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Query: UMLS:C0018801 (heart failure)
 72,216 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The emergence of diuretic drugs and angiotensin converting enzyme (ACE) inhibitors ranks amongst the major therapeutic advances of modern medicine. The discovery of these drug groups arose largely by chance, yet each has dramatically influenced the treatment of congestive cardiac failure and arterial hypertension. The central role which diuretics have had in the management of both oedema and hypertension hinges on their ability to induce a net renal excretion of solute and water by selective interference with either active or passive ion transport processes in different segments of the nephron. Irrespective of sites of action, the continued antihypertensive action of diuretics is characterized by a reduction in plasma volume and extracellular fluid (ECF) volume that lasts for as long as the diuretic is given. The mechanism of this effect remains unclear but may involve autoregulatory reactions that leave cardiac output unaltered but maintain a sustained reduction in total peripheral resistance. ACE inhibitors also lower blood pressure by decreasing total peripheral resistance, leaving cardiac output, plasma volume and ECF volume unchanged. The detailed way these haemodynamic changes are achieved remains unknown but inhibition of converting enzyme present not only in the kidney but also in many extrarenal tissue sites, appears important. In both hypertension and cardiac failure, however, the kidney acts as a key target organ for ACE inhibitors. The increased renal vascular resistance and inappropriate renal salt excretion are reversed with enhanced renal blood flow and saluresis. Both angiotensin II (AII) and vasopressin-mediated contraction of glomerular mesangial cells is inhibited, making glomerular filtration more efficient. Reduced aldosterone secondary to blockade of AII formation contributes to saluresis whilst encouraging positive potassium balance. ACE inhibition also impairs breakdown of kinins which may contribute to intrarenal and peripheral vasodilation either on their own or via release of prostaglandins and other vasoactive substances. The hypotensive actions of diuretics are potentiated by ACE inhibition primarily through blockade of AII formation and prevention of secondary aldosteronism. In combination, these drugs permit low doses to be used because of their synergistic effects. Caution has to be exercised whenever ACE inhibition is used, without and especially with diuretics, in the management of renovascular hypertension and other low-perfusion states. In these circumstances, AII plays an important autoregulatory role in preserving glomerular filtration through an increase in post-glomerular resistance.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Evolution of diuretics and ACE inhibitors, their renal and antihypertensive actions--parallels and contrasts. 303 17

The renin-angiotensin system appears to have evolved millions of years ago as a primary attempt to preserve circulatory homeostasis at a time when the principal cause of a low cardiac output was intravascular volume depletion. Angiotensin II supported systemic BP by direct systemic vasoconstriction, by facilitating the central and peripheral effects of the sympathetic nervous system, by promoting renal sodium retention by the production of aldosterone, and by increasing total body water by enhancing thirst and the synthesis of vasopressin. In addition, angiotensin II evolved as an important mechanism to preserve the glomerular filtration rate in low-flow states. These actions of angiotensin II were beneficial when the system first evolved, but its activation in patients with heart failure not only fails to reverse the low-output state but further exacerbates loading conditions in the left ventricle, thereby leading to worsening heart failure. Moreover, increased levels of angiotensin II cause heightened sympathetic nervous activity, potassium depletion, and hyponatremia, each of which can lead to further clinical deterioration. Therefore, activation of the renin-angiotensin system in heart failure might appear (at first) to be a maladaptive response. Recent evidence, however, suggests that this hormonal system continues (even in heart failure) to carry out the primary functions for which it was designed. Angiotensin II plays an important role in preserving systemic BP and in preserving the glomerular filtration rate as renal artery pressure and renal blood flow decline; in addition, by stimulating the synthesis of aldosterone, the renin-angiotensin system provides an important role for potassium disposal.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Adaptive and maladaptive actions of angiotensin II in patients with severe congestive heart failure. 303 91

Neurohumoral vasoconstrictor systems are activated in heart failure and influence left ventricular function by modifying pre- and afterload. The renin-angiotensin system, sympathetic nerve activity and vasopressin have all been implicated as mechanisms of vasoconstriction. We investigated the vasoconstrictive action of vasopressin by blocking its vascular receptors by a specific antagonist in animal models of heart failure due to rapid right ventricular pacing in dogs and to aortocaval fistula, pulmonary stenosis and aortic stenosis in rats. In all animal models studied, we observed an inappropirately elevated secretion of vasopressin in association with a decreased plasma osmolality. We found only a small reduction of aortic pressure and peripheral vascular resistance following the vasopressin inhibitor. The renin-angiotensin system and sympathetic nerve activity were activated in all animal models. We injected teprotide in order to test the role of angiotensin in the regulation of peripheral vascular tone, and found a much greater decrease of blood pressure and peripheral vascular resistance than caused by the vasopressin antagonist. These experiments suggest that vasopressin and the renin system increase peripheral vascular tone in certain models of heart failure, and demonstrate a much greater importance for the renin system.
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PMID:Role of vasopressin in experimental heart failure. 304 96

The renin-angiotensin system is activated in heart failure in proportion to the severity of the haemodynamic derangement and to diuretic dose. Angiotensin converting enzyme (ACE) inhibitors reduce circulating levels of angiotensin II and aldosterone and, in some patients, plasma noradrenaline, vasopressin and cortisol. Typically there is potassium retention and a minor increase in plasma potassium, but cumulative sodium balance may increase or decrease depending on pretreatment fluid and haemodynamic status and on policy regarding diuretic dose. Circulatory dynamics usually improve and blood flow to the brain, myocardium and kidneys is preserved. Changes in glomerular filtration rate are dictated by haemodynamic characteristics and, again, by diuretic dose and dietary sodium. There are potential hazards with ACE inhibitor therapy but most problems can be anticipated and avoided. Future trends may include the introduction of ACE inhibitors with or without concomitant diuretic therapy in early cardiac failure, and intravenous ACE inhibition immediately after acute myocardial infartion. Whether the ACE inhibitors will prove more successful than alternative antihypertensive agents in preventing cardiac complications (including heart failure) of hypertension, is an intriguing question.
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PMID:Converting enzyme inhibitors in heart failure. 304 97

There are two sets of compensatory mechanisms activated when the heart fails: cardiac mechanisms that try to maintain a normal cardiac output and peripheral circulatory mechanisms that try to maintain blood pressure to perfuse the heart and the brain. The latter are most important during the stress of exercise. During exercise, two patterns of responses are noted: 1) blood vessels supplying active skeletal muscle fail to dilate normally, and 2) blood vessels supplying other visceral organs constrict excessively. The inability of skeletal muscle resistance vessels to dilate normally to a metabolic stimulus is related to sodium and water accumulation in the vessels and to a deconditioning response. These effects probably are at the small artery level. This results in an abnormal metabolic response to exercise. Vasoconstriction in visceral organs is related to neurogenic (sympathetic adrenergic) and humoral (angiotensin, norepinephrine, and vasopressin) mechanisms. The peripheral sympathetic nervous system is the primary determinant of the high plasma norepinephrine levels seen in heart failure. The role of the sympathetic nervous system is to provide for acute vasoconstriction and the renin-angiotensin system is to provide for chronic visceral vasoconstriction. These circulatory mechanisms operate most effectively over different time frames that are either short (sympathetic nervous system), intermediate (renin-angiotensin system), or long (deconditioning, vascular stiffness). When treatment is successful these systems return to normal over similar time frames.
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PMID:The peripheral distribution of cardiac output in heart failure. 306 42

Congestive heart failure is a very complex clinical syndrome characterized by a number of important extracardiac features. In an attempt to maintain circulatory homeostasis, there is activation of a number of vasopressor/Na+ retentive forces. Plasma levels of angiotensin, norepinephrine and vasopressin rise, likely contributing to heightened peripheral resistance and antidiuresis. These forces appear to be offset to some extent by vasodilator/Na+ excretion activity in the form of increased prostaglandins, atrial natriuretic factor, and dopamine. There is a complex interplay between these neurohumoral systems in heart failure which is just beginning to be understood.
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PMID:Extracardiac features of heart failure: catecholamines and hormonal changes. 306 12

Angiotensin II (AII), aldosterone (Aldo) and arginine vasopressin (AVP) in plasma were determined during basal conditions in seventeen patients with congestive heart failure and in seventeen control subjects. The same parameters were measured before and 1, 2 and 3 h after an oral water load of 20 ml (kg body weight)-1 together with urine volume (V) and free water clearance (CH2O) in seven patients with congestive heart failure and in seven control subjects. AII, Aldo and AVP were significantly higher in heart failure than in control subjects (AII:81 and 12 pmol l(-1) (medians), P less than 0.01; Aldo: 411 and 103 pmol l(-1), P less than 0.01; AVP: 5.3 and 2.0 pmol l)-1), P less than 0.01). AVP was positively correlated to Aldo in both heart failure (p = 0.593, n = 17, P less than 0.02) and control subjects (p = 0.511, n = 17, P less than 0.05), but in neither of the groups to AII. V and CH2O were significantly lower in heart failure when compared to control subjects (maximum increase in CH2O 3.55 and 5.86 ml min-1, P less than 0.02), but did not correlate directly with either A II, Aldo or AVP. Creatinine clearance was reduced in heart failure. It is concluded that the activity of both the renin-angiotensin-aldosterone system and the osmoregulatory system is enhanced in congestive heart failure, presumably as a compensatory phenomenon in order to maintain arterial blood pressure. It is suggested that the decrease in free water clearance may be attributed to both an elevated level of vasopressin and a reduced glomerular filtration rate.
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PMID:Angiotensin II, aldosterone and arginine vasopressin in plasma in congestive heart failure. 308 74

The pathogenesis of hyponatremia remains debated; therefore, we determined the roles of plasma vasopressin, fluid intake and renal free water excretion in hyponatremic medical patients. We evaluated 100 consecutive hypo-osmolar hyponatremic patients (PNa = 127 +/- 0.7 mM l-1) in a prospective manner. We observed: hyponatremia was often found in association with advanced congestive cardiac failure (twenty-five of 100 patients), liver cirrhosis (16%) and primary volume contraction (29%). There was a 17% in-hospital mortality of hyponatremic patients. This was primarily related to the severity of underlying illnesses rather than to hyponatremia per se. The most consistently observed laboratory finding of hyponatremia was non-osmotic vasopressin stimulation; mean observed PADH was 4.7 +/- 0.7 pg ml-1 and vasopressin was detectable by radioimmunoassay (RIA) in 91% of all patients. In addition to vasopressin stimulation we also found evidence of advanced 'circulatory underfilling' in most hyponatremic patients. Mean urinary osmolality was hypertonic to plasma (441 +/- 17.4 m0sm kg H2O-1). This applied to patients with hyponatremic cardiac failure, liver cirrhosis and volume contraction. Almost all of these patients received high ceiling diuretics. (v) Spontaneous mean daily fluid intake was 2.4 +/- 0.2 l. In summary, our findings suggest that disturbances of vasopressin, fluid intake and renal free water excretion co-operate in the pathogenesis of hyponatremia. In clinical states of advanced circulatory underfilling the occurrence of hyponatremia indicates a poor prognosis of the patient.
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PMID:Pathogenesis of clinical hyponatremia: observations of vasopressin and fluid intake in 100 hyponatremic medical patients. 310 2

Arginine vasopressin is elevated in congestive heart failure. To determine the effect of arginine vasopressin upon systemic hemodynamics and regional blood flows, we administered the specific inhibitor of the vascular action of vasopressin [1-(beta-mercapto-beta,beta-cyclopentamethylenepropionic acid),2-(O-methyl)-tyrosine]-arginine vasopressin [d(CH2)5Tyr(Me)AVP] to 15 dogs with chronic right-heart failure produced by tricuspid avulsion and progressive pulmonary artery constriction. The animals exhibited increased plasma arginine vasopressin and norepinephrine levels. Vasopressin inhibition increased cardiac output and left ventricular dP/dt and dP/dt/P, and it decreased total peripheral vascular resistance, whereas mean aortic pressure did not change significantly. Simultaneously, blood flow increased to skeletal muscle, kidneys, skin, and right and left ventricular myocardium. Plasma catecholamines also increased. Pretreatment with propranolol and prazosin abolished the increases in cardiac output and left ventricular function produced by vasopressin inhibition. Pretreatment also led to a decrease in mean aortic pressure after vasopressor inhibition. In contrast, administration of d(CH)2)5Tyr(Me)AVP to 11 sham-operated animals or administration of normal saline to nine sham-operated and eight heart-failure dogs was without effect either in the absence or in the presence of adrenergic receptor blockade. Thus, arginine vasopressin participates in the control of the circulation in right-sided congestive heart failure, with both a direct constrictor action on blood vessels and an indirect action by inhibition of the sympathetic nervous system.
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PMID:Short-term hemodynamic effects of vasopressin V1-receptor inhibition in chronic right-sided congestive heart failure. 318 Mar 81

Congestive heart failure is a complex clinical syndrome characterized by a number of neuroendocrine responses. These responses are probably an evolutionary vestige of mechanisms designed to defend volume and maintain circulatory homeostasis. Activation of the sympathetic nervous system and renin-angiotensin-aldosterone system and the release of vasopressin have been clearly documented in patients with heart failure. Unlike the normal ventricle, the failing ventricle responds to peripheral vasoconstriction and sodium retention with further hemodynamic embarrassment and circulatory congestion. Certain vasorelaxant natriuretic substances are also released during heart failure, perhaps in an attempt to offset excessive peripheral constriction and sodium retention. Prostaglandin E2, atrial natriuretic peptide (or atrial natriuretic factor) and plasma dopamine are found to be increased in some patients with heart failure. However, peripheral constriction and sodium retention appear to be dominant, particularly in the advanced stages of heart failure. An understanding of these neuroendocrine responses has led to new developments in therapy. Angiotensin-converting enzyme inhibitors have emerged as distinctly useful drugs in the treatment of heart failure. Agents designed to block excessive sympathetic drive and inhibit vasopressin are under investigation. Infusion of atrial natriuretic factors and the use of selective dopamine agonists are also undergoing clinical trials in patients with heart failure. Increased knowledge of the neuroendocrine responses will likely result in even newer and more imaginative therapy.
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PMID:Neuroendocrine manifestations of congestive heart failure. 329 96


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