Renal and systemic effects of enalapril in chronic one-kidney hypertension

Role of the angiotensin type 1 receptor in modulating the carotid chemoreflex in an ovine model of renovascular hypertension

OBJECTIVE

The carotid body has been implicated as an important mediator and putative target for hypertension. Previous studies have indicated an important role for angiotensin II in mediating carotid body function via angiotensin type-1 receptors (AT1R); however, their role in modulating carotid body function during hypertension is unclear.

METHODS

Using a large preclinical ovine model of renovascular hypertension, we hypothesized that acute AT1R blockade would lower blood pressure and decrease carotid body-mediated increases in arterial pressure. Adult ewes underwent either unilateral renal artery clipping or sham surgery. Two weeks later, flow probes were placed around the contralateral renal and common carotid arteries.

RESULTS

In both hypertensive and sham animals, carotid body stimulation using potassium cyanide caused dose-dependent increases in mean arterial pressure but a reduction in renal vascular conductance. These responses were not different between groups. Infusion of angiotensin II led to an increase in arterial pressure and reduction in renal blood flow. The sensitivity of the renal vasculature to angiotensin II was significantly attenuated in hypertension compared with the sham animals. Systemic inhibition of the AT1R did not alter blood pressure in either group. Interestingly carotid body-evoked arterial pressure responses were attenuated by AT1R blockade in renovascular hypertension but not in shams.

CONCLUSION

Taken together, our findings indicate a decrease in vascular reactivity of the non-clipped kidney to angiotensin II in hypertension. The CB-evoked increase in blood pressure in hypertension is mediated in part, by the AT1R. These findings indicate a differential role of the AT1R in the carotid body versus the renal vasculature.

Intracranial baroreflex is attenuated in an ovine model of renovascular hypertension

We have previously shown that elevations in intracranial pressure (ICP) within physiological ranges in normotensive animals increase arterial pressure; termed the intracranial baroreflex. Hypertension is associated with alterations in reflexes which maintain arterial pressure however, whether the intracranial baroreflex is altered is not known. Hence, in the present study, we tested the hypothesis that in hypertension, physiological increases in ICP would not be accompanied with an increase in arterial pressure. Renovascular hypertension was associated with no change in heart rate, renal blood flow or ICP levels compared to the normotensive group. ICV infusion of saline produced a ramped increase in ICP of 20 ± 1 mmHg. This was accompanied by an increase in arterial pressure (16 ± 2 mmHg) and a significant decrease in renal vascular conductance. ICV infusion of saline in the hypertensive group also increased ICP (19 ± 2 mmHg). However, the increase in arterial pressure was significantly attenuated in the hypertensive group (5 ± 2 mmHg). Ganglionic blockade abolished the increase in arterial pressure in both groups to increased ICP. Our data indicates that physiological increases in ICP lead to increases in arterial pressure in normotensive animals but this is severely attenuated in renovascular hypertension.

Total peripheral resistance responsiveness during the development of secondary renal hypertension in dogs

OBJECTIVE

To determine whether the responses of total peripheral resistance and arterial pressure to vasoconstrictor agents are amplified as renovascular hypertension develops in dogs.

METHODS

After baseline measurements, the effects of renal artery stenosis (1K, 1C hypertension) were studied in groups of untreated and enalapril-treated dogs early (1-3 weeks) and later (4-6 weeks) as the hypertension developed. Both resting and open-loop haemodynamic measurements were made and the effects of acute intravenous infusions of vasopressin (0.25, 0.5 and 1.25 ng/kg per min) and phenylephrine (0.125, 0.25 and 0.50 microg/kg per min on arterial pressure, cardiac output and calculated total peripheral resistance responses were measured.

RESULTS

Renal artery stenosis induced an increase in arterial blood pressure in both groups of dogs, with similar changes in haemodynamics also observed in open-loop conditions. The slopes of arterial pressure and peripheral resistance responses to vasopressin and phenylephrine were not significantly changed in early or late hypertension, in either the untreated or enalapril-treated groups.

CONCLUSIONS

Hypertension from renal artery stenosis in dogs was due to nonautonomic, nonangiotensin II mechanisms. There was no evidence of vascular amplification of the effects of vasoconstrictor agents, indicating that this did not play a role in the development of hypertension.

Chronic renal ischemia: implications for cardiovascular disease risk

Chronic renal ischemia caused by atherosclerotic renal artery stenosis (RAS) is gaining recognition as a potentially important risk factor for cardiovascular (CV) morbidity and mortality. The etiology of increased risk of CV events is multifaceted and includes direct physiologic changes that increase risk as well as intermediate clinical effects that are associated with worse outcome. Physiologic changes associated with increased CV risk in patients with RAS include increased production of fibrogenic and vasoactive peptides such as renin, angiotensin, endothelin, and catecholamines, as well as endothelial cell dysfunction. Clinical intermediate conditions associated with higher incidences of CV events seen in patients with renal ischemia include hypertension, systemic atherosclerosis, chronic renal failure, and left ventricular hypertrophy and dysfunction. More thorough understanding of the myriad physiologic changes seen in patients with RAS will likely improve patient selection for renal artery revascularization. Clinical trials should examine a full range of CV and renal outcomes, not just blood pressure, to adequately assess the merits of revascularization.

Chronic renal ischemia: pathophysiologic mechanisms of cardiovascular and renal disease

Chronic renal ischemia caused by renal artery stenosis (RAS) elicits a complex biologic response. Although the traditional pathophysiologic pathways underlying renal ischemia have been well studied, there is emerging evidence that additional mechanisms may be responsible for producing many of the hemodynamic alterations and end-organ injury seen in patients with RAS, including persistent hypertension, renal insufficiency, and cardiac disturbance syndromes. A better understanding of these mechanisms may allow earlier identification of RAS, provide markers to predict the response to revascularization, or allow unique therapeutic targets for drug development. This and a subsequent article will explore the pathophysiologic and clinical implications of chronic renal ischemia.

Placental insufficiency and fetal growth restriction lead to postnatal hypotension and altered postnatal growth in sheep

Low birth weight has been associated with elevated arterial pressure in later life but mechanisms are unknown. Our aim was to determine the effects of low birth weight resulting from intrauterine growth restriction (IUGR) on fetal and postnatal arterial pressures and the potential roles of circulating cortisol and renin. We induced IUGR by umbilico-placental embolization (UPE) in fetal sheep from 120 d of gestation until birth (approximately 147 d); postnatal lambs (8 IUGR, 8 controls) were studied for 8 wk. Fetal and postnatal arterial pressures were measured and blood samples taken for measurement of gas tensions, cortisol concentrations and renin activity. In IUGR fetuses, mean arterial pressure (MAP) initially increased with UPE, but near term was not different to values in controls. IUGR lambs weighed 33% less than controls at birth and remained lighter than controls during the 8 postnatal weeks; their growth pattern was different to that of controls. IUGR lambs had lower MAP than controls, and this relative hypotension (-4 mm Hg) persisted throughout the 8 postnatal weeks. Covariate analysis showed that the relative hypotension of IUGR lambs could have resulted from their smaller size. Plasma cortisol concentrations were not different between IUGR and control animals before or after birth. Plasma renin activity was not different in postnatal IUGR lambs compared with controls. Thus, postnatal cortisol and renin levels were not consistent with the development of hypotension or hypertension. We conclude that late gestational IUGR in sheep leads to relative hypotension in the early postnatal period, probably a result of reduced body size.

Renovascular hypertension: structural changes in the renal vasculature

Experimental narrowing of the main renal artery to produce hypertension increases the aorta-glomerular capillary pressure difference and vascular resistance. This article examines the hypothesis that hypertension also may be caused by structural changes that narrow intrarenal blood vessels, similarly increasing preglomerular vascular resistance and the aortic-glomerular capillary pressure gradient. There is evidence of both wall hypertrophy and lumen narrowing of the preglomerular arteries in spontaneously hypertensive rats, with increased preglomerular resistance and aortic-glomerular capillary pressure difference. We have also attempted to induce structural changes in renal-preglomerular vessels experimentally by infusing angiotensin II at low doses (0.5 to 4.5 ng/kg per minute) into the renal artery of Sprague-Dawley rats and greyhound dogs for up to 4 weeks. This angiotensin II infusion produced apparent dose-related effects on preglomerular vessel structure and hypertension. The possibility that hypertension may be induced by structural changes in preglomerular resistance vessel walls, by simulation of the hemodynamic effects of main renal artery stenosis, deserves further investigation.

Systemic hemodynamic responses to chronic angiotensin II infusion into the renal artery of dogs

Chronic intrarenal infusion of angiotensin II (0.5 ng.kg-1.min-1) in dogs increases arterial pressure. In the present study we determined whether this was associated with changes in cardiac output or in total peripheral resistance. Mean arterial pressure did not change initially but was significantly increased over days 14-28 of the infusion period (+6 +/- 2 mmHg), as was total peripheral resistance (+4 +/- 2 mmHg.min.l-1). Neither cardiac output, renal blood flow, nor glomerular filtration rate was significantly changed over this period. To determine the influence of the autonomic nervous system on the developing hypertension, periodic acute autonomic ganglion blockade was performed. Before angiotensin II infusion ganglion blockade reduced total peripheral resistance and increased cardiac output, and this effect was similar across the 4 wk of angiotensin II infusion. Systemic hemodynamics were not affected by intravenous angiotensin II infusion (0.5 ng.kg-1.min-1). Thus intrarenal infusion of low-dose angiotensin II produced a chronic increase in arterial pressure due to an action within the kidney. The hypertension was associated with increased total peripheral resistance but not with marked changes in cardiac output or renal function or in the influence of the autonomic nervous system on systemic hemodynamics.

Renal and cardiovascular effects of renal medullary damage with bromoethylamine in dogs

Bromoethylamine (BEA, 30-40 mg/kg) was administered to dogs to determine whether damage to the inner medulla of the kidney, the putative source of a depressor hormone, causes hypertension in this species. Bromoethylamine produces hypertension in rats but this has not been confirmed in other species, although we have shown that this dose of BEA in dogs abolishes the release of a reno-medullary vasodepressor hormone in response to marked increases in renal perfusion pressure. During acute BEA administration over 1 h to conscious dogs, there were no significant effects on renal blood flow, arterial pressure or total peripheral resistance, but there was a significantly greater diuresis compared to vehicle administration. Over the first 10-14 days after BEA, daily urine output rose 5-10 fold initially and plasma creatinine concentration rose markedly. There was no significant effect on arterial pressure, cardiac output, total peripheral resistance, or renal blood flow over this period. BEA administration caused extensive damage to the thin limbs of the loops of Henle, widespread thrombosis of blood vessels and haemorrhage into the interstitium of the dog renal medulla. Reno-medullary interstitial cells were devoid of lipid droplets, were synthetic, and were associated with increased amounts of extracellular matrix. Thus extensive renal medullary damage by BEA administration to conscious dogs did not alter resting systemic haemodynamics, and these results therefore provide no evidence for a role for the medulla in the maintenance of resting arterial pressure in the dog.

Continuous versus intermittent angiotensin converting enzyme inhibition in renal hypertensive rats

Converting enzyme inhibitors impair renal function of the kidney beyond a stenosis of the renal artery in humans and induce histological lesions in the clipped kidney of renal hypertensive rats. In two-kidney, one clip hypertensive rats, we compared the time course and magnitude of the biochemical effects of angiotensin converting enzyme inhibition on the plasma renin-angiotensin system, cardiac hypertrophy, renal lesions, and 24-hour blood pressure decrease induced by either intermittent angiotensin converting enzyme inhibition administration (benazepril PO, 10 mg/kg once a day, n = 93) or continuous administration (benazeprilat, 3 mg/kg per day via osmotic pumps, n = 92). Control rats (n = 91) received the drug vehicle intermittently or continuously. Mortality was significantly reduced by both intermittent (n = 3/93) and continuous (n = 3/92) inhibition compared with controls (n = 18/91) (P < .001). Changes in the plasma renin-angiotensin system and blood pressure were parallel. A continuous suppression of the activity of the plasma renin-angiotensin system was associated with a 24-hour decrease in blood pressure with continuous inhibition, whereas intermittent inhibition induced a similar fall in blood pressure only for the first hours after gavage.(ABSTRACT TRUNCATED AT 250 WORDS)

Preservation of renal function by angiotensin during chronic adrenergic stimulation

The purpose of the present study was to determine the role of angiotensin II (Ang II) in mediating renal responses to chronic intrarenal norepinephrine infusion. Norepinephrine was continuously infused for 5 days into the renal artery of unilaterally nephrectomized dogs at progressively higher daily infusion rates: 0.05, 0.10, 0.20, 0.30, and 0.40 micrograms/kg/min. In three additional groups of dogs, norepinephrine infusion was repeated during chronic intravenous captopril administration to fix plasma Ang II concentration at 1) low levels (no Ang II infused), 2) high levels in the renal circulation (Ang II infused intrarenally at a rate of 1 ng/kg/min), and 3) high levels in the systemic circulation (Ang II infused intravenously at a rate of 5 ng/kg/min). In the control group of animals with intact renin-angiotensin systems, there were progressive increments in mean arterial pressure (from 96 +/- 4 to 141 +/- 6 mm Hg) and plasma renin activity (from 0.4 +/- 0.1 to 10.9 +/- 4.5 ng angiotensin I/ml/hr) and concomitant reductions in glomerular filtration rate and renal plasma flow to approximately 40% of control during the 5-day norepinephrine infusion period. In marked contrast, when captopril was infused chronically without Ang II, mean arterial pressure was 20-25 mm Hg less than that under control conditions, and the renal hemodynamic effects of norepinephrine were greatly exaggerated; by day 3 of norepinephrine infusion, both glomerular filtration rate (16 +/- 2% of control) and renal plasma flow (12 +/- 4% of control) were considerably lower than values in control animals (86 +/- 4% and 80 +/- 8% of control, respectively). Similarly, when a high level of Ang II was localized in the renal circulation during captopril administration, mean arterial pressure was depressed, and again there were pronounced renal responses to norepinephrine. Conversely, when Ang II was infused intravenously during captopril administration, mean arterial pressure was not reduced, and the glomerular filtration rate and renal plasma flow responses to norepinephrine were similar to those that occurred under control conditions. These findings indicate that the renin-angiotensin system prevents exaggerated renal vascular responses to chronic norepinephrine stimulation by preserving renal perfusion pressure.

Renovascular hypertension: information from experiments using conscious dogs

1. Evidence from experiments in conscious, instrumented dogs shows that hypertension from renal artery stenosis is due to: (i) the stimulus, the mechanical resistance of the stenosis; and (ii) the secondary responses to this, especially angiotensin II (initially) and cardiovascular hypertrophy. 2. The hydraulic resistance of the stenosis is responsible for about 20-25% of the rise in blood pressure. 3. Angiotensin II is initially the most important secondary response to the stenosis. Within days, however, other as yet undetermined factors become dominant in the maintenance of the hypertension. The most important of these factors is probably cardiovascular hypertrophy. 4. These secondary factors are homeostatic, in that they mitigate the effects of stenosis on renal function.

Development of hypertension from unilateral renal artery stenosis in conscious dogs

The renal and systemic changes after stenosis of the left renal artery (n = 5) or sham stenosis (n = 6) in conscious dogs were studied sequentially over 25 days. Stenosis produced a prompt rise in arterial pressure, which was at all times due to reduced peripheral vascular conductance, with no increase in cardiac output despite initial evidence of mild fluid retention. The decrease in peripheral conductance was attributable to 1) the stenotic kidney (25% of the total and due to the mechanical effect of the stenosis itself), 2) the nonstenotic kidney (about 15% of the total and not caused by angiotensin II), and 3) the nonrenal vasculature (60%). The decrease in conductance in the nonrenal vasculature was due partly to angiotensin II, but there was also a gradually developing non-angiotensin II component. Acute administration of captopril caused significantly greater changes in arterial pressure and peripheral conductance throughout the period of stenosis than before stenosis (and greater than in sham-stenosis dogs), indicating that angiotensin II was constricting the peripheral vasculature even when plasma renin levels were no longer elevated. In the stenotic kidneys, captopril produced a fall in renal vascular resistance, but renal blood flow did not rise because there was an approximately equal rise in the resistance of the stenosis. There was no evidence for a role for the autonomic nervous system in the hypertension, as ganglion blockade (pentolinium) had similar hemodynamic effects before and after stenosis. Thus, the hypertension was due at all times to reduced peripheral conductance, with the two kidneys responsible for 40% of this reduced conductance.

Renal hypertension following aortic constriction is abolished by angiotensin II converting enzyme inhibitor, but not by low-salt diet

This study evaluates the role of different sodium intakes and the role of angiotensin II in the development and the maintenance of renovascular hypertension in rats with constriction of the aorta proximal to the renal arteries. The rats were studied 3 weeks after surgery when the hypertension was well established. Glomerular filtration rate was decreased and filtration fraction was increased in rats with proximal aortic constriction. Low and high salt intakes had no effect on glomerular filtration and filtration fraction. Treatment with angiotensin II converting enzyme inhibitor increased the glomerular filtration rate and reduced the filtration fraction in rats with proximal aortic constriction to the same levels as in control rats. Serum levels of angiotensin II were about the same in rats with proximal aortic constriction as in control rats. Conclusion. The renovascular hypertension in proximal aortic constriction is influenced by locally formed angiotension II but not by alterations in salt intake.

Renal venous wedge pressure in renal wrap hypertension in rabbits

1. Renal cellophane wrapping to produce hypertension causes thickening of the capsule of the kidney. To determine whether this compresses the kidney, deep renal vein wedge pressure was measured as an estimate of tissue pressure in anaesthetized rabbits 1 month after cellophane wrapping (n = 5) or a sham operation (n = 3). 2. Renal vein wedge pressure was 18.3 +/- 2.0 mmHg in hypertensive rabbits and 8.4 +/- 1.1 mmHg in the sham-operated rabbits. 3. Arterial pressure was raised or lowered with angiotensin II or glyceryl trinitrate, respectively. Arterial and wedge pressures were approximately linearly related and, at any given arterial pressure, wedge pressure was approximately 8 mmHg higher in the cellophane-wrapped kidney than in the kidney of the sham-operated group. 4. These results, showing that renal wedge pressure is elevated in renal wrap rabbits, indicate that the kidneys are compressed, probably by the thickened renal capsule. This may explain the increased renal vascular resistance seen in this form of hypertension.

Effect of antihypertensive therapy on the cardiovascular amplifiers

1. In established chronic hypertension the amplifier properties of vessels and heart contribute about 70% to the maintenance of the elevated blood pressure (BP). Recent studies in spontaneously hypertensive rats (SHR) suggest that the structural changes occur very early and their amplifier properties may be critical for the development of hypertension. 2. In patients with primary hypertension, the greater the regression of cardiac and vascular hypertrophy, the slower the subsequent redevelopment of hypertension. Following regression of hypertrophy, the antihypertensive action of moderate regular exercise can maintain BP in the normal range in a proportion of patients. 3. Early treatment of SHR with enalapril greatly reduces the subsequent 'steady-state' BP in SHR. This produces virtually complete regression of vascular hypertrophy, but somewhat lesser degrees of regression of cardiac hypertrophy. 4. These studies serve as models for primary and secondary prevention of hypertension. A strategy based on intermittent drug and non-pharmacological therapy in man may contribute to the secondary prevention of atherosclerosis, in view of the adverse effects on lipid profiles of many antihypertensive drugs.

Two forms of vasoconstriction in systemic hypertension

Clinical, pharmacologic and biochemical evidence characterizes essential hypertension as a heterogeneous spectrum of pathophysiologic substances rather than the single entity it has long been presumed to be. Although the causes of essential hypertension remain obscure, 2 different mechanisms for long-term vasoconstriction that sustain diastolic hypertension in the experimental and clinical forms of primary aldosteronism and renovascular hypertension can also be identified and quantified among patients with essential hypertension. The first mechanism is renin independent, requires antecedent sodium retention and appears related to abnormal membrane transport of calcium. This vasoconstriction is identified by low plasma renin and ionized calcium and is correctable by sodium depletion or calcium channel or alpha blockade. The second vasoconstrictor mechanism is renin mediated and involves an increase in cytosolic calcium. This mechanism is quantifiable by the plasma renin level or the hypotensive response to an antirenin-system drug (converting enzyme inhibitor, beta blocker or saralasin). Depending on the state of sodium balance, these 2 mechanisms contribute reciprocally to maintenance of arteriolar tone in experimental models, in both normal and hypertensive people, and in patients with congestive heart failure. In these situations, at the extremes of the range of plasma renin values, one or the other mechanism predominates, whereas in the medium range of renin values both mechanisms can be operative. These interrelations provide a basis for applying more precisely tailored therapy and for stratifying patients pathophysiologically for further study.

Angiotensin II-induced contraction of mesangial cells in acute renal artery stenosis in dogs

1. Renal artery stenosis was induced in anaesthetized dogs, and the kidney rapidly fixed after 30 min. 2. Electron microscopy revealed marked folding of the paramesangial basement membrane in stenotic kidneys (n = 7). The extent of this folding was significantly less in dogs treated with captopril (n = 6). 3. It is suggested that this folding reflects angiotensin II-induced contraction of the mesangial cells, which may help maintain glomerular filtration rate following stenosis.