Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01185 (vasopressin)
23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Experimental myocardial infarction is a model of cardiac overload due to amputation of part of the cardiac muscle. The development of cardiac failure depends on the size of the infarct and the time factor. This model of overload is associated with changes of the phenotype of the remaining healthy muscle and with peripheral vascular modifications partially dependent of the activation of pressor and/or deactivation of dilator systems. These changes are proportional to the size of the infarction at a given time after induction of the model. The degree of right ventricular hypertrophy and the decrease in blood pressure reflect the severity of infarction and the deterioration of the remaining myocardial function, affecting the haemodynamics both before and after the left ventricle. The increases in the 1/3 forms of isomyosins, the amount of subendocardial collagen, the biosynthesis, stocking and secretion of ANF are related to the infarct size and degree of overload. Similarly, the concentration of cyclic GMP is proportional to the infarct size. These parameters reflect ventricular overload, the increase of stress and energy deprivation of the remaining healthy muscle. The activation of peripheral pressor systems is also dependent on the infarct size reflects the effect of cardiac pump dysfunction on the kidney, liver, brain and endothelium. Large infarcts are associated with increased circulating renin and renal concentrations, with a decrease in angiotensinogen levels related to its consumption by the renin and to reduced hepatic synthesis and also with increased secretion and biosynthesis of vasopressin by the hypothalamus. In this model, Perindopril is beneficial by decreasing the cardiac load. It reduces the blood pressure, causes regression of bi-auricular and right ventricular hypertrophy. Changes in myosin isoenzyme configuration regress and subendocardial fibrosis and ANF concentrations are normalised. The effects of ACE inhibitors in this context, though very beneficial, are limited by the impossibility of normalising cardiac load and stress when the initial amputation of cardiac contractile mass exceeds 40%.
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PMID:[Experimental myocardial infarction in the rat. Effect of perindopril]. 166 27

In this article, we review briefly the available theories and data on [Ca2+]i-waves and [Ca2+]i-oscillations in mammalian cardiac and vascular smooth muscles. In addition to our review, we also report: (i) the existence and characterization of rapid agonist-induced [Ca2+]i-waves in cultured vascular smooth muscle cells (A7r5 cells); and (ii a new method for studying rapid [Ca2+]i-waves in mammalian cardiac ventricular cells. In mammalian cardiac muscle several types of Ca(2+)-release from sarcoplasmic reticulum (SR) are known to occur and might be involved in Ca(2+)-waves and Ca(2+)-oscillations: (a) Ca(2+)-induced release of Ca2+, of the type thought to be important in normal excitation-contraction coupling; (b) spontaneous, cyclic release of Ca2+ related to a Ca(2+)-overload of the SR; and (c) Ins(1,4,5)P3-induced Ca(2+)-release. The available data support the idea that [Ca2+]i-waves in heart propagate by a mechanism somewhat different than that involved in normal excitation-contraction coupling (a, above), perhaps involving spontaneous release of Ca2+ from an overloaded SR (b, above). In mammalian vascular smooth muscle, our data support the idea that agonist-receptor interaction (vasopressin, in this case) initiates [Ca2+]i-waves that then propagate via some form of Ca(2+)-induced release of Ca2+, perhaps in a manner similar to that proposed by Berridge and Irvine [1].
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PMID:Ca(2+)-oscillations and Ca(2+)-waves in mammalian cardiac and vascular smooth muscle cells. 205 96

Ventricular dysfunction due to an abnormality of the heart which is associated with typical hemodynamic, renal and hormonal reactions, characterizes the clinical syndrome heart failure. The traditional definition of heart failure as the inability to pump an amount of blood sufficient to cover the metabolic needs of the body in the presence of adequate venous return, emphasizes mainly the reduction in cardiac output but not the increase in intracardiac pressures. Pressure or volume overload, decreased contractility, loss of muscle mass or restricted filling represent the most important pathological processes leading to heart failure. The disturbance of systolic ventricular function due to pressure or volume overload or diminished contractility is characterized by a decrease in the ejection fraction, the disturbance in diastolic ventricular function associated with restricted filling is characterized by elevated chamber stiffness. Decreased contractility is most commonly responsible for the development of heart failure. Impairment of diastolic ventricular function can only be regarded as the dominant mechanism leading to heart failure in the presence of a small noncompliant ventricle. Impairment of diastolic ventricular function in an enlarged heart is always associated with an impairment of systolic ventricular function and is, then, relegated to a subordinate role. Common causes of heart failure are coronary artery disease, hypertension, cardiomyopathies, valvular heart diseases and congenital heart diseases, for the incidence of which coronary artery disease is most frequently responsible. Most of these diseases lead to heart failure not via a single, but rather several of the specified pathophysiological processes. Possible mechanisms for loss of contractility include structural changes as well as alterations in excitation-contraction coupling. Possible mechanisms responsible for impaired diastolic ventricular function encompass, in addition to altered calcium flux, structural changes such as fibrosis and hypertrophy and factors such as asynchrony and abnormal loading conditions. With increasing derangement of cardiac function, there is recruitment of the compensatory mechanisms: hypertrophy of the cardiac muscle, Frank-Starling mechanism, activation of the sympathetic nervous system, the renin-angiotensin-aldosterone system and the arginine-vasopressin system. The goal is maintenance of adequate blood pressure and cardiac output whereby blood flow is redistributed in favor of the heart and brain and away from the skin, musculature and visceral organs. Activation of the neurohumoral system can lead to excessive vasoconstriction as well as sodium and water retention resulting in an undesired elevation of preload and afterload which, in turn, leads to further worsening of the heart failure.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[Pathophysiologic and diagnostic aspects of heart failure]. 219 15

Rats were exposed to osmotic stress either acutely, over periods of 1 or 4 h, or chronically, over several days. In acute experiments, hyposmolality was induced by intraperitoneal infusion of dilute glucose or mannitol solutions, whereas hyperosmolality was induced by use of sodium chloride, concentrated glucose or mannitol solutions, or urea. Chronic hypernatremia was induced by daily administration of sodium chloride to water-deprived animals; chronic hyponatremia was induced by daily injection of antidiuretic hormone supplemented with glucose. Animals were made hyperglycemic using streptozotocin or uremic by ureteral ligation. Where appropriate, animals were anesthetized with thiobutabarbital (Inaktin) or ether. In acute experiments, analysis of the composition of the cardiac ventricle, diaphragm, liver, and renal cortex showed no evidence of cell volume regulatory processes involving transmembrane movement of potassium ions. There was a small but significant increase in free amino acids [measured as ninhydrin-positive substance (NPS)] in cardiac muscle exposed to hypertonic solutions of sodium chloride and glucose but not when plasma osmolality was raised using mannitol. In cerebral cortical tissue, after 4 h of exposure to acute hypertonicity by infusion of sodium chloride or glucose, there was a significant increase in tissue potassium content and a slight increase in NPS content. In chronic experiments, tissue analysis revealed good evidence for cellular volume readjustment only in cerebral cortex and heart. In the cortex, levels of free amino acids, principally taurine and glutamate (plus glutamine), showed large increases during hypernatremia and hyperglycemia and corresponding decreases during hyposmolality. In heart the principal amino acid present was taurine, and it, together with aspartate and glutamate (plus glutamine), showed large changes under osmotic stress. Other tissues analyzed showed only small changes in composition.
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PMID:Response of tissues of the rat to anisosmolality in vivo. 832 70

Experimental myocardial infarction is a model of cardiac overload in which part of the cardiac muscle is removed. The resulting left ventricle insufficiency depends on the size of the infarct and time. The infarcted area remodels, due to proteolytic activity of inflammatory cells and collagenogenesis from fibroblast activity. The phenotype of the residual healthy cardiac muscle undergoes modification, and there are peripheral vascular changes which are partly dependent on the activation of pressor systems and/or inactivation of dilator systems. The changes are proportional to the infarct size at any given time after induction of the model. The degree of right ventricular hypertrophy and the drop in arterial pressure are upstream and downstream markers of the loss of left ventricular function and therefore indicate the extent of the remodelling. The increase of type V3isomyosin, the amount of subendocardial collagen, and the biosynthesis, storage and secretion of atrial natriuretic factor (ANF) are all proportional to the infarct size and the degree of cardiac overload. The level of urinary cGMP is also correlated with infarct size. These indices show ventricular remodelling, increased stress and energy restriction of the residual healthy cardiac muscle. The activation of peripheral pressor systems also depends on infarct size. They reflect the influence of defective cardiac pumping on the kidney, liver, brain and endothelium. Massive infarcts are accompanied by an increase in circulating renin and in renal renin content, by a decrease in angiotensinogen due to its consumption by renin, and to its insufficient hepatic synthesis, and by an increase in vasopressin secretion and biosynthesis in the hypothalamus. Converting enzyme inhibition has beneficial effect in this model by lowering cardiac load. It reduces arterial pressure, reverses bi-atrial and right ventricular hypertrophy, reduces the changes in the myosin isoenzyme patterns, and normalizes subendocardial fibrosis and the level of ANF. Although the effects of converting enzyme inhibition are beneficial in this model, they are restricted by their inability to normalize the load and stress when the initial loss of cardiac contractile material exceeds 40%.
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PMID:Left ventricular remodelling following experimental myocardial infarction. 882 57

Angiotensin II receptor antagonists (AT-1) represent a new group of orally active antihypertensive agents. Activation on AT-1 receptor leads to vasoconstriction, stimulation of the release of catecholamines and antidiuretic hormone with production of thirst, and promote growth of vascular and cardiac muscle; these effects are blocked by AT-1 antagonist agents. The first chemically useful, orally active AT-1 receptor antagonist was losartan, followed by other agents currently in clinical use, such as: valsartan, eprosartan, irbesartan, telmisartan, candesartan, and many others under investigation. AT-1 receptor antagonists are effective in reducing high blood pressure in hypertensive patients. Monotherapy in mild to moderate hypertension controls blood pressure in 40 to 50% of these patients; when a low dose of a thiazide diuretic is added, 60 to 70% of patients are controlled. The efficacy is similar to angiotensin-converting enzyme inhibitors, diuretics, calcium antagonists and beta-blocking agents. Tolerability has been reported to be very good. AT-1 receptor antagonists would be a drug of choice in otherwise well-controlled hypertensive patients treated with angiotensin-converting enzyme inhibitors who developed cough or angioedema. The final position in the antihypertensive therapy in this special population and other clinical situations, such as left ventricular hypertrophy, heart failure, diabetes mellitus and renal disease, has to be determined in large prospective clinical trials, some of which are now being conducted.
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PMID:Angiotensin II receptor antagonists in arterial hypertension. 1085 84

Congestive heart failure is a complex disease that results from pumping failure of the cardiac muscle and adaptational processes of the cardiovascular system to correct for the reduced blood supply to the organism. It is associated with increased vasoconstriction and impaired vasodilation in response to physical activity. The elevated vasoconstrictor tone is caused by the activation of compensatory mechanisms including the sympathetic nervous system and stimulation of the release of neurohormones like angiotensin II, catecholamines, and vasopressin. Furthermore, the vascular endothelium is importantly involved in the regulation of vascular tone as it releases a variety of vasoactive substances that act locally and systemically. In congestive heart failure, there is a marked imbalance between the diminished release or the increased inactivation of vasodilators on the one hand, ie, nitric oxide, and the elevated production, release, or reduced inactivation of vasoconstrictors such as endothelin-1 on the other hand. In addition to its very potent vasoconstrictor effects, endothelin-1 possesses antinatriuretic and mitogenic properties that are a common feature of substances that are involved in development of the deleterious consequences that render congestive heart failure a lethal disease. The spectrum of action of the endothelin system and the advent of specific antagonists for its receptors have made this system a very interesting target for clinical research and possibly for future therapeutic approaches.
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PMID:Endothelin in heart failure. 1098 Oct 44

Angiotensin II receptor blockers represent a class of effective and well tolerated orally active antihypertensive drugs. Activation of AT(1) receptors leads to vasoconstriction, stimulation of the release of catecholamines and antidiuretic hormone and promote growth of vascular and cardiac muscle. AT(1) receptor blockers antagonise all those effects. Losartan was the first drug of this class marketed, shortly followed by valsartan, irbesartan, telmisartan, candesartan, eprosartan and others on current investigation. All these drugs have the common properties of blockading the AT(1) receptor thereby relaxing vascular smooth muscle, increase salt excretion, decrease cellular hypertrophy and induce antihypertensive effect without modifying heart rate or cardiac output. Most of the AT(1) receptor blockers in use controlled blood pressure during the 24 h with a once-daily dose, without evidence of producing tolerance to the antihypertensive effect and being with low incidence of side effects even at long term use. Monotherapy in mild-to-moderate hypertension controls blood pressure in 40 to 50% of these patients; when a low dose of thiazide diuretic is added, 60-70% of patients are controlled. The efficacy is similar to angiotensin-converting enzyme (ACE) inhibitors, diuretics, calcium antagonists and beta-blocking agents. AT(1) receptor blockers are specially indicated in patients with hypertension who are being treated with ACE inhibitors and developed side effects such as, cough or angioedema. The final position in the antihypertensive therapy in this special population and other clinical situations, such as left ventricular hypertrophy, heart failure, diabetes mellitus and renal disease, has to be determined in large prospective clinical trials, some of which are now being conducted and seem promising.
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PMID:Angiotensin II receptor antagonists role in arterial hypertension. 1198 4

The objective of this investigation was to use semi-quantitative immunohistochemistry to determine the distribution and expression levels of AQP2 and AQP3 proteins in normal human Tissue MicroArrays. Expression of the vasopressin regulated AQP2 was observed in a limited number of tissues. AQP2 was prominent in the apical and subapical plasma membranes of cortical and medullary renal collecting ducts. Surprisingly, weak AQP2 immunoreactivity was also noted in pancreatic islets, fallopian tubes and peripheral nerves. AQP2 was also localized to selected parts of the central nervous system (ependymal cell layer, subcortical white matter, hippocampus, spinal cord) and selected cells in the gastrointestinal system (antral and oxyntic gastric mucosa, small intestine and colon). These findings corroborate the restricted tissue distribution of AQP2. AQP3 was strongly expressed in many of the human tissues examined particularly in basolateral membranes of the distal nephron (medullary collecting ducts), distal colon, upper airway epithelia, transitional epithelium of the urinary bladder, tracheal, bronchial and nasopharyngeal epithelium, stratified squamous epithelial cells of the esophagus, and anus. AQP3 was moderately expressed in basolateral membranes of prostatic tubuloalveolar epithelium, pancreatic ducts, uterine endometrium, choroid plexus, articular chondrocytes, subchondral osteoblasts and synovium. Low AQP3 levels were also detected in skeletal muscle, cardiac muscle, gastric pits, seminiferous tubules, lymphoid vessels, salivary and endocrine glands, amniotic membranes, placenta and ovary. The abundance of basolateral AQP3 in epithelial tissues and its expression in many non-epithelial cells suggests that this aquaglyceroporin is a major participant in barrier hydration and water and osmolyte homeostasis in the human body.
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PMID:Distribution of AQP2 and AQP3 water channels in human tissue microarrays. 1570 94

Chronic heart failure (CHF) is a leading cause of hospitalization and is associated with a poor prognosis, although in the past decade substantial progress has been made in understanding the pathophysiology and therapy of CHF with reduced left ventricular (LV) ejection fraction. Use of angiotensin-converting-enzyme inhibitors and angiotensin-receptor antagonists either individually or in combination, certain beta-receptor blockers, and judicious use of aldosterone antagonists, has reduced hospital admission rates and mortality from CHF with reduced LV ejection fraction. More clinical trials are needed, however, particularly in patients with CHF and preserved LV ejection fraction. In patients who remain symptomatic despite medical therapy, and who have long QRS intervals (>0.12 s) and markedly reduced LV ejection fraction, the value of cardiac resynchronization therapy with a biventricular pacemaker has now been demonstrated. Yet, morbidity and mortality remain high, indicating a major need for further improvement. Novel therapies include medical management with statins, vasopressin antagonists, erythropoietin, oxypurinol and levosimendan, which improve vascular and myocardial function and reduce fluid overload, in addition to surgical approaches, which reduce LV remodeling. These routes might not, however, suffice in patients with CHF and LV dysfunction. Prevention of apoptosis and particularly regeneration of cardiac muscle would represent a shift of the current paradigm. Stem-cell-based therapies are rapidly evolving, and while basic science is needed to optimize these strategies, medium-sized clinical studies could help to verify the beneficial effects on LV function. In this review, we discuss current treatment methods and new strategies to improve treatment of CHF.
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PMID:Chronic heart failure: an overview of conventional treatment versus novel approaches. 1630 19


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