A new perspective on therapeutic inhibition of advanced glycation in diabetic microvascular complications: common downstream endpoints achieved through disparate therapeutic approaches?

A commonality among the chemically disparate compounds that inhibit the formation and accumulation of advanced glycation end products (AGEs) or their signalling pathways is their end organ protection in experimental models of diabetes complications. Although this group of therapeutics are structurally and functionally distinct with numerous mechanisms of action, the most important factor governing their therapeutic capability is clearly their ability to alleviate the tissue burden of advanced glycation, rather than the biochemical mechanism by which this is achieved. However, it remains to be determined if it is the reduction in tissue AGE levels per se or inhibition of downstream signal pathways which is ultimately required for end organ protection. For example, a number of these agents stimulate antioxidant defences, modify lipid profiles and inhibit low-grade inflammation. These novel actions emphasise the importance of further examination of the advanced glycation pathway and in particular the diverse action of these agents in ameliorating the development of diabetic complications such as nephropathy.

Role of angiotensin and its inhibition in hypertension, ischemic heart disease, and heart failure.

This is a personal historical account relating the events that led to the first application of angiotensin inhibition (either by ACE inhibitors or by angiotensin receptor blockade) to the investigation of the pathogenesis and treatment of hypertension, ischemic heart disease, and heart failure. Included are animal experiments, clinical observations, and the earliest clinical experimental studies that helped define some of the detrimental effects of angiotensin II and the beneficial hemodynamic results of its inhibition, which have been subsequently corroborated and amplified by large randomized outcome trials.

[Microalbuminuria and left ventricular hypertrophy in essential arterial hypertension. A study in non-diabetic patients]. / Microalbuminurie et hypertrophie ventriculaire gauche au cours de l'hypertension artérielle essentielle. Etude chez des sujets non diabétiques.

To evaluate the relationship between urinary albumin excretion and left ventricular hypertrophy in essential hypertension, we studied, cross-sectionally, 64 subjects with essential hypertension and no diabetes. Urinary albumin excretion and Sokolow index correlated significantly (r = 0.483; P = 0.0001). Five subjects were positive for microalbuminuria (> 30 mg/24 h) and Sokolow index (> 35 mm); 43 were negative for both, with a concordance rate of 77 percent (chi-squared test 11.1; P = 0.0009). Stepwise multivariate regression analysis indicated two independent determinants for urinary albumin excretion: Sokolow index (F = 18.29), and diastolic blood pressure (F = 12.23). The relationships between urinary albumin excretion, Sokolow index, and blood pressure were not different in the 18 subjects taking angiotensin I-converting enzyme inhibitors and in the 46 others. The close relationship between urinary albumin excretion and Sokolow index observed in this study suggests that left ventricular hypertrophy due to hypertension may account for the increased cardiovascular mortality observed in non diabetic subjects with microalbuminuria.

Pharmacologic treatment of occlusive mesenteric ischemia in rats.

This study assessed the contribution of angiotensin II, oxygen-free radicals, and vasopressin to the mortality of acute mesenteric ischemia in rats. Rats received saline replacement (16 ml/kg/hr) for 3 hr during and after 85 min of superior mesenteric artery (SMA) occlusion. Only 21% of rats that received saline alone (n = 14, control) survived 48 hr, significantly less than the 100% survival of sham-operated rats (no SMA occlusion, n = 5, P less than 0.01). Neither teprotide (an angiotensin converting-enzyme inhibitor), allopurinol (to reduce oxygen-free radical formation), nor a specific vasopressin antagonist [1-(beta-mercapto-beta,beta-cyclopentamethyleneproprionic acid), 2-(O-methyl) tyrosine arginine-vasopressin] improved 48-hr survival, which was 17% in each group (n = 6, each). Survival improved significantly to 86% (n = 7, P less than 0.001) when intravenous glucagon (1.6 micrograms/kg/min) was given for 2 hr after SMA reperfusion. Survival after dopamine infusion (12 micrograms/kg/min iv) was 67% at 48 hr, a nearly significant improvement (n = 9, P less than 0.06). These results suggest that angiotensin II, oxygen-free radicals, and vasopressin do not contribute significantly to the high mortality observed after acute intestinal ischemia in this rat model, but that glucagon, and to a lesser extent, dopamine, are potentially therapeutic.

Renal effects of angiotensin converting enzyme inhibitors in hypertension.

This review focuses on the renal effects of the angiotensin converting enzyme inhibitors, captopril and enalapril. Emphasis is placed on the renal response to these drugs in patients with primary essential hypertension, and in hypertension accompanying renal parenchymal disease. Specifically reviewed are the renal function and hemodynamic, salt and water, body fluid composition, and urinary protein excretion responses. The interruption of the renin-angiotensin-aldosterone axis has the potential to produce a variety of favorable renal responses, including reduction of renal vascular resistance, enhancement of renal blood flow, enhancement of glomerular filtration rate, acute natriuresis, sustained diuresis, and a decrease in urinary protein excretion. Data in support of these potential renal perturbations are presented and discussed. The results suggest that the angiotensin converting enzyme inhibitors are important therapeutic agents in the treatment of hypertensive disease, in that they may modify pathophysiologic renal abnormalities encountered in this disease state.

Chronic treatment of hypertensive patients with converting enzyme inhibitors.

It is widely accepted that pharmacologic reduction of the blood pressure of hypertensive patients reduces the risk of at least some of the major cardiovascular complications (1-5). All major studies were carried out before orally active converting enzyme inhibitors had become available. In other words, very effective antihypertensive drugs have been around for quite some time and have already proven their efficacy. Therefore, the considerable enthusiasm that has developed during the very recent years for the new converting enzyme inhibitors should be evaluated in the light of previously available antihypertensive drugs, the more so, as drugs cheaper than converting enzyme inhibiting agents are presently available. Thus, the increased expense when using this new class of antihypertensive compounds should be justified by a therapeutic gain. When evaluating a class of antihypertensive drugs such as converting enzyme inhibitors, there are basically three main considerations: What is their efficacy in long-term use? This includes the effect on blood pressure, on heart, on hemodynamics, and on blood flow distribution. What are the metabolic effects? What is the effect on sodium and potassium excretion? How are the serum lipids affected by its use? Are there any untoward effects related either to the chemical structure of the compound per se or rather to the approach? In particular, are there any central effects of the drug which can cause discomfort to the patient? The following discussion has the principal aim to review these aspects with chronic use of oral converting enzyme inhibiting agents without, however, even attempting to provide an exhaustive review of the subject.

[Angiotensin-converting enzyme inhibition: direct and indirect mechanisms]. / Angiotensin-Conversions-Enzym-Hemmung: Direkte und indirekte renale Mechanismen.

The introduction of angiotensin-converting-enzyme (ACE)-inhibitors into the analysis of the renin-angiotensin system (RAS) had broadened our knowledge of the integral role of renin and the kidney in circulatory homeostasis and has provided a pathophysiologically based concept for the treatment of hypertension. When the RAS is activated, as it is when sodium is restricted, the renal blood supply shows the most striking vasodilatation among vascular beds assessed after ACE-inhibition. Sodium excretion rises, there is a fall in blood-pressure, and plasma concentrations of angiotensin II (AII) and aldosterone are reduced. Conversely, with sodium loading the hemodynamic and hormonal effects of ACE-inhibitors are small. In 50-60% of normal or high-renin patients with essential hypertension ACE-inhibitors induce a potentiated acute renal response: renal blood flow and sodium excretion increase more than they do in the remainder of the hypertensives or in normal subjects. The responders of the hypertensive patients fail to increase renal blood flow or to enhance renal vascular responsiveness to infused AII when they shift from a low to a high sodium intake. The altered renal response of these "sodium-sensitive" hypertensives could be related to local activity of the RAS which is insufficiently suppressed by sodium loading. ACE-inhibition reverses this failure of the renal blood supply to respond to sodium loading. Kidneys of spontaneously hypertensive rats and the renin-rich kidney of Goldblatt-hypertensive rats show an increased tubulo glomerular (TG) feedback response as compared to normal kidneys. The change in TG-feedback response might be expected to contribute to the inability of the hypertensive kidney to respond adequately to sodium loading. ACE-inhibition reduces TG-feedback sensitivity. In renal artery stenosis glomerular capillary pressure tends to be maintained by an AII mediated rise in postglomerular resistance. Suppression of AII by ACE-inhibition reduces efferent vascular tone and thus filtration rate. There is a potential for interaction of ACE-inhibitors with the kallikrein and prostaglandin pathways as well as with the sympathetic nervous system and endogenous opioids. This may modify the renal and blood pressure responses to these compounds.

Cerebral vasospasm following aneurysmal subarachnoid hemorrhage.

Cerebral vasospasm following aneurysmal subarachnoid hemorrhage is one of the most important causes of cerebral ischemia, and is the leading cause of death and disability after aneurysm rupture. There are two definitions of cerebral vasospasm: angiographic and clinical. Care must be exercised to be certain that it is clear which entity is being addressed. The diagnosis of the clinical syndrome is one of exclusion and can rarely be made with absolute certainty. The pathogenesis of cerebral vasospasm is poorly understood. Most current theories focus on the release of factors from the subarachnoid clot. More attention must be given to the role of endothelial damage and alterations in the blood-arterial wall barrier. The application of modern techniques for studying vascular smooth muscle which have been developed as a result of research in the areas of hypertension and atherosclerosis must be applied to the problem of cerebral vasospasm. A stress test to select patients with angiographic arterial narrowing who have adequate cerebral vascular reserve to undergo surgery should be developed. The optimal treatment of vasospasm awaits development of agents for blocking or inactivating spasmogenic substances or blocking arterial smooth muscle contraction. Rheological or hemodynamic manipulations to prevent or reverse ischemic consequences of vasospasm are relatively effective, but complicated and hazardous, and should be viewed principally as interim measures awaiting development of more specific therapies for the arterial narrowing.

Reduction in hypertension-induced protein synthesis in the rat pulmonary trunk after treatment with teprotide (SQ 20881).

Angiotensin II has been previously implicated as a mediator of vasoconstriction during the development of hypoxic pulmonary hypertension. The effect of angiotensin-converting enzyme inhibition with teprotide (SQ 20881) on development of pulmonary hypertension was determined by measurement of the drug's ability to modify hypertension-induced protein synthetic changes in the rat pulmonary trunk. Rats were injected with either SQ 20881 (2 mg/kg body wt every 8 hr) or saline vehicle during exposure to chronic hypoxia at 0.5 atm for either 3 or 7 days. Comparisons were made of tissue weight, absolute protein content, and in vitro synthesis of collagen and noncollagen protein of the pulmonary trunks of SQ-treated hypoxic, SQ-treated normoxic, saline-treated hypoxic, and saline-treated normoxic rats. Treatment of hypoxic rats with SQ 20881 was found to significantly decrease right ventricular pressure, tissue weight, absolute protein content, and in vitro protein synthesis after 7 days compared to saline-treated hypoxic rats. Neither right ventricular hypertrophy nor the development of polycythemia was decreased by SQ 20881 treatment.

Monotherapy of hypertension with angiotensin-converting enzyme inhibitors.

Angiotensin-converting enzyme (ACE) inhibitors are clearly effective treatment for all stages of hypertension. Since the introduction of captopril in 1981, numerous ACE inhibitors have been synthesized and are under investigation. Their exact antihypertensive mechanism of action remains unclear. Part of their effect may be mediated by vasodilator prostaglandins. Early studies with as much as 1,000 mg a day captopril demonstrated the agent's ability to reduce blood pressure, but only 10 percent of the severely hypertensive patients were controlled with monotherapy. Subsequent studies have demonstrated that patients with mild to moderate hypertension can be controlled with ACE inhibitor alone, although there is a tendency for the very low doses to lose their effect with time. Black patients are less readily controlled with monotherapy. Captopril has now been demonstrated to be effective in the hypertension of scleroderma and has reversed scleroderma renal crisis. ACE inhibitors are also effective for the treatment of severe congestive heart failure.

The kidney and strategies for the treatment of hypertension.

Renal compensatory mechanisms are a chief consideration when selecting an antihypertensive agent. The relationships, therefore, between renal blood flow and glomerular filtration rate, sodium handling by the kidney, and release of renin require particular attention. We shall examine therapeutic measures such as beta adrenergic blockers, vasodilators, calcium entry blockers, and converting enzyme inhibitors in light of their effects on renal blood flow.

Haemodynamic responses to specific renin-angiotensin inhibitors in hypertension and congestive heart failure. A review.

The renin-angiotensin system is an important regulator of vascular resistance in many patients with hypertension and congestive heart failure. To quantitatively evaluate this contribution requires correlation of markers of the renin-angiotensin system with haemodynamic parameters, notably blood pressure, cardiac output, and calculated systemic vascular resistance. In addition, to determine ventricular loading properties, assessment of cardiac filling pressures is also required. The availability of specific pharmacological inhibitors of the renin-angiotensin system greatly enhances such correlation, as the haemodynamic consequence of blocking the renin-angiotensin system can then more fully identify its contribution. In the last decade, highly specific pharmacological inhibitors have become available to serve such a purpose. Renin inhibitory peptides, and renin-specific antibodies can block the rate-limiting step of the renin-angiotensin cascade: namely, the cleavage of 4 amino acids from the angiotensinogen substrate by renin. However, this method of blockade is still at the early stages of investigation. More readily available are converting enzyme inhibitors which block the formation of angiotensin II, the potent vasoconstrictor which mediates increased systemic vascular resistance, and angiotensin II analogues which compete with endogenous angiotensin II for vascular and adrenal receptors. Although hypertension and chronic congestive heart failure are clinically distinct entities in many respects, their common bond is the fact that both pathological mechanisms are mediated by an increase of systemic vascular resistance. The implications of blocking the resulting vasoconstriction in both entities are therefore quite similar. This review summarises our present knowledge of the contribution of the renin-angiotensin system to the vasoconstriction of hypertension and congestive heart failure, and also summarises the haemodynamic consequences of such inhibition. The implications of the response to these specific pharmacological probes, as well as their limitations, are discussed. Their importance rests not only in their therapeutic application, but also in their contribution as probes for pathophysiological mechanisms of vasoconstriction in cardiovascular disease.

Role of angiotensin converting enzyme inhibitors in essential and renal hypertension. Effects of captopril and enalapril on renin-angiotensin-aldosterone, renal function and hemodynamics, salt and water excretion, and body fluid composition.

Among the many generic classes of drugs currently being used for the treatment of hypertension, few, following long-term therapy, improve or correct the underlying renal function and hemodynamic abnormalities encountered in patients with sustained hypertension. This review focuses on the renal effects of the angiotensin converting enzyme inhibitors captopril and enalapril. Each drug is discussed in terms of its short- and long-term effects on the renin-angiotensin-aldosterone system, renal function and hemodynamics, salt and water excretion, and body fluid composition. Data are presented that demonstrate that enalapril, used alone or in combination with diuretic therapy, has the unique ability to control hypertension, to improve glomerular filtration rate and effective renal plasma/renal blood flow, and to decrease renal vascular resistance, without producing adverse effects on salt and water excretion or body fluid composition. If the safety of enalapril is confirmed in long-term studies, the drug will clearly assume a prominent role as either first- or second-step (in combination with a diuretic) therapy in the treatment of hypertension.

Antisera to human renin normalize renin-dependent hypertension in the monkey: therapeutic implications.

Polyclonal antisera raised against pure human renin normalize renin-dependent blood pressure elevation in the monkey (M. fascicularis). In vitro, comparable inhibition of either human or monkey plasma renin by the antisera was demonstrated. In vivo, intravenous infusion of 2 ml of antisera did not change mean arterial pressure of salt-repleted monkeys, however, its administration to salt-depleted monkeys with elevated plasma renin activity lowered mean arterial pressure 10 Torr. A 25 Torr rise in mean arterial pressure and increase in plasma renin activity occurred promptly after inflation of a suprarenal aortic cuff in conscious uninephrectomized monkeys. Administration of 2 ml of antisera to these monkeys normalized mean pressure, which was reduced by an additional 10 Torr if the animals were previously salt-depleted. Maximal hypotension occurred within 1 hour and was sustained for approximately 10 hours. Because of the differing specificities of polyclonal antisera, sera raised in two laboratories against human renin purified from different sources were employed. Identical results were obtained. This is the first demonstration of the use of antisera to inhibit endogenous renin activity in primates and predicts the in vivo efficacy of renin antisera as experimental, diagnostic and therapeutic agents.

Converting enzyme inhibition to identify and treat renin-mediated or sodium-volume related forms of increased peripheral resistance in hypertension and in congestive heart failure.

Ten years of experience with three different converting enzyme inhibitors (CEI; teprotide, captopril and enalapril) in over 300 hypertensive patients reveals that CEI act largely to block renin-angiotensin mediated vasoconstriction. Thus, their effectiveness or lack of it is predicted by the baseline plasma renin measurement. Accordingly, responses to these pharmacological agents can be used to identify and quantify renin-mediated vasoconstriction in the spectrum of hypertensive diseases. The converse is also generally true. Patients failing to respond to CEI exhibit low renin values and their increased peripheral resistance appears related to other mechanisms, possibly involving a subtle increase in total body sodium. Thus, low renin states such as low-renin essential hypertension, primary aldosteronism, and anephric man exhibit little or no response to CEI. The relationship between the renin system activity and effectiveness of CEI reflects a specific interference with a particular pathogenic mechanism which is further supported by the fact that two other types of renin system inhibitors (beta-blockers and saralasin) are similarly effective or ineffective according to the operant renin profile also by studies in patients with congestive heart failure without hypertension in whom the same relationships can be demonstrated. Like hypertensives, heart failure patients exhibit a broad spectrum of renin activity values, and their pretreatment renin levels predict the responses to CEI. We have also found that plasma renin values in heart failure are dependent on sodium intake. When salt is administered, renin falls and patients then become unresponsive to CEI.(ABSTRACT TRUNCATED AT 250 WORDS)

Drug suppression of the angiotensin system in congestive heart failure.

Congestive heart failure is frequently associated with elevated systemic vascular resistance. Lowering resistance can improve cardiac performance and alleviate symptoms. The angiotensin-converting enzyme inhibitors offer a new way to lower resistance and have certain advantages, including the inhibition of compensatory mechanisms. However, skillful use of these compounds demands a thorough understanding of their pharmacologic properties and of the pathophysiology of congestive heart failure.