measured pressure, external diameter, and cross-sectional area of the vessel wall (CSA) in maximally dilated (with EDTA) cerebral arterioles. Treatment of SHRSP with the high dose of perindopril or the combination of propranolol and the low dose of perindopril normalized cerebral arteriolar mean pressure (50+/-1 [mean+/-SEM] and 43+/-2 mm Hg vs 50+/-1 mm Hg in WKY and 94+/-3 mm Hg in untreated SHRSP; P<0.05), pulse pressure (15+/-1 and 16+/-1 mm Hg vs 13+/-1 mm Hg in WKY and 35+/-1 mm Hg in untreated SHRSP; P<0.05), and CSA (1103+/-53 and 1099+/-51 microm2, respectively, vs 1057+/-49 microm2 in WKY and 1281+/-62 microm2 in untreated SHRSP; P<0.05). In contrast, treatment of SHRSP with the low dose of perindopril or propranolol alone did not normalize arteriolar pulse pressure (24+/-1 and 21+/-1 mm Hg) and failed to prevent increases in CSA (1282+/-77 and 1267+/-94 microm2). Treatment with either dose of perindopril or the combination of propranolol and perindopril significantly increased external diameter in cerebral arterioles of SHRSP (99+/-3, 103+/-2, and 98+/-3 microm vs 87+/-2 microm in untreated SHRSP; P<0.05), whereas propranolol alone did not (94+/-3 microm; P>0.05). These findings suggest that effects of angiotensin-converting enzyme inhibitors on cerebral arteriolar hypertrophy in SHRSP may depend primarily on their effects on arterial pressure, particularly pulse pressure, whereas their effects on cerebral arteriolar remodeling (defined as a reduction in external diameter) may be pressure independent.     

Arteriolar diameter and tissue oxygen tension during muscle contraction in hypertensive rats

This study evaluated the possibility that in hypertension, mechanisms that maintain near normal arteriolar diameters at elevated arteriolar pressures limit the ability of skeletal muscle arterioles to dilate in response to an increase in tissue metabolism. The spinotrapezius muscles of 16- to 20-week-old spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY) were contracted at frequencies of 1, 2, 4, and 8 Hz. The inner diameters of first-order through third-order arterioles were measured at rest and following 3 minutes of contractions. Tissue oxygen tension (PO2) at the venous end of capillaries was monitored during 8-Hz contractions. At rest, following contractions, and after maximum dilation with adenosine, the inner diameters of arterioles of equivalent branch order were not significantly different in SHR and WKY. Opening of closed arterioles during muscle contraction and adenosine application occurred in less than 5% of the observations in both groups. The resting tissue PO2 was 25.5 +/- 1.3 mm Hg in normal rats and 26.1 +/- 2.1 mm Hg in SHR. At nearly maximum vasodilation during 8-Hz stimulation, tissue PO2 recovered to 81.9 +/- 12.7% of control in WKY but only to 41.2 +/- 13.0% of control in SHR. These observations indicate that the expression of local regulatory mechanisms related to tissue metabolism is virtually normal in the spinotrapezius muscle vasculature of SHR in the context of arteriolar dilation. However, at near maximum performance, factors other than absolute arteriolar diameter preclude the normal preservation of tissue PO2 in the spinotrapezius muscle of SHR.     

Effect of lovastatin on cerebral circulation in spontaneously hypertensive rats

Statins, which are often given to hypertensive patients, reduce the incidence of stroke. However, their effects on the cerebral circulation have been scarcely studied, although lovastatin has been reported to reduce hypertension-induced renal arteriolar hypertrophy. We examined the structure and mechanics of cerebral arterioles and the lower limit of cerebral blood flow (CBF) autoregulation in spontaneously hypertensive rats (SHR) that were untreated (n=9) or treated for 1 month with lovastatin (n=12; 20 mg x kg(-1) x d(-1)) and in untreated Wistar-Kyoto rats (WKY; n=8). We studied the lower limit of CBF autoregulation by repeated measurement of CBF (arbitrary units; laser Doppler) and internal arteriolar diameter (microm; cranial window) at baseline and during stepwise hypotension. Stress-strain relationships were calculated from repeated measurement of internal arteriolar diameter during stepwise hypotension and cross-sectional area (CSA) of the vessel wall in maximally dilated cerebral arterioles (EDTA, 67 mmol/L). Lovastatin slightly reduced mean arterial pressure (treated, 153+/-3 versus untreated, 171+/-5 mm Hg, P<0.05; WKY, 106+/-3 mm Hg) and normalized CSA (treated, 826+/-52 versus untreated, 1099+/-16 microm(2), P<0. 05; WKY, 774+/-28 microm(2)). Stress-strain curves show that lovastatin also attenuated the increase in passive distensibility. Lovastatin had no effect on the external diameter of cerebral arterioles or the lower limit of CBF autoregulation. Our results show that although lovastatin has substantial effects on arteriolar mechanics and wall CSA, it has little effect on internal diameter. This phenomenon may explain its lack of effect on CBF autoregulation.     

Chronic N(G)-nitro-L-arginine methyl ester treatment does not prevent flow-induced remodeling in mesenteric feed arteries and arcading arterioles

Although endothelium-derived NO is an important mediator in acute flow-induced changes in arterial tone, the role of NO in chronic flow-induced changes in the resistance artery and arteriolar structure remains largely unresolved. We investigated the effects of chronic inhibition of NO synthase on arterial and arteriolar remodeling in a rat mesenteric model in which flow changes were induced. Alternating first-order mesenteric arteries were ligated to shunt blood flow through the intermittent patent arteries. Animals received no treatment (NT) or a continuous infusion of N:(G)-nitro-L-arginine methyl ester (L-NAME, 25 mg/kg SC per day). After 2 weeks, local in vivo blood flow and in vitro arterial pressure-diameter relationships were assessed, as were the in situ diameters of arcading arterioles. Medial cross-sectional areas (CSAs) were measured histologically. In both groups of animals, blood flow was significantly increased in patent arteries and decreased in ligated arteries compared with control vessels. Nonetheless, in L-NAME-treated rats, patent artery flow was increased to a lesser extent, although control flow was not significantly reduced (0.18+/-0.05 versus 0.26+/-0.05 mL/min). In NT rats, the diameter of patent arteries was significantly larger and the diameter of ligated arteries was significantly smaller than that of control arteries. CSAs displayed the same pattern of change (11. 9+/-0.6 x 10(3), 6.1+/-0.7 x 10(3), and 8.2+/-1.0 x 10(3) microm(2) for patent, ligated, and control arteries, respectively). Arterioles in the NT collateral pathway (218+/-15 microm) had diameters similar to control arteriole diameters (201+/-15 microm) but had a significantly larger CSA (6.2+/-0.6 x 10(3) versus 4.2+/-0.4 x 10(3) microm(2)). In L-NAME-treated rats, the flow-induced changes of the diameter and CSA in patent arteries, ligated arteries, and arcading arterioles mimicked those in NT rats. Nonetheless, control feed arteries (430+/-21 versus 497+/-16 microm) and arcading arterioles (156+/-21 microm) were significantly narrower after L-NAME treatment. Thus, chronic blockade of NO oxide synthase (1) tended to reduce arterial blood flow and resulted in inward remodeling of mesenteric arteries and arterioles and (2) did not prevent arterial and arteriolar remodeling in response to imposed changes in blood flow. Endothelium-derived mediators other than NO can play a major role in flow-induced arterial remodeling.     

Effects of indapamide, a thiazide-like diuretic, on structure of cerebral arterioles in hypertensive rats

We examined the effects of indapamide, a thiazide-like diuretic, on cerebral arterioles in spontaneously hypertensive rats (SHR). The structure and mechanics of cerebral arterioles were examined in untreated Wistar Kyoto rats (WKY) and SHR that were untreated or treated for 3 months with a low (1 mg/kg per day) or a high (10 mg/kg per day) dose of indapamide. We measured pressure, diameter, and cross-sectional area of the vessel wall (CSA) in maximally-dilated (EDTA) cerebral arterioles. Treatment of SHR with the high dose of indapamide normalized cerebral arteriolar mean pressure (62+/-4 [mean+/-SEM] versus 59+/-3 mm Hg in WKY and 88+/-6 mm Hg in untreated SHR; P<0.05), pulse pressure (13+/-1 versus 10+/-1 mm Hg in WKY and 20+/-1 mm Hg in untreated SHR; P<0.05), and CSA (1080+/-91 versus 1100+/-48 microm2 in WKY and 1439+/-40 microm2 in untreated SHR; P<0.05). In contrast, treatment of SHR with the low dose of indapamide did not normalize arteriolar mean (72+/-3) and pulse pressure (20+/-1 mm Hg), but did normalize CSA (1091+/-52 microm2). Treatment with either dose of indapamide failed to increase external diameter in cerebral arterioles of SHR (89+/-4 and 92+/-4 microm, respectively, versus 103+/-6 microm in WKY and 87+/-4 microm in untreated SHR). Finally, treatment with indapamide attenuated the rightward shift of the stress-strain curve in SHR, suggesting that treatment with indapamide attenuated increases in distensibility of cerebral arterioles in SHR. These findings suggest that, whereas thiazide-like diuretics may not attenuate eutrophic inward remodeling of cerebral arterioles in SHR, they may attenuate hypertrophic inward remodeling via a mechanism unrelated to their pressor effects.     

Effects of local reduction in pressure on distensibility and composition of cerebral arterioles

This study examined effects of local reductions in mean and pulse pressures on cerebral arterioles in normotensive Wistar-Kyoto rats (WKY) and stroke-prone spontaneously hypertensive rats (SHRSP). WKY and SHRSP underwent clipping of one carotid artery at 1 month of age. At 10-12 months of age, mechanics of pial arterioles were examined in vivo in anesthetized rats. Bilateral craniotomies were performed to expose pial arterioles in the sham and clipped cerebral hemispheres. Stress-strain relations were calculated from measurements of pial arteriolar pressure (servo null), diameter, and cross-sectional area of the arteriolar wall. Point counting stereology was used to quantitate individual components in the arteriolar wall. Before deactivation of smooth muscle with EDTA, mean (Pm) and pulse (Pp) pressures were significantly less (p less than 0.05) in clipped than in sham arterioles in WKY (Pm, 63 +/- 2 versus 73 +/- 2 mm Hg; Pp, 23 +/- 3 versus 30 +/- 3 mm Hg) and SHRSP (Pm, 94 +/- 4 versus 110 +/- 4 mm Hg; Pp, 27 +/- 2 versus 38 +/- 3 mm Hg). Cross-sectional area of the arteriolar wall was less (p less than 0.05) in clipped than in sham arterioles in both groups of rats (1,403 +/- 125 versus 1,683 +/- 125 microns2 in WKY; 1,436 +/- 72 versus 1,926 +/- 134 microns2 in SHRSP). There was a correlation between cross-sectional area of the vessel wall and pulse pressure (r2 = 0.66), but not mean pressure (r2 = 0.09). During maximal dilatation with EDTA, the stress-strain curve was shifted to the left in clipped arterioles of SHRSP, but not of WKY, which indicates that carotid clipping in SHRSP reduces passive distensibility of cerebral arterioles. The proportion of distensible components in the vessel wall (smooth muscle, elastin, and endothelium) was reduced in clipped arterioles in SHRSP, but not in WKY. These findings suggest that 1) vascular hypertrophy of cerebral arterioles is related more closely to pulse pressure than to mean pressure, and 2) reduction of pial arteriolar pressure completely prevents cerebral vascular hypertrophy and attenuates increases in passive distensibility of cerebral arterioles in SHRSP.     

Arteriolar occlusion causes independent cellular responses in endothelium and smooth muscle

OBJECTIVES: To test the hypothesis that arteriolar occlusion causes different cellular changes in endothelial and smooth muscle cells. METHODS: Cheek pouch arterioles (resting diameter 41 +/- 2 microm) of anesthetized hamsters were occluded briefly (<60 seconds) either upstream or downstream from an observation site. Changes in membrane potential and intracellular calcium concentration ([Ca(2+)](i)) of the endothelial or smooth muscle cells were determined by using fluorescence microscopy (ratiometric analysis). RESULTS: The pressure in the occluded segment decreased by 17.4 +/- 2.6 cm H(2)O during upstream occlusion and increased by 16.8 +/- 6 cm H(2)O during downstream occlusion (n = 5). Upstream occlusion caused vasoconstriction of the occluded segment by 2.4 +/- 0.4 microm, whereas downstream occlusion produced brief vasodilatation by 1.1 +/- 0.2 microm. The endothelial cells hyperpolarized during upstream or downstream occlusion (ratio change: 2.26 +/- 0.24% and 2.39 +/- 0.42%, respectively; p < 0.01, n = 5). There were no changes in endothelial [Ca(2+)](i). The smooth muscle cells depolarized (ratio change: -2.08 +/- 0.14%, n = 5) with an increase in [Ca(2+)](i) (ratio change: 2.92 +/- 0.16%, n = 6) during downstream occlusion. However, there was no detectable change in membrane potential or [Ca(2+)](i) of smooth muscle cells during upstream occlusion. All the changes rapidly recovered when occlusion was released. Responses of an in-situ isolated segment on a side branch revealed conducted dilatory signals caused by the occlusions. CONCLUSIONS: Our results show that the endothelial and smooth muscle cells respond independently to arteriolar occlusion. The endothelial and smooth muscle cells do not effectively communicate in [Ca(2+)](i) or membrane potential during acute arteriolar occlusion. Hyperpolarizing signals in endothelium cause conducted dilation.     

The roles of nitric oxide in dilating proximal and terminal arterioles of skeletal muscle during systemic hypoxia

Indirect evidence suggests that dilatation evoked by systemic hypoxia in proximal and terminal arterioles of skeletal muscle is mediated by adenosine acting on A(1) receptors, but that the dilatation of proximal arterioles requires the presence of nitric oxide (NO), whereas that of terminal arterioles is mediated by NO. In the present study, we showed that primary and terminal arterioles of spinotrapezius muscle (diameters: 45 +/- 4 and 9 +/- 1 microm, respectively) in anaesthetised rats dilated by 15 +/- 7 and 48 +/- 24%, respectively, during hypoxia (breathing 12% O(2)). Inhibition of NO synthesis with intravenous nitro-L-arginine methyl ester attenuated these responses (to -2 +/- 3 and -4 +/- 4%, respectively). However, when a tonic level of NO was subsequently restored by infusion of NO donor, hypoxia evoked dilatation of primary arterioles (+24 +/- 8%) but not terminal arterioles (0 +/- 4%). The adenosine A(1) receptor antagonist DPCPX (8-cyclopentyl-1,3-dipropylxanthine) (intravenous) attenuated this 'restored' primary arteriolar vasodilatation (to +6 +/- 3%). Similar results were obtained with 8% O(2). We propose that (1) proximal arteriolar dilatation evoked by systemic hypoxia depends on a background level of NO, which facilitates the action of adenosine on A(1) receptors, and (2) hypoxia-evoked dilatation of terminal arterioles is mediated by NO synthesised via A(1) receptor stimulation.     

Effect of T-type selective calcium antagonist on renal microcirculation: studies in the isolated perfused hydronephrotic kidney

Although calcium antagonists exert preferential vasodilation of renal afferent arterioles, we have recently demonstrated that nilvadipine and efonidipine, possessing both L-type and T-type calcium channel blocking action, reverse the angiotensin (Ang) II-induced afferent and efferent arteriolar constriction. In the present study, we investigated the role of T-type calcium channels in mediating the Ang II-induced efferent arteriolar tone using the selective T-type calcium channel blocker mibefradil. Isolated perfused hydronephrotic rat kidneys were used for direct visualization of renal microcirculation. Administration of Ang II (0.3 nmol/L) caused marked constriction of afferent (from 13.5+/-0.6 to 9.2+/-0.6 microm, P<0.01, n=6) and efferent (from 11.5+/-1.0 to 7.4+/-0.7 microm, P<0.01, n=5) arterioles. Mibefradil (1 micromol/L) dilated both vessels, with 82+/-11% and 72+/-7% reversal of afferent and efferent arterioles, respectively. Similarly, nickel chloride (100 micromol/L) caused dilation of both arterioles, similar in magnitude in afferent (68+/-10%, n=7) and efferent (80+/-7%, n=7) arterioles. To eliminate the possibility that the mibefradil-induced dilation was mediated by L-type channel blockade, mibefradil was administered in the presence of nifedipine (1 micromol/L). Thus, nifedipine caused modest efferent arteriolar dilation (30+/-6% reversal, n=9), and subsequent addition of mibefradil elicited further dilation of this vessel (80+/-4%, P<0.01 versus nifedipine). Furthermore, mibefradil reversed the Ang II-induced efferent arteriolar constriction even in the presence of nifedipine and phentolamine. These findings demonstrate that T-type calcium antagonists markedly dilate the Ang II-induced efferent arteriolar constriction, but the action is not mediated by inhibition of catecholamine release. This potent activity would contribute to the efferent arteriolar response to nilvadipine and efonidipine and may offer benefit in light of glomerular hemodynamics.     

Dysfunction of nitric oxide mediation in isolated rat arterioles with methionine diet-induced hyperhomocysteinemia.

In humans, increased plasma homocysteine (Hcy) has been shown to be correlated with occlusive arterial diseases and atherosclerosis. Studies of isolated conductance vessels of experimental animals suggest that Hcy may interfere with local vasoregulatory mechanisms, yet the effect of hyperhomocysteinemia (HHcy) on the function of microvessels, such as skeletal muscle arterioles, has not been investigated. Male Wistar rats were divided into 2 groups: control rats (C; plasma Hcy, 7.1+/-0.3 micromol/L; n=25), and rats made HHcy by 1 g/kg body weight daily intake of methionine in the drinking water for 4 weeks (plasma Hcy, 23.6+/-2.9 micromol/L; P<0.01 versus C; n=25). First-order arterioles ( approximately 130 micrometer in diameter) were isolated from gracilis muscle, cannulated, and pressurized (80 mm Hg, no-flow conditions). Changes in diameter were observed by videomicroscopy. Arteriolar constrictions to norepinephrine (NE; 3x10(-7) mol/L) were significantly (P<0.01) greater in HHcy compared with C rats (C, 37.7+/-4.9%; HHcy, 59.5+/-5. 2%). Removal of the endothelium (-E) augmented NE-induced constrictions only in arterioles from C rats, whereas it had no effect on responses of arterioles from HHcy rats (C-E, 55.9+/-6.9%; HHcy-E, 56.5+/-7.0%). Dilations to cumulative doses of acetylcholine (ACh; 10(-8) mol/L) were significantly reduced in arterioles from HHcy rats (C, 64.0+/-5.2%; HHcy, 24.1+/-6.8%). Inhibition of nitric oxide (NO) synthesis with N(omega)-nitro-L-arginine (L-NNA; 10(-4) mol/L) significantly decreased ACh-induced dilations of C arterioles, whereas it did not affect HHcy arterioles. Similar alterations were found in arteriolar dilations to histamine, another known NO-dependent agonist. Endothelium-independent dilations to the NO donor sodium nitroprusside were not different in arterioles from C and HHcy rats, either in the presence or absence of L-NNA. Presence of superoxide dismutase and catalase (scavenger of reactive oxygen metabolites) did not affect HHcy-induced alterations in the ACh response. We conclude that hyperhomocysteinemia reduces rat skeletal muscle arteriolar dilations in response to ACh and histamine, and enhances constrictions to NE, alterations that are likely to be caused by the reduced mediation of these responses by NO. The reduced activity of NO in arterioles may contribute to the microvascular impairment described in HHcy.     

Calcium-independent release of endothelial nitric oxide in the arteriolar network: onset during rapid juvenile growth

OBJECTIVE: In young rats, skeletal muscle arterioles respond to acetylcholine, which elicits Ca2+-dependent endothelial nitric oxide (NO) release, but not to shear stress, which does not require increased intracellular Ca2+ for endothelial NO release. The aim of this study was to determine if, in general, signaling pathways for endothelial NO release that differ in their reliance on Ca2+ may be developing at different times during normal arteriolar network growth in skeletal muscle. METHODS: Arteriolar responses to intraluminal infusion of the Ca2+ ionophore A23187, and the Ca2+-independent agonists vascular endothelial growth factor (VEGF) and simvastatin, were studied before and during NO synthase (NOS) inhibition with NG-monomethyl-L-arginine (L-NMMA) in the exteriorized spinotrapezius muscle of weanling (age 4-5 wks) and juvenile (7-8 wks) rats. RESULTS: There were no age-dependent differences in arteriolar responses to A23187 applied over a concentration range that dilated arterioles from 9 +/- 2 to 74 +/- 8% of maximum, and L-NMMA attenuated these responses by the same amount in both age groups. In juveniles, arterioles dilated up to 39+/-5% of maximum in response to VEGF, and up to 83 +/- 6% of maximum in response to simvastatin, with L-NMMA greatly reducing the responses to both agonists. In contrast, arterioles in weanlings did not dilate in response to either agonist. CONCLUSIONS: These findings suggest that some Ca2+-independent signaling pathways for endothelial NO release may not initially be operational in the arteriolar network, but quickly become established during juvenile growth. This is consistent with the idea that microvascular control mechanisms are not fixed at birth, but rather undergo progressive changes in concert with microvascular network growth and changes in tissue metabolic requirements.     

Effects of aging on mechanics and composition of cerebral arterioles in rats

The purpose of this study was to examine effects of aging on the mechanics and composition of cerebral arterioles. We measured pressure (servo-null) and diameter in pial arterioles in anesthetized adult (9-12 months old) and aged (24-27 months old) Fischer 344 rats. After deactivation of smooth muscle with EDTA, diameter of pial arterioles at 70 mm Hg pial arteriolar pressure was less in aged than in adult rats (67 +/- 4 vs. 81 +/- 4 microns [mean +/- SEM], p less than 0.05). The stress-strain relation and the slope of tangential elastic modulus versus stress (6.8 +/- 0.6 vs. 5.3 +/- 0.3, p less than 0.05) indicated that distensibility of pial arterioles was reduced in aged rats. Cross-sectional area of the vessel wall, measured histologically, was less in aged than adult rats (1,239 +/- 91 vs. 1,832 +/- 180 microns2, p less than 0.05). Point counting stereology was used to quantitate smooth muscle, elastin, collagen, and basement membrane in the arteriolar wall. Cross-sectional areas of smooth muscle and elastin were significantly less in aged than adult rats (744 +/- 57 vs. 1,291 +/- 119 microns2 for smooth muscle, 52 +/- 6 vs. 113 +/- 15 microns2 for elastin; p less than 0.05), whereas cross-sectional areas of collagen and basement membrane were not significantly different in aged and adult rats (4 +/- 1 vs. 3 +/- 1 microns2 for collagen, 236 +/- 17 vs. 258 +/- 31 microns2 for basement membrane). The ratio of nondistensible (collagen and basement membrane) to distensible (smooth muscle and elastin) components was greater in aged than adult rats (0.30 +/- 0.01 vs. 0.18 +/- 0.01, p less than 0.05). Thus, we conclude that, during aging, cerebral arterioles undergo atrophy, distensibility of cerebral arterioles is reduced, and the relative proportion of distensible elements, elastin and smooth muscle, is reduced in the arteriolar wall.     

Asymmetrical dimethylarginine inhibits shear stress-induced nitric oxide release and dilation and elicits superoxide-mediated increase in arteriolar tone

l-arginine is the substrate used by NO synthase to produce the vasodilator NO. However, in several human diseases, such as hyperhomocysteinemia, diabetes mellitus, and hypertension, there is an increase in serum levels of methylated l-arginines, such as asymmetrical dimethylarginine (ADMA), which cannot be used by NO synthase to produce NO. Yet, the functional consequence of increased levels of ADMA on the vasomotor function of resistance vessels has not been delineated. We hypothesized that elevated levels of exogenous ADMA inhibit NO mediation of flow/shear stress-dependent dilation of isolated arterioles. In the presence of indomethacin, isolated arterioles from rat gracilis muscle (approximately 165 microm at 80 mm Hg) were incubated with ADMA (10(-4) mol/L), which eliminated the dilations to increases in intraluminal flow (control: from 164+/-5.4 to 188+/-3.8 microm versus ADMA: from 171+/-6.1 to 173+/-6.3 microm at 20 microL/min). ADMA did not affect dilations to nifedipine (10(-6) mol/L; control: 63.4+/-2%, ADMA: 65.8+/-3%) or 8-bromo cGMP (10(-4) mol/L; control: 51.2+/-2.1%, ADMA: 49.3+/-3.4%). In addition, ADMA elicited significant constriction of arterioles (from 173+/-17 microm to 138+/-16 microm at 80 mm Hg), which was prevented by previous incubation of arterioles with polyethylene-glycol (PEG) superoxide dismutase (SOD; 120 U/mL, control: 155+/-11 microm versus ADMA: 150+/-14 microm). Correspondingly, ADMA increased PEG-SOD reversible manner the production of vascular superoxide assessed by lucigenin-enhanced chemiluminescence and ethidium bromide fluorescence. Thus, increased levels of ADMA in various diseases could inhibit the regulation of arteriolar resistance by shear stress-induced release of NO and elicit superoxide-mediated increase in basal tone, both of which favor the development of hypertension.     

Shear stress-induced release of prostaglandin H(2) in arterioles of hypertensive rats

The nitric oxide-mediated portion of shear stress-induced dilation of rat gracilis muscle arterioles was shown to be impaired in spontaneously hypertensive rats (SHR). Because shear stress-induced dilation is primarily mediated by endothelium-derived prostaglandins in rat cremasteric arterioles, we hypothesized that in the cremasteric vascular bed the mediation of shear stress-induced dilation by prostaglandins is altered in hypertension. At a constant intraluminal pressure of 80 mm Hg, the active diameters of isolated rat cremasteric arterioles of normotensive 30-week-old Wistar-Kyoto rats (WKY) and SHR were 58.0+/-3.1 and 51.7+/-3.6 microm, respectively, whereas their passive diameters were 109.4+/-4.4 and 101.9+/-6.7 microm, respectively. Dilations to increases in shear stress elicited by increases in intraluminal flow (from 0 to 25 microL/min) were significantly less (P<0.05) in cremasteric arterioles isolated from SHR than from WKY. Arachidonic acid (10(-5) mol/L) elicited constrictions in SHR arterioles but dilations in WKY arterioles. The prostaglandin H(2)/thromboxane A(2) (PGH(2)/TxA(2)) receptor antagonist SQ 29,548 (10(-6) mol/L) significantly increased basal diameter by 11% and normalized the attenuated shear stress-induced dilation in SHR, whereas it did not affect basal diameter and arteriolar responses of WKY. Furegrelate, a specific inhibitor of TxA(2) synthase, did not affect the response in SHR. Also, SQ 29,548 reversed the arachidonic acid-induced constriction to dilation in SHR arterioles, whereas it did not affect the dilator response in WKY arterioles. Constrictions of arterioles of WKY and SHR to U46,619 (a PGH(2)/TxA(2) receptor agonist) were not different. These results demonstrate that in cremasteric arterioles of hypertensive rats, shear stress elicits an enhanced release of PGH(2), resulting in a reduced shear stress-dependent dilation. Thus, augmented hemodynamic forces can alter the shear stress-induced synthesis of prostaglandins, which may contribute to the elevated vascular resistance in hypertension.     

Mechanics of cerebral arterioles in hypertensive rats

Chronic hypertension is associated with hypertrophy of cerebral blood vessels. Previous studies of the mechanical properties of cerebral vessels in chronic hypertension have examined large cerebral arteries. The goals of this study were first to develop a method to examine vascular mechanics of cerebral arterioles in vivo and second to determine whether the stiffness of cerebral arterioles is altered in the presence of chronic hypertension. We calculated circumferential stress and strain of pial arterioles in age-matched, anesthetized stroke-prone spontaneously hypertensive rats (SHRSP) and in Wistar Kyoto rats (WKY) from measurements of pial arteriolar pressure, inner diameter, and wall thickness. Pial arteriolar pressure was measured with a servonull system. Smooth muscle of pial arterioles was deactivated with ethylenediaminetetraacetic acid (EDTA), and pressure-diameter relations were examined during step-wise reductions in pressure. Prior to deactivation of smooth muscle in 3-4-month-old rats, pial arteriolar pressure was greater in SHRSP than in WKY (110 +/- 4 versus 75 +/- 2 mm Hg [mean +/- SE]; p less than 0.05). Pial arteriolar diameter, which was measured at prevailing levels of pial arteriolar pressure, was less in SHRSP than in WKY (52 +/- 5 versus 63 +/- 3 microns; p less than 0.05). Following deactivation of smooth muscle, diameter of pial arterioles at 70 mm Hg of pial arteriolar pressure was similar in the two groups: 104 +/- 6 microns in SHRSP and 109 +/- 3 microns in WKY (p greater than 0.05). Wall thickness was 4.5 +/- 0.2 microns in SHRSP and 4.1 +/- 0.1 microns in WKY (p greater than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)