Sympathetic alpha-adrenergic control of large-bore arterial vessels, arterioles and veins, and of capillary pressure and fluid exchange in whole-organ cat skeletal muscle

The sympathetic nervous control of the vascular bed of cat gastrocnemius muscle was studied with a new whole-organ technique which permits simultaneous, continuous and quantitative measurements of capillary pressure (Pc), capillary fluid exchange and resistance reactions in the whole vascular bed and in its three consecutive sections: large-bore arterial vessels (greater than 25 microns), arterioles (less than 25 microns) and veins. The results demonstrated a distinct neural control of all three consecutive vascular sections, graded in relation to the rate of nerve excitation up to maximum at 16 Hz. Stimulation at high rates, which in the steady state caused an average rise of overall regional resistance from 15.3 to 120 PRU (7.8-fold increase), thus raised large-bore arterial vessel resistance from 8.8 to 64 PRU (7.3-fold increase), arteriolar resistance from 4.5 to 49 PRU (10.9-fold increase) and venous resistance from 2.0 to 7 PRU (3.5-fold increase). The rate of resistance development (PRUs-1) of the sympathetic constrictor response was much higher in the arteriolar than in the other sections, which indicates that the neural control is especially prompt and efficient in the arterioles. A passive component was shown to contribute to the described responses only on the venous side, but in no case by more than 10% of the total sympathetic venous resistance response, which thus is mainly active. Of special functional importance was that the new technique provided information about the adrenergic control of Pc in absolute figures. From the control value of 19 mmHg, graded sympathetic stimulation caused a graded decline in Pc, at maximum constriction by about 7 mmHg. This resulted in marked net transcapillary fluid absorption, in turn increasing plasma volume.     

Sympathetic a-adrenergic control of large-bore arterial vessels,arterioles and veins,and of capillary pressure and fluid exchange in whole-organ cat skeletal muscle

The sympathetic nervous control of the vascular bed of cat gastrocnemius muscle was studied with a new whole-organ technique which permits simultaneous, continuous and quantitative measurements of capillary pressure (P_c), capillary fluid exchange and resistance reactions in the whole vascular bed and in its three consecutive sections: large-bore arterial vessels (> 25 μm), arterioles (< 25 μm) and veins. The results demonstrated a distinct neural control of all three consecutive vascular sections, graded in relation to the rate of nerve excitation up to maximum at 16 Hz. Stimulation at high rates, which in the steady state caused an average rise of overall regional resistance from 15.3 to 120 PRU (7.8-fold increase), thus raised large-bore arterial vessel resistance from 8.8 to 64 PRU (7.3-fold increase), arteriolar resistance from 4.5 to 49 PRU (10.9-fold increase) and venous resistance from 2.0 to 7 PRU (3.5-fold increase). The rate of resistance development (PRU s^-1) of the sympathetic constrictor response was much higher in the arteriolar than in the other sections, which indicates that the neural control is especially prompt and efficient in the arterioles. A passive component was shown to contribute to the described responses only on the venous side, but in no case by more than 10% of the total sympathetic venous resistance response, which thus is mainly active. Of special functional importance was that the new technique provided information about the adrenergic control of P_c, in absolute figures. From the control value of 19 mmHg, graded sympathetic stimulation caused a graded decline in P_c, at maximum constriction by about 7 mmHg. This resulted in marked net transcapillary fluid absorption, in turn increasing plasma volume.     

Effects of venous pressure elevation on myogenic vasoconstrictive responses to static and dynamic arterial pressures

In order to establish the nature of the stretch-evoked dynamic properties of vascular smooth muscle in arterioles, we have examined the static and dynamic effects of both arterial pulse pressure and elevated venous pressure on the resistance vessels (arteries and arterioles) in an intestinal mesenteric preparation derived from dogs. The dynamic myogenic response to stretch stimuli was directly related to both the frequency of arterial pulse pressure (1-20 c/min) and the level of venous pressure (0-45 mmHg). Under elevated venous pressure (20 mmHg), the mean arterial flow decreased with an increase in the frequency of arterial pulse pressure. The arteriolar vascular tone (namely, vascular resistance) was seen to be enhanced. We found that elevated venous pressure promotes active constriction (9-53%) of arteriolar smooth muscle (myogenic mechanism). The elevation of venous pressure also caused a rhythmic constriction (vasomotion) in the site of both vein and artery, which was completely abolished by an alpha-blocker (phentolamine). The results suggest that during venous pressure elevation a very pronounced myogenic constriction in terminal arterioles is caused by either a local neural reflex or a propagated myogenic response in the arteriolar network.     

On the nature of basal vascular tone in cat skeletal muscle and its dependence on transmural pressure stimuli

The aim of the present study was to elucidate in some detail the characteristics of the intrinsic basal vascular tone in the adrenergically blocked skeletal muscle with regard to its extent and site along the vascular bed, its dependence on arterial pressure via static and dynamic transmural pressure stimuli, and its sensitivity to local metabolic influence. Basal tone, which apparently is of myogenic nature, was pronounced in ‘proximal arterial vessels’ (>25 μm i.d.) and in the ‘microvessels’ (<25 μm), but low in ‘large veins’. Its functional characteristics, however, were different in the ‘proximal arterial vessels’ and the ‘microvessels’. Normal basal tone in the ‘microvessels’ thus seemed to be intimately dependent on the arterial blood pressure level and, at least partly, initiated by its static mean pressure distension effect as well as by its dynamic pulse pressure oscillations. It could be virtually abolished by a transmural pressure decrease applied at fast rate (‘strong inhibitory dynamic transmural pressure stimulus’). Basal tone in the ‘proximal arterial vessels’, on the other hand, was little affected by arterial pressure and almost irresponsive to transmural pressure stimuli. Basal tone in the ‘microvessels’ was much more sensitive to metabolic stimuli than that in the ‘proximal arterial vessels’. The present results, viewed in the light of some recent electrophysiological studies on vascular smooth muscle, suggest that smooth muscle in the ‘microvessels’ is mainly of the spike-generating type, whereas that in the ‘proximal arterial vessels’ seems to be of different nature, possibly of the non-spike-generating type.     

Blood pressure regulation V: in vivo mechanical properties of precapillary vessels as affected by long-term pressure loading and unloading

Recent studies are reviewed, concerning the in vivo wall stiffness of arteries and arterioles in healthy humans, and how these properties adapt to iterative increments or sustained reductions in local intravascular pressure. A novel technique was used, by which arterial and arteriolar stiffness was determined as changes in arterial diameter and flow, respectively, during graded increments in distending pressure in the blood vessels of an arm or a leg. Pressure-induced increases in diameter and flow were smaller in the lower leg than in the arm, indicating greater stiffness in the arteries/arterioles of the leg. A 5-week period of intermittent intravascular pressure elevations in one arm reduced pressure distension and pressure-induced flow in the brachial artery by about 50 %. Conversely, prolonged reduction of arterial/arteriolar pressure in the lower body by 5 weeks of sustained horizontal bedrest, induced threefold increases of the pressure-distension and pressure-flow responses in a tibial artery. Thus, the wall stiffness of arteries and arterioles are plastic properties that readily adapt to changes in the prevailing local intravascular pressure. The discussion concerns mechanisms underlying changes in local arterial/arteriolar stiffness as well as whether stiffness is altered by changes in myogenic tone and/or wall structure. As regards implications, regulation of local arterial/arteriolar stiffness may facilitate control of arterial pressure in erect posture and conditions of exaggerated intravascular pressure gradients. That increased intravascular pressure leads to increased arteriolar wall stiffness also supports the notion that local pressure loading may constitute a prime mover in the development of vascular changes in hypertension.     

Augmented vasoconstrictor response to changes in vascular transmural pressure in patients with essential arterial hypertension

The vasoconstrictor response to increase in venous transmural pressure in subcutaneous tissue was studied in 9 patients with essential arterial hypertension. Subcutaneous blood flow was measured on the distal part of the forearm and at the lateral malleolus by the local ¹³³Xe washout technique. Increase in venous transmural pressure was obtained by lowering the area under study 40cm below midaxillary line in the recumbent subject. Average mean arterial pressure ± 1 S.E. was 133 ± 6 mmHg. The fractional increase in vascular resistance induced by arteriolar constriction was more pronounced in the hypertensive patients than in a normotensive control group. “Minimal vascular resistance” in the papaverine relaxed vascular bed was higher in the hypertensive patients than in the controls. Distensibility of the papaverine relaxed resistance vessels was diminished in the patients. Follow-up studies after 6–18 months of anti-hypertensive treatment indicate that the vasoconstrictor response as well as “minimal vascular resistance” are normalized, whereas the distensibility of the papaverine relaxed arterioles remained unaltered in the hypertensive patients. The results indicate that the arteriolar smooth muscle cells of hypertensive patients are subjected to reversible hypertrophy whereas the reduced distensibility of the resistance vessels is due to irreversible structural changes.     

Resistance responses in proximal arterial vessels, arterioles and veins during reactive hyperaemia in skeletal muscle and their underlying regulatory mechanisms

The reactive hyperaemia response cat skeletal muscle to 2-120 s arterial occlusions was analysed with regard to amplitude, duration, 'excess blood flow' and site of dilator action along the vascular bed. The last-mentioned was assessed with a new whole-organ technique permitting continuous segmental resistance recordings in arterial vessels greater than 25 microns, arterioles less than 25 microns and veins. Peak amplitude, duration and excess flow all increased with increasing occlusion length, of which excess flow was linearly related to occlusion length. The site of active dilatation was preferentially confined to arterioles less than 25 microns in which complete relaxation was observed after only 20 s occlusion, although the duration of the response continued to increase with more prolonged occlusions. A graded, but less pronounced, dilatation occurred in the arterial vessels greater than 25 microns and in the veins, the former exhibiting a 63% inhibition of tone as a maximum response at 120 s occlusion. The recovery phase was characterized by a vivid active constrictor component apparently protecting the capillaries from excessive pressure load upon arterial occlusion release, but this constriction became attenuated at long occlusions, thereby prolonging the hyperaemia response. The role of myogenic regulatory mechanisms in the responses was assessed from observed segmental resistance reactions to selectively applied transmural pressure stimuli similar to those elicited by arterial occlusion/release. It was concluded that myogenic mechanisms alone could explain the amplitude of the reactive hyperaemia response at short (up to 30 s) occlusions. Metabolic mechanisms seemed to be responsible for further relaxation of the proximal arterial vessels at longer occlusions, and also for the increased duration of the hyperaemia response at occlusions exceeding 10 s. Blockade of nitric oxide formation (endothelium-derived relaxing factor) did not seem to affect the reactive hyperaemia response.     

Protective role of sympathetic nerve activity to exercising skeletal muscle in the regulation of capillary pressure and fluid filtration

This study describes the integrated sympathetic/metabolic control of capillary pressure (Pc) and filtration in cat skeletal muscle as studied during graded exercise and superimposed graded (2, 6 and 16 Hz) vasoconstrictor nerve excitation. The applied technique permitted simultaneous analysis of the underlying changes of resistance in the whole vascular bed (RT) and in its large-bore arterial resistance vessels (greater than 25 microns), small arterioles (less than 25 microns) and veins. Graded exercise per se caused graded increases in capillary pressure, which at heavy work exceeded the resting control value by 12.2 mmHg, in turn leading to marked loss of plasma fluid by filtration. Sympathetic nerve stimulation was much more efficient in lowering capillary pressure during exercise than at rest, in spite of an exercise-induced marked attenuation of the vasoconstrictor response (RT). The sympathetically evoked capillary pressure fall per unit resistance increase was larger the greater the degree of exercise vasodilation, implying a highly nonlinear relation between capillary pressure and RT and also between the more direct determinant of capillary pressure the post- to precapillary resistance ratio, and RT. Strenuous exercise in vivo is known to be associated with a markedly increased reflex sympathetic discharge to exercising muscle which has been a puzzling feature in view of its untoward restriction of the exercise hyperaemia response. To the extent the present results are representative for this in vivo situation, they suggest that sympathetic discharge to exercising muscle, in spite of some flow restricting effect, might serve a highly beneficial function, causing effective protection against excessive work-induced rise of capillary pressure and harmful plasma fluid loss into the extravascular space of working muscle.     

In-vivo effects of endothelin-1 and ETa receptor blockade on arterial,venous and capillary functions in skeletal muscle

Results from in vitro studies have indicated that endothelin-1 is a main candidate for endothelium-derived contracting factors. The aim of this in vivo study was to describe in quantitative terms the effects of endothelin-1 (ET-1), and of ET_a receptor blockade, on vascular tone (resistance) in large-bore arterial resistance vessels (> 25 μm), small arterioles (< 25 μm) and the veins, as well as on capillary pressure and fluid exchange in cat gastrocnemius muscle. Endothelin-1 (100–1600 ng kg-1 min-1, i.a.) elicited, after an initial transient dilation, a strong dose-dependent constrictor response in all three consecutive vascular sections, yet with a preferential action on the small arterioles and the veins. The vasoconstriction developed very slowly over about 1 h and was also long-lasting after cessation of the infusion. Our main quantitative analysis refers to effects elicited by 20 min long i.a. infusions of ET-1 at a dose of 400 ng kg-1 min-1. At the end of this period, the peptide caused, on average, a three-fold increase in total regional vascular resistance, in turn explained by a 70% increase in large-bore arterial resistance, a 280% increase in arteriolar resistance and a 220% increase in venous resistance. The latter effect was also manifested as a pronounced capacitance response, and as a decrease in the pre- to post-capillary resistance ratio leading regularly to a rise in capillary pressure, net transcapillary fluid filtration and oedema formation which is unusual for a vasoconstrictor. The new specific competitive ET_A receptor antagonist FR 139317 was found to be fully effective in vivo, insofar as it abolished the constrictor response to endothelin-1. ET_A receptor blockade, or administration of phosphoramidon, an inhibitor of ET-1 production, did not influence the level of basal vascular tone, indicating no significant endogenous release of ET-1 under resting conditions. This contrasts to the established pronounced endogenous release of endothelium-derived nitric oxide. Finally, vascular myogenic regulation was found not to be mediated by ET-1. The results, taken together, suggest a possible role of ET-1 in long-term, rather than short-term, regulation of vascular tone in vivo, perhaps especially during pathophysiological conditions.     

Effect of Carotid Sinus Stimulation on Cardiac Output and Peripheral Vascular Resistance during Changes in Blood Volume Distribution in Man

In ten healthy subjects (mean age 29.6 years) the hemodynamic response to carotid sinus stimulation (neck suction - 40 mmHg) was studied under control conditions and during peripheral pooling of blood (lower body negative pressure). Heart rate, arterial and central venous pressure, cardiac output and forearm blood flow were measured. The time sequence of the heart rate response was studied separately in six healthy subjects. During control conditions, carotid sinus stimulation induced a significant decrease in arterial pressure and heart rate. The blood pressure decrease mainly reflected a reduction in cardiac output, total peripheral vascular resistance being essentially unchanged. However, in the skeletal muscle, represented by a forearm segment, vascular resistance decreased significantly. During lower body negative pressure (LBNP) the same stimulation of the carotid sinus induced a significantly greater fall in mean arterial pressure even though the reduction in cardiac output was slightly smaller on the average than in the control condition. The heart rate increased, probably secondary to a time dependent increase in heart rate elicited by the continuous LBNP stimulus. Total peripheral vascular resistance decreased significantly during LBNP, the reaction likewise differing significantly from that in the control condition. Thus the augmented blood pressure response was due to a more pronounced vasodilatation when the carotid sinus was stimulated during lower body negative pressure. The results indicate that the hemodynamic changes elicited by carotid sinus stimulation are modified by changes in the distribution of blood volume and in the tone of resistance vessels.     

Relation between capillary pressure and vascular tone over the range from maximum dilatation to maximum constriction in cat skeletal muscle

An attempt was made to assess, from a large sample (n = 567), the normal level of hydrostatic capillary pressure (Pc) in resting skeletal muscle and the extent of Pc regulation as effected by strictly graded activation of metabolic and adrenergic control mechanisms over the entire physiological range of vascular tone. With the use of a new whole-organ technique, Pc towards the venous end of the capillary was continuously recorded at constant arterial pressure (100 mmHg) and under simultaneous observations of total regional vascular resistance (RT), precapillary resistance (Ra) and post-capillary resistance (RV). In the control state with a Starling fluid equilibrium, a venous pressure of 7 mmHg and normal vascular tone (RT = 19.1 +/- 0.3 PRU), Pc averaged 16.7 +/- 0.3 mmHg. Graded metabolic dilatation (muscle exercise), decreasing RT to a minimum value of 1.7 PRU, caused progressive increase in Pc up to 32 mmHg and consequent fluid filtration. Conversely, graded adrenergic constriction, increasing RT to a maximum of 100 PRU, caused a progressive decrease in Pc down to 10 mmHg and consequent fluid absorption. The relation between Pc and RT was highly non-linear, Pc increasing more steeply the more RT approached low values, and was described by the power function: Pc = 36.43 x RT-0.27 (r = -0.79, P less than 0.001). The resistance ratio, Rv/Ra (the main determinant of Pc), and vascular tone (RT) showed a similar non-linear relation. Regulatory change of Rv/Ra was mainly accomplished by active change of Ra, but a pronounced Rv decrease (venodilatation) occurred in the lowest RT range, exerting a protective function against excessive increase in Pc and detrimental plasma fluid loss.     

Regulation of skeletal muscle perfusion during exercise

For exercise to be sustained, it is essential that adequate blood flow be provided to skeletal muscle. The local vascular control mechanisms involved in regulating muscle perfusion during exercise include metabolic control, endothelium-mediated control, propagated responses, myogenic control, and the muscle pump. The primary determinant of muscle perfusion during sustained exercise is the metabolic rate of the muscle. Metabolites from contracting muscle diffuse to resistance arterioles and act directly to induce vasodilation, or indirectly to inhibit noradrenaline release from sympathetic nerve endings and oppose α-adrenoreceptor-mediated vasoconstriction. The vascular endothelium also releases vasodilator substances (e.g., prostacyclin and nitric oxide) that are prominent in establishing basal vascular tone, but these substances do not appear to contribute to the exercise hyperemia in muscle. Endothelial and smooth muscle cells may also be involved in propagating vasodilator signals along arterioles to parent and daughter vessels. Myogenic autoregulation does not appear to be involved in the exercise hyperemia in muscle, but the rhythmic propulsion of blood from skeletal muscle veins facilitates venous return to the heart and muscle perfusion. It appears that the primary determinants of sustained exercise hyperemia in skeletal muscle are metabolic vasodilation and increased vascular conductance via the muscle pump. Additionally, sympathetic neural control is important in regulating muscle blood flow during exercise.     

Endogenous nitric oxide as a physiological regulator of vascular tone in cat skeletal muscle during haemorrhage

The problem whether endogenous nitric oxide (NO) may serve as a true physiological regulator of vascular tone in vivo was approached by testing its role during graded acute haemorrhage with the aid of the nitric oxide synthase (NOS) inhibitor l -NAME. The study was performed on the vascular bed of cat skeletal muscle with a technique permitting quantitative recordings of vascular resistance in the whole vascular bed (R_T) and in its consecutive sections, the proximal arterial resistance (‘feeder’) vessels (>25 μm; R_a,prox), the small arterioles (<25 μm) and the veins. NO blockade by close-arterial l -NAME infusion in the control situation increased R_T from 16.3 to 33.0 PRU (+102%), because of a selective increase in R_a,prox by 16.7 PRU. A 35% blood loss per se raised R_T from 13.6 to 21.7 PRU. Superimposed NO blockade in this state caused a much stronger vasoconstriction than in the control situation, increasing R_T to 60.9 PRU (+181%) and R_a,prox by 40.5 PRU, which indicated an ～2.4-fold increase (P< 0.001) in the NO dilator influence in the R_a,prox section above control. The effect was independent of autonomic nerves. The increased NO dilator influence during haemorrhage most likely was caused by an increased production of endothelium-derived nitric oxide (EDNO). The constrictor response to l -NAME was graded in relation to the blood loss (17.5 vs. 35%). The results indicate that EDNO functions as a physiological regulator of vascular tone in the arterial ‘feeder’ vessels during haemorrhage, serving to counterbalance to a significant extent the concomitant adrenergic constriction, and thereby preventing critical reduction of blood flow and untoward heterogeneous flow distribution within the tissue.     

Loci of Neurogenic and Metabolic Effects on Precapillary Vessels of Skeletal Muscle

Folkow , B., R. R. Sonnenschein , and D. L. Wright , Loci of neurogenic and metabolic effects on precapillary vessels of skeletal muscle. Acta physiol. scand. 1971. 81. 459–471. By cannulation of a branch of the proximally clamped sural artery of the anesthetized cat, distal arterial pressure (DAP) in the gastrocnemius muscle was recorded. Measurement of blood flow, femoral arterial pressure and DAP allowed calculation of total resistance (R_t) and its partition into a distal component (R_d) which included precapillary sphincters and the smaller arterioles, and a proximal component (R_P) which included the larger arteries. With sympathetic vasoconstriction, the initial increase in R_t was accounted for mainly by constriction of the distal vessels which then tended to relax; progressive constriction of proximal vessels accounted for most of the elevated R_t during the steady state; subsequent reactive hyperemia mainly involved distal vessels. R_t was less affected by sympathetic stimulation during exercise than when the muscle was at rest; constriction of distal vessels was more markedly reduced than that of proximal vessels. Ascending dilatation was evident during exercise. Sympathetic cholinergic vasodilatation mainly involved vessels more proximal to those which were dilated early in exercise. The findings are compatible with the concept that capillary flow distribution, as a function of terminal arterioles and precapillary sphincters, is adjusted by local factors towards an optimum for the prevailing metabolic level of the tissue.     

Pulsatile pressure and flow in the mesenteric vascular bed of the cat

Summary The transmission of arterial pressure and flow pulse through the mesenteric vascular bed was studied in 18 experiments on cats. Pressures were measured in the superior mesenteric artery and in small mesenteric veins, red blood cell flow velocities in mesenteric microvessels smaller than 60 diameter. Venous pressures were found to show heart beat synchronous oscillatory components of 0.2–0.5mmHg amplitude. Venous pressure pulses were delayed in time in comparison to the arterial pressure pulses: mean transit times varied between 85 and 110 msec. Blood flow velocities in arterioles and venules were generally pulsatile, the amplitude of the arteriolar pulses averaging 52.5% of mean velocity, of the venular pulses 32.5%. The velocity pulses were found to be similar in shape as flow pulses in larger arteries. Infusion of vasoactive drugs showed transmission of arterial pulses to be inversely dependent upon vascular resistance. It is concluded that the concept of complete damping of the arterial pulse during the passage of blood through the intestinal vascular bed cannot be maintained. Two different mechanisms of pulse transmission are discussed: direct hydraulic transmission through the capillary network and transmission across the vascular wall from the arteriole to the venule.Supported by USPHS Grant HE-08977.     

Beta2-adrenergic attenuation of capillary pressure autoregulation during hemorrhagic hypo tension,a mechanism promoting transcapillary fluid absorption in skeletal muscle

The aim of this study was to evaluate a possible humoral β₂-adrenergic effect on the capillary pressure autoregulation capacity in cat skeletal muscle during bleeding. For this purpose capillary pressure autoregulation in response to graded decrease in arterial pressure was studied in sympathectomized muscle in the control state, and during haemorrhagic hypovolaemia in the presence and absence of selective β₂-adrenoceptor blockade (ICI 118,551). The study was performed with a technique that permits continuous recordings of average capillary pressure in absolute terms and of the regional pre- and postcapillary vascular resistance, from which the pre- to post capillary resistance ratio could be determined. In the pre-haemorrhagic control state, an experimental decrease in arterial pressure from 100 to 50 mmHg caused a fall of capillary pressure from 17.6 by only 1.7 mmHg (ΔP_A/ΔP_c= 29), demonstrating an efficient capillary pressure autoregulation. This autoregulation was accomplished by a decrease in pre- to post capillary resistance ratio in turn being a result of active precapillary dilatation and a passive increase in post capillary vascular resistance. Haemorrhage per se, via a humoral α-adrenergic preferentially precapillary vaso-constriction, caused a decrease in capillary pressure to 16.8 mmHg at arterial pressure 100 mmHg. A superimposed decrease in arterial pressure to 50 mmHg resulted in a capillary pressure fall by 3.7 mmHg (ΔP_A/ΔP_e= 14), indicating impaired autoregulation capacity. This attenuation to a great extent could be ascribed to adrenaline-induced B₂-adrenoceptor stimulation, since β₂-blockade restored the Δ arterial pressure/capillary pressure ratio to 20. Low-dose isoprenaline infusion in the control state similarly caused marked impairment of capillary pressure autoregulation. The β₂-adrenergic attenuation of capillary pressure autoregulation appears to be a beneficial effect in haemorrhagic hypotension, since it lowers capillary pressure passively in relation to the arterial pressure fall, thereby reinforcing the a-adrenergic active capillary pressure decrease, leading to more effective transcapillary fluid absorption and, hence, improved replenishment of plasma volume.     

Renal autoregulation: evidence for the transmural pressure hypothesis.

Autoregulation of glomerular filtration rate (GFR) was examined during uteral orarterial constriction in anesthetized dogs after renal denervation. GFR was sustaineduntil ureteral pressure greater than 80 mmHg, provided renal arterial pressure exceeded 180 mmHg, but fell at ureteral pressure less than 54 mmHg when arterial pressure averaged 127 plus or minus 5 mmHg; renal blood rose as GFR declined. Ethacrynic acid, saline, or mannitol infusion increased tubular pressure without reducing GFR,but during subsequent ureteral constriction GFR fell at uteral pressure less than 40mmHg. During arterial constriction GFR was maintained at lower arterial pressures in hydropenic than in diuretic dogs. Because of thisdifference in the range of autoregulation, saline infusion increased GFR more in hydropenic than in diuretic dogs except at high arterial pressure. This response to reduced plasma oncotic pressure and the constancy of GFR over a wide range of proximal tubular and arterial pressure indicate constancy of thehydrostatic transmural pressure of glomerular capillaries. Afferent arteriolar resistance is, in addition to a regulation by transmural pressure, perhaps controlled by vascular stretch receptors in the glomeruli.     

Microvascular myogenic reaction in the wing of the intact unanesthetized bat.

Microvascular dimension and flow responses to stepwise changes in arterial and venous pressures, ranging from zero to +100 mmHg and zero to -75 mmHg have been recorded. Observations were made in arterioles, terminal arterioles, and precapillary sphincters in the wing web of intact, unanesthetized bats. The results show for all categories of vessels that with reduced transmural pressures there is a progressive increase in mean diameter and a decrease in rhythmic vasomotion rate. Flow changes are variable. For elevated transmural pressures there is a vasoconstriction with drastic flow reduction that is inconsistent with metabolic control. However, after prolonged elevation of pressure there is a progressive increase in flow, suggesting a "metabolic escape". Computed wall tension remains reasonably constant for a wide range of transmural pressures, suggesting that wall tension may be the controlled variable. These findings support the hypothesis of a myogenic reaction as a mechanism for maintenance of basal vascular tone in the intact unanesthetized bat.     

Effects of angiotensin-converting enzyme inhibition on arterial,venous and capillary functions in cat skeletal muscle in vivo

The aim of the present study was to analyse quantitatively, on a cat gastrocnemius muscle preparation in vivo, the effects of local angiotensin-converting enzyme (ACE) inhibition by enalaprilat on total regional vascular resistance (tone) and its distribution to the large-bore arterial resistance vessels (>25 μm), the small arterioles (<25 μm) and the veins. Associated effects on capillary pressure and fluid exchange were also studied. Close-arterial infusion of enalaprilat (0.05–0.20 mg kg muscle tissue min^-1) elicited a moderate dilator response in all three consecutive sections of the muscle vascular bed, an increase in capillary pressure and transcapillary fluid filtration. This dilation could be abolished by the selective bradykinin B₂-receptor antagonist Hoe 140 (2 mg kg^-1 min^-1, i.a.), indicating that the dilator mechanism of ACE inhibition was an increased local concentration of bradykinin, and hardly at all a decreased concentration of angiotensin (AT) II. The generalized dilator response to ACE inhibition along the vascular bed suggested a relatively uniform distribution of ACE from artery to vein and this was further supported by the finding that a close-arterial infusion of AT I (0.04–0.32 μg kg^-1 min^-1), which was vasoactive only after conversion to AT II by local ACE, elicited a generalized constrictor response in all three vascular sections. In contrast, infused AT II (0.01–0.16 μg kg^-1 min^-1) constricted almost selectively the large-bore arterial vessels. The specific angiotensin AT₁-receptor antagonist losartan (2 mg kg^-1 min^-1, i.a.) abolished the constrictor response to AT II but did not affect vascular tone under control conditions, indicating that AT II is not involved in the initiation of basal vascular tone in muscle. These results, taken together, indicate that under basal conditions vascular ACE contributes to the local control of vascular tone in skeletal muscle by degrading the endogenous dilator bradykinin, and not by converting AT I into vasoconstrictor AT II.