Importance of the renal medullary circulation in the control of sodium excretion and blood pressure

The control of renal medullary perfusion and the impact of alterations in medullary blood flow on renal function have been topics of research interest for almost four decades. Many studies have examined the vascular architecture of the renal medulla, the factors that regulate renal medullary blood flow, and the influence of medullary perfusion on sodium and water excretion and arterial pressure. Despite these studies, there are still a number of important unanswered questions in regard to the control of medullary perfusion and the influence of medullary blood flow on renal excretory function and blood pressure. This review will first address the vascular architecture of the renal medulla and the potential mechanisms whereby medullary perfusion may be regulated. The known extrarenal and local systems that influence the medullary vasculature will then be summarized. Finally, this review will present an overview of the evidence supporting the concept that selective changes in medullary perfusion can have a potent influence on sodium and water excretion with a long-term influence on arterial blood pressure regulation.     

Influence of l-arginine supplementation on reproductive blood flow and embryo recovery rates in mares

Supplementation with l-arginine can increase uterine arterial blood flow and vascular perfusion of the preovulatory follicle in mares. Increased vascular perfusion of the preovulatory follicle has been correlated with successful pregnancy in mares. The objective of this study was to determine if supplemental l-arginine would increase ovarian arterial blood flow, vascular perfusion of the preovulatory follicle, and embryo recovery rates in mares. Mares were blocked by age and breed and assigned at random within block to l-arginine supplementation or control groups. Mares were fed l-arginine beginning 17 days before and through the duration of the study. Transrectal Doppler ultrasonography was used to measure ovarian arterial blood flow and vascular perfusion of the preovulatory follicle daily when it reached 35 mm and subsequent CL on Days 2, 4, and 6. Mares, on achieving a follicle of 35 mm or more were bred via artificial insemination and an embryo collection was attempted 7 days after ovulation. Treatment did not affect interovulatory interval (arginine-treated, 18.1 ± 2.6 days; control, 20.7 ± 2.3 days) or embryo recovery rate (arginine-treated, 54%; control, 48%). Mares treated with l-arginine had a larger follicle for the 10 days preceding ovulation than control mares (30.4 ± 1.2 and 26.3 ± 1.3 mm, respectively; P < 0.05) and vascular perfusion of the dominant follicle tended (P = 0.10) to be greater for the 4 days before ovulation. No differences were observed between groups in diameter or vascular perfusion of the CL. Resistance indices, normalized to ovulation, were not significantly different between groups during the follicular or luteal phase. Oral l-arginine supplementation increased the size and tended to increase perfusion of the follicle 1, but had no effect on luteal perfusion or embryo recovery rates in mares.     

Selected contribution: redistribution of pulmonary perfusion during weightlessness and increased gravity.

To compare the relative contributions of gravity and vascular structure to the distribution of pulmonary blood flow, we flew with pigs on the National Aeronautics and Space Administration KC-135 aircraft. A series of parabolas created alternating weightlessness and 1.8-G conditions. Fluorescent microspheres of varying colors were injected into the pulmonary circulation to mark regional blood flow during different postural and gravitational conditions. The lungs were subsequently removed, air dried, and sectioned into approximately 2 cm(3) pieces. Flow to each piece was determined for the different conditions. Perfusion heterogeneity did not change significantly during weightlessness compared with normal and increased gravitational forces. Regional blood flow to each lung piece changed little despite alterations in posture and gravitational forces. With the use of multiple stepwise linear regression, the contributions of gravity and vascular structure to regional perfusion were separated. We conclude that both gravity and the geometry of the pulmonary vascular tree influence regional pulmonary blood flow. However, the structure of the vascular tree is the primary determinant of regional perfusion in these animals.     

Canine renal vascular response to bilateral carotid occlusion during hypoxia

Chloralose-urethane anesthetized dogs were utilized to determine if hypoxemic potentiation of the baroreceptor-mediated increase in renal sympathetic nerve activity (RSNA) results in sufficient renal vascular vasoconstriction to reduce renal blood flow (RBF) during bilateral carotid occlusion (BCO). Additionally, hypercapnia and mechanical ventilation were randomly combined with hypoxemia during BCO to determine if further augmentation of renal vasoconstriction could be accomplished. BCO resulted in a similar increase in blood pressure (renal perfusion pressure) in all periods. RBF was not reduced significantly by BCO during any period even though renal vascular resistance was significantly increased by BCO during each period. When hypoxemia was combined with hypercapnia and mechanical ventilation simultaneously, there was a greater percentage increase in renal resistance with BCO. During BCO, when renal perfusion pressure was returned to control values by suprarenal aortic constriction, RBF remained unchanged and renal resistance decreased to control values. These results indicate that the BCO-induced increase in RSNA is relatively moderate and, even when potentiated by hypoxemia, hypercapnia, and mechanical ventilation, is not sufficient to reduce RBF in the presence of an increase in blood pressure and renal autoregulation.     

Role of mechanosensitivity of the endothelium in weakening of the vascular bed vasoconstriction

The effect of control of arterial diameter by the shear stress at the endothelium on noradrenaline-induced constriction of femoral vascular bed was investigated in anaesthetised cats. We compared noradrenaline-induced responses during the perfusion of the hindlimb at a constant blood flow and at a constant pressure as vasoconstriction is accompanied by an increase in wall shear stress only in the former case. We found that the same concentration of noradrenaline at a constant flow caused an augmentation of vascular resistance that was considerably smaller than at a constant pressure perfusion. This difference was almost eliminated after either removal of the endothelium or selective impairment of the endothelial sensitivity to the shear stress. These findings demonstrate that the control of arterial smooth muscle tone at a constant blood flow by shear stress at the endothelium does weaken noradrenaline-induced vasoconstriction.     

Low-flow vascular remodeling in the metabolic syndrome X

Peripheral microvascular dysfunction is a common affliction in patients with the metabolic syndrome X. Previous studies have described a number of vascular impairments in vasomotor control in both human patients and animal models of syndrome X, but the net effect of these impairments on microvascular structure has not been examined. The goal of the current study was to test the hypothesis that syndrome X reduces muscle perfusion and induces vascular remodeling. The obese Zucker rat was used as a model of syndrome X, and the microcirculation of the hindlimb and brain were examined. Obese Zucker rats were obese, hyperlipidemic, hyperinsulinemic, and hyperglycemic. Blood flow to the hindlimb was reduced by 59% in obese rats relative to lean rats. Skeletal muscle resistance arteries of the hindlimb microcirculation of obese rats had thinner walls, smaller lumens, and reduced distensibility. Hindlimb microvessels from obese rats also demonstrated reduced expression of vascular smooth muscle cell markers. Each of these traits is consistent with low-flow remodeling. In contrast, the cerebral microcirculation, where flow is vigorously autoregulated, showed no vascular remodeling nor were there changes in microvascular smooth muscle marker expression. Neither physical activity nor muscle mass were significantly different between lean and obese rats. Taken together, these findings suggest that syndrome X, by reducing hindlimb blood flow, induces a marked remodeling of microcirculation to favor smaller, less distensible vessels. This remodeling may result in an architectural limitation of maximum perfusion capacity and may be an important maladaption in the progression of peripheral microvascular disease.     

Integrative control of the skeletal muscle microcirculation in the maintenance of arterial pressure during exercise.

Skeletal muscle blood flow and vascular conductance are influenced by numerous factors that can be divided into two general categories: central cardiovascular control mechanisms and local vascular control mechanisms. Central cardiovascular control mechanisms are thought to be designed primarily for the maintenance of arterial pressure and central cardiovascular homeostasis, whereas local vascular control mechanisms are thought to be designed primarily for the maintenance of muscle homeostasis. To support the high metabolic rates that can be generated during muscle contraction, skeletal muscle has a tremendous capacity to vasodilate and increase oxygen and nutrient delivery. During whole body dynamic exercise at maximal oxygen consumption (VO2 max), the skeletal muscle receives 85-90% of cardiac output. Yet despite receiving such a large fraction of cardiac output during high-intensity exercise, a vasodilator reserve remains with the potential to produce further elevations in skeletal muscle vascular conductance and blood flow. However, because maximal cardiac output is reached during exercise at VO2 max, further elevations in muscle vascular conductance would produce a fall in arterial pressure. Therefore, limits on muscle perfusion must be imposed during whole body exercise to prevent such drops in pressure. Effective arterial pressure control in response to a potentially hypotensive challenge during high-intensity exercise occurs primarily through reflex-mediated increases in sympathetic nerve activity, which are capable of modulating vasomotor tone of the skeletal muscle resistance vasculature. Thus skeletal muscle vascular conductance and perfusion are primarily mediated by local factors at rest and during exercise, but other centrally mediated control systems are superimposed on the dominant local control mechanisms to provide an integrated regulation of both arterial pressure and skeletal muscle vascular conductance and perfusion during whole body dynamic exercise.     

An approach to hypothermic renal preservation

A selective review of the literature concerning hypothermic renal storage suggests that two major interrelated factors control the success of the various procedures that have been advocated; these are the preservation of an intact vascular endothelium and the maintenance of adequate adenine nucleotide reserves. The damaging effect of warm ischemia is ascribed primarily to microcirculatory occlusion by rigid, ATP-depleted red cells, and secondarily to other effects of adenine nucleotide deficiency. It is suggested that continuous perfusion is a valuable technique when there has been significant warm ischemia, because it provides an effective method of restoring a patent microcirculation and is also useful when prolonged storage is required, since adenine nucleotide levels are better maintained than by the available alternatives. However, careful selection of perfusates is necessary to avoid additional perfusion injury to the endothelium. The criteria for effective preservation without continuous perfusion appear to be: little if any warm ischemic injury, effective removal of blood prior to storage, and the inclusion in the washout fluid of relatively impermeant solutes that will prevent cell swelling (particularly endothelial swelling) during preservation. An integrated approach involving both “washout” and perfusion techniques is suggested.     

The role of endothelial mechanosensitivity in vessel bed responses to changes in blood pressure in cats

In 19 anaesthetised cats, the response of vascular bed to increasing perfusion pressure at a constant blood flow perfusion consisted of two phases: a myogenic constriction and a subsequent arterial dilatation. The latter depended on ability of the endothelium to relax the smooth muscle under stress. The findings suggest that the control of the smooth muscle tone by a stress has to fight against the myogenic constriction and thus determines the changes in vascular resistance induced by an increased arterial pressure.     

Physiological and immunocytochemical evidence for a new concept of blood flow regulation in the corpus luteum

To explain the high rate of blood flow in the corpus luteum, we hypothesize that luteal blood vessels offer minimal resistance to flow and are incapable of vasomotion. This hypothesis was tested in rabbits at mid-pseudopregnancy by measuring blood flow in the corpus luteum and ovarian stroma with tracer-labeled microspheres at three levels of arterial blood pressure, which was manipulated by constricting the aorta above the ovarian artery. In addition, the distribution of vascular smooth muscle in the ovary was evaluated with morphological and immunocytochemical techniques. Decreases in arterial pressure were paralleled by reductions in blood flow in the corpus luteum, whereas ovarian stromal blood flow was unchanged. Consistent with our hypothesis, there was no change in the low level of vascular resistance offered by blood vessels in the corpus luteum, supporting the view that they are maximally dilated and incapable of autoregulation. Morphologically, the vessels within the corpus luteum appeared as large sinusoidal capillaries without smooth muscle, providing an anatomical explanation for the lack of vasomotor control demonstrated physiologically. The absence of vascular smooth muscle was confirmed with immunocytochemistry using an antibody against the muscle-specific intermediate filament, desmin. The fluorescein-labeled antibody decorated arteries and arterioles within the ovarian stroma and near the capsule of the corpus luteum, but did not decorate vessels in the corpus luteum of pseudopregnancy, providing additional evidence that the vessels of the corpus luteum lack the smooth muscle investment necessary to change vascular caliber. From these findings, we have proposed a novel scheme to explain intraovarian blood flow regulation. Vascular resistance in the ovarian stroma, as in most tissues, is acutely regulated by dilation or constriction of intratissue arterioles. In contrast, vascular resistance within the corpus luteum is modeled as a relatively invariable parameter, fixed at a low level by the morphological characteristics of the luteal vasculature. Therefore, the corpus luteum operates on a linear (maximally "vasodilated") pressure-flow curve, does not actively regulate intratissue blood flow, and is subject to acute regulation of perfusion only through changes in extra-luteal vessels.     

The spatial-temporal redistribution of pulmonary blood flow with postnatal growth.

The pulmonary vascular tree undergoes remarkable postnatal development and remodeling. While a number of studies have characterized longitudinal changes in vascular function with growth, none have explored regional patterns of vascular remodeling. We therefore studied six neonatal pigs to see how regional blood flow changes with growth. We selected pigs because of their rapid growth and their similarities to human development with respect to the pulmonary vascular tree. Fluorescent microspheres of varying colors were injected into the pulmonary circulation to mark regional blood on days 3, 12, 27, 43, and 71 after birth. The animals were awake and in the prone posture for all injections. The lungs were subsequently removed, air dried, and sectioned into approximately 2-cm(3) pieces. Flow on each injection day was determined for each piece. Despite the increase in the hydrostatic gradient in the lung with growth, there was a strong correlation between blood flow to the same lung piece when compared on days 3 and 71 (0.73 +/- 0.12). Although a dorsal-ventral gradient of perfusion did not exist on day 3, blood flow increased more in the dorsal region by day 12 and then gradually became more uniform by day 71. Although most of the lung pieces did not show any discernable pattern of blood flow redistribution, there were spatial patterns of blood flow redistribution that were similar across animals. Our findings suggest that local mechanisms, shared across animals, guide regional changes in vascular resistance or vasoregulation during postnatal development. In the pig, these mechanisms act to produce more uniform flow in the normal posture for an ambulating quadruped. The stimuli for these changes have not yet been identified.     

Ductal injection does not increase the islet yield or function after cold storage in a vascular perfusion model

Several studies have reported that pancreatic ductal preservation greatly improved the islet yield and function after cold storage. However, these studies were devoid of appropriate controls, such as vascular perfusion, which is routinely performed to preserve organs in the clinical setting. In this study, we created a vascular perfusion model using inbred rats, and investigated the effect of ductal injection on the islet yield and function after cold storage. Rat pancreases after 10 h cold ischemia were classified as follows: without ductal/vascular perfusion; with ductal injection; with vascular perfusion; and with ductal/vascular perfusion. The islet yield, function, viability, release of inflammatory mediators, and pathological changes in the exocrine tissues were assessed in the Hanks' Balanced Salt Solution (HBSS) model. The islet yield was also assesed by introducing University of Wisconsin Solution (UWS) and Histidine-Tryptophan-Ketoglutarate solution (HTK), which are the standard clinical preservation solutions. In the HBSS model, ductal injection and vascular perfusion significantly improved the islet yield compared with the control group. However, ductal injection showed no additional effects on the islet yield, function, viability and suppressing the release of inflammatory mediators when vascular perfusion was performed. Although ductal injection significantly decreased the apoptosis of exocrine cells, no beneficial effect on vacuolation was observed. In contrast, vascular perfusion significantly suppressed vacuolation in the exocrine tissues. Likewise, in the UWS and HTK model, ductal injection and vascular perfusion improved the islet yield compared with the control group. Nevertheless, the combination group showed no additional effects. These data suggest that ductal injection has no additional effect on islet yield and function after cold storage in a vascular perfusion model. We propose that ductal injection can be an effective and simple alternative for vascular perfusion prior to pancreas harvest, but is not necessary in most cases, since vascular perfusion is routinely performed.     

Atrial natriuretic factor in the Langendorff perfused coronary vasculature of the rabbit isolated heart

Removal of exogenously administered rat ANF (99-126) (rANF) from the rabbit coronary vasculature was investigated. Rabbit hearts were perfused using a modified Langendorff technique and ANF concentrations in the perfusate were measured by a radio-receptor assay. Under these conditions no major degradation of ANF was observed. On perfusion, however, the heart liberated large amounts of ANF. This release peaked 15 minutes after the initiation of perfusion, (685 + 220 pM) and then fell to a sustained basal level (305 + 80 pM) after 45 minutes. Although an increase in the perfusate flow rate reduced the ANF concentration, there was no significant difference in the rate of ANF release between the two flow rates used. After momentary cessation of flow ANF concentration fell to a significantly lower level, however, once again no significant change in rate of release occurred. These results suggest that the heart is not a major site of ANF degradation and that alterations in flow rate through the coronary vascular bed can cause changes in amounts of ANF released.     

Mesenteric afferent nerves are sensitive to vascular perfusion in a novel preparation of rat ileum in vitro

Using novel in vitro preparations of vascularly perfused rat ileum, we investigated mesenteric afferent sensitivity to vascular perfusion. Gut (GPP) and vascular (VPP) perfusion pressures were recorded simultaneously with afferent discharge (AD). After preconstriction (L-phenylephrine), capsaicin (100 microM, gut lumen) caused a transient increase in AD and a sustained fall in VPP, supporting afferent modulation of vascular tone. In turn, AD was affected by vascular perfusion rate (VPR). Increasing VPR step-wise (0.6 to 1.0, 1.4 and 1.8 ml/min) caused concomitant falls in AD, returning at 0.6 ml/min. Terminating flow (5 min) increased AD. Afferent responses were independent of changes in GPP, vascular O2, or the gut "tube" ("gut-off"). In gut-off studies, where capsaicin (100 nM ia) still reduced VPP, flow-associated falls in AD were abolished by the enzyme neuraminidase (0.2 U/ml ia or extravascularly over 20 min). In contrast, increased AD after stopped flow was unaffected. We propose that mesenteric afferents "sense" changes in vascular perfusion. The precise stimuli (pressure and/or flow) and the physiological relevance to control of local circulation remain to be determined.     

Vasomotion: the case for chaos

Fluctuations in vascular calibre, a phenomenon known as vasomotion, are ubiquitous in the microcirculation and represent emergent behaviour that involves synchronisation of Ca²⁺ oscillations in individual vascular cells. Ideally, coordinated interactions between locally generated vasomotion and neuro-humoral control mechanisms will allow optimal sensing of flow and pressure within vascular networks and thereby facilitate synergistic readjustments in local vascular conductance and flow under conditions of dynamically changing metabolic demand. Indeed, many studies have reported that vasomotion becomes more prominent under pathophysiological conditions, suggesting that it may serve as an adaptive homeodynamic response that maintains or re-establishes flow when perfusion is compromised. We here summarise evidence that the apparent irregular nature of vasomotion reflects deterministic interactions between a small number of dominant control variables, rather than random events, and may therefore be formally classified as chaotic. We also discuss the potential physiological benefits of chaos in the microcirculation and the key roles of signalling via gap junctions and nitric oxide.     

Impaired microvascular perfusion: a consequence of vascular dysfunction and a potential cause of insulin resistance in muscle

Insulin has an exercise-like action to increase microvascular perfusion of skeletal muscle and thereby enhance delivery of hormone and nutrient to the myocytes. With insulin resistance, insulin's action to increase microvascular perfusion is markedly impaired. This review examines the present status of these observations and techniques available to measure such changes as well as the possible underpinning mechanisms. Low physiological doses of insulin and light exercise have been shown to increase microvascular perfusion without increasing bulk blood flow. In these circumstances, blood flow is proposed to be redirected from the nonnutritive route to the nutritive route with flow becoming dominant in the nonnutritive route when insulin resistance has developed. Increased vasomotion controlled by vascular smooth muscle may be part of the explanation by which insulin mediates an increase in microvascular perfusion, as seen from the effects of insulin on both muscle and skin microvascular blood flow. In addition, vascular dysfunction appears to be an early development in the onset of insulin resistance, with the consequence that impaired glucose delivery, more so than insulin delivery, accounts for the diminished glucose uptake by insulin-resistant muscle. Regular exercise may prevent and ameliorate insulin resistance by increasing "vascular fitness" and thereby recovering insulin-mediated capillary recruitment.     

Skeletal muscle vasoconstriction produced by prostaglandin synthesis inhibitors; dependence on pump perfusion

A comparison was made of the effect of prostaglandin synthesis inhibitors (PGSI) on systemic blood pressure and hindlimb muscle vascular resistance of anesthetized dogs under different experimental conditions. When muscle blood flow was monitored using an extracorporeal or noncannulating electromagnetic blood flow probe, indomethacin (5 mg/kg i.v.) increased blood pressure slightly, but did not change vascular resistance. Administration of PGSI (indomethacin, meclofenamate, or naproxen, 5 mg/kg i.v.) after 2 hr of pump perfusion of the hindlimb caused a 22% increase in blood pressure, and 39% increase in vascular resistance 30 min afterwards. When administered immediately after instituting pump perfusion, indomethacin caused no significant change in blood pressure or vascular resistance at the 30 min interval, but at 60 min vascular resistance was increased. A similar vasoconstrictor response to indomethacin was obtained when it was infused in a lower dose intraarterially to the hindlimb, or when given i.v. after ligation of the renal pedicles. The results indicate that pump perfusion results in elaboration of a nonrenal prostaglandin(s) which maintains a vasodilator influence on the skeletal muscle vascular bed.     

Improved Functionality of the Vasculature during Conventionally Fractionated Radiation Therapy of Prostate Cancer

Although endothelial cell apoptosis participates in the tumor shrinkage after single high-dose radiotherapy, little is known regarding the vascular response after conventionally fractionated radiation therapy. Therefore, we evaluated hypoxia, perfusion and vascular microenvironment changes in an orthotopic prostate cancer model of conventionally fractionated radiation therapy at clinically relevant doses (2 Gy fractions, 5 fractions/week). First, conventionally fractionated radiation therapy decreased tumor cell proliferation and increased cell death with kinetics comparable to human prostate cancer radiotherapy. Secondly, the injection of Hoechst 33342 or fluorescent-dextrans showed an increased tumor perfusion within 14 days in irradiated tumors, which was correlated with a clear reduction of hypoxia. Improved perfusion and decreased hypoxia were not explained by increased blood vessel density, size or network morphology. However, a tumor vascular maturation defined by perivascular desmin+/SMA+ cells coverage was clearly observed along with an increase in endothelial, zonula occludens (ZO)-1 positive, intercellular junctions. Our results show that, in addition to tumor cell killing, vascular maturation plays an uncovered role in tumor reoxygenation during fractionated radiation therapy.     

Impaired blood flow autoregulation in nonfiltering kidneys: effects of theophylline administration

To investigate blood flow autoregulation in filtering and nonfiltering kidneys, renal blood flow was determined during graded reductions in renal perfusion pressure in seven anesthetized dogs containing both a filtering and nonfiltering kidney. In each dog, one kidney was made nonfiltering by the method of EH Blaine, JO Davis, and RT Witty (Circ Res 27:1081-1089, 1970). Renal perfusion pressure was decreased from 129 to 115, 99, and 83 mm Hg by stepwise constriction of the suprarenal aorta. In filtering kidneys, the maximum decrease in renal perfusion pressure reduced renal blood flow only 20.1% of control whereas renal blood flow of nonfiltering kidneys decreased by 41.0% of control. During aortic constriction, renal vascular resistance of nonfiltering kidneys remained unchanged or slightly increased. These hemodynamic changes were associated with significantly greater autoregulation indices in nonfiltering kidneys. In eight dogs with nonfiltering kidneys, competitive inhibition of adenosine with theophylline (9 mg/kg iv) restored autoregulation of renal blood flow as shown by significant decreases in renal vascular resistance. These data indicate that in the nonfiltering kidney model, autoregulation of renal blood flow is impaired. It is suggested that this impaired autoregulatory response may result from renal ischemia and the vasoconstrictor influence of elevated intrarenal adenosine concentration.