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

A 24-year-old woman was admitted to our hospital with acute paracetamol poisoning, and severe hepatic injury. The peak blood level of GOT, GPT and LDH were 32,600 U, 119,200 U and 36,500 U respectively. Glucagon-insulin and glutathione were administered to save the liver function. On the third hospital day, hemodialysis was administered to treat acute renal failure. On the 16th hospital day, when the liver and renal functions recovered, severe pulmonary congestion occurred and right heart catheterization revealed high pulmonary pressure. Echocardiography showed left ventricular enlargement accompanied by a severe diffuse impairment of left ventricular wall motion. Multi-focal ventricular arrhythmia was frequent during this period. Hemodialysis and artificial respiration were carried out for the treatment of heart failure. Three months after admission, myocardial perfusion scintigram showed patchy reduction in the uptake of Tl-201 throughout the myocardium, and left ventriculography showed mild diffuse impairment of the LV wall motion (ejection fraction: 49%). In this case, acute heart failure appeared approximately 2 weeks after the severe hepatic injury. Apparently myocardial damage following paracetamol overdosage is caused not only by direct toxicity but by severe metabolic derangement.
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PMID:A case of myocardial damage following acute paracetamol poisoning. 252 40

The central and peripheral vascular haemodynamic effects of glucagon were studied in 29 patients. With a single dose method of 2 or 5 mg. glucagon intravenously the inotropic action of the drug produced immediate increased myocardial contractility with significant increase in cardiac output and enhanced cardiac performance, and lowering of pulmonary arterial pressure and pulmonary vascular resistance. No primary peripheral vascular effect was evident, and the increased systemic pressure and lowered systemic resistance appear to be secondary to the central action of the drug. With the dosage used there were no undesirable side-effects apart from a feeling of slight nausea. Though the haemodynamic effects are abrupt, reaching their maximum values in the first 10 minutes after injection, they tend to be dissipated within half an hour, presumably due to the very rapid destruction of the drug. Repeated booster doses rather than continuous infusion may be the method of choice to maintain an increased cardiac output. The positive chronotropic action of the drug may cause transient palpitations. Glucagon increased the cardiac output in the acute phase of myocardial infarction by 42 per cent. The haemodynamic effects in chronic rheumatic heart disease are more varied, and it may increase left atrial pressure in mitral stenosis, which is undesirable. Hyperglycaemia results from liver glycogenolysis but blood sugar levels rarely exceeded 200 mg./100 ml. These results warrant further study of the value of glucagon as a positive inotropic agent in low output heart failure, especially in acute myocardial infarction with cardiogenic shock, or after cardiac surgery, or in unrelieved chronic congestive heart failure.
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PMID:Haemodynamic effects of glucagon. 542 74

Although glucagon exerts positive inotropic effects in patients with no or mild impairment of cardiac function, similar effects are not consistently observed in patients with chronic heart failure. Accordingly, the inotropic effects of glucagon on papillary muscles from normal cats and cats in which right ventricular failure had been produced for 4-145 days by pulmonary artery banding were compared. At the peak of the concentration-response curve, glucagon increased peak isometric tension (T) in normal muscles from 4.4+/-0.4 to 6.6+/-0.5 g/mm(2) (P <0.001), and maximum rate of tension development (dT/dt) from 16.9+/-0.9 to 25.1+/-1.6 g/sec per mm(2) (P < 0.001). In contrast, glucagon produced no significant increases in T or dT/dt in failure muscles. The percentage increases in T and dT/dt caused by norepinephrine were the same in muscles from normal and failing hearts. Since the cardiac effects of glucagon and norepinephrine may be mediated by adenyl cyclase, responsiveness of adenyl cyclase was determined in particulate fractions of the right ventricle. Glucagon activated adenyl cyclase in normal, but had no effect in failure preparations. Norepinephrine-induced activation of adenyl cyclase, however, was unaltered by failure. Thus, in contrast to norepinephrine, glucagon loses the capacity to augment myocardial contractility and activate adenyl cyclase in hearts derived from cats in chronic failure.
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PMID:Effects of experimental heart failure on the capacity of glucagon to augment myocardial contractility and activate adenyl cyclase. 544 51

Two cases of severe beta-blocker overdose are presented that were treated successfully with glucagon therapy. The effects of glucagon in reversing the cardiovascular depression of profound beta-blockade, including its mechanism of action, onset and duration of action, dosage and administration, cost and availability, and side effects are reviewed. Medical complications of beta-blocker overdose include hypotension, bradycardia, heart failure, impaired atrioventricular conduction, bronchospasm and, occasionally, seizures. Atropine and isoproterenol have been inconsistent in reversing the bradycardia and hypotension of beta-blocker overdose. Glucagon increases heart rate and myocardial contractility, and improves atrioventricular conduction. These effects are unchanged by the presence of beta-receptor blocking drugs. This suggests that glucagon's mechanism of action may bypass the beta-adrenergic receptor site. Because it may bypass the beta-receptor site, glucagon can be considered as an alternative therapy for profound beta-blocker intoxications. The doses of glucagon required to reverse severe beta-blockade are 50 micrograms/kg iv loading dose, followed by a continuous infusion of 1-15 mg/h, titrated to patient response. Glucagon-treated patients should be monitored for side effects of nausea, vomiting, hypokalemia, and hyperglycemia. The high cost and limited availability of glucagon may be the only factors precluding its future clinical acceptance.
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PMID:Glucagon therapy for beta-blocker overdose. 614 98

Glucagon is an important therapeutic agent in critical care medicine. Although its endogenous hormonal functions have been well described, its clinical uses are rarely discussed. Glucagon is effective in the treatment of hypoglycemia, cardiogenic shock and heart failure, propranolol overdose, esophageal meat impaction, ureteral colic due to calculi, and acute diverticulitis. It may prove useful in the treatment of endotoxin and hypovolemic shock as well as toxicity due to excesses of procainamide, quinidine, or ouabain.
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PMID:Glucagon: hormone or therapeutic agent? 637 66

Digitalis causes vasoconstriction of peripheral vasculature and has been shown to markedly decrease splanchnic blood flow in experimental animals in doses that are comparable to therapeutic doses in man. The effect of digitalis on splanchnic blood flow in heart failure in experimental animals and in man has been controversial. We found that i.v. ouabin reduced ESBF by 30% to 40% (p less than 0.001) in normal volunteer human subjects, that i.v. digoxin reduced ESBF by 15% to 25% (p less than 0.01) in normal subjects, and that oral digoxin had no discernible effect on ESBF in normal subjects. The difference between the effects of i.v. and oral administration appeared to be due to differences in peak blood levels, which were almost 10 times higher after i.v. administration. Glucagon prevented the effect of i.v. digoxin on ESBF in normal subjects. For patients in heart failure, the effect of i.v. digoxin on ESBF was variable: some patients had decreased ESBF but two had increased ESBF that seemed to be associated with a greater increase in cardiac output.
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PMID:Effect of digitalis on estimated splanchnic blood flow. 705 51

Glucagon has been reported to be one of the most effective treatments for severe beta-blocker poisoning. Recently, amrinone was suggested as an alternative therapeutic choice for beta-blocker poisoning. Milrinone, a derivative of amrinone, acts independently of beta-adrenoceptors and increases cyclic AMP. Therefore milrinone may also be effective in the treatment of beta-blocker poisoning. In the present study, we compared the effect of glucagon and milrinone in treating severe beta-blocker poisoning. Following the administration of 10 mg/kg propranolol i.v. over 10 min, heart rate, cardiac output, mean arterial pressure, stroke volume, and end tidal CO2 were depressed, while central venous pressure, and pulmonary capillary wedge pressure increased significantly (p < 0.05). Following the administration of saline (Group S, N = 3), glucagon 20 micrograms/kg (Group G, N = 5), and milrinone 300 micrograms/kg (Group M, N = 5), hemodynamic parameters were observed for 30 min. In group M, mean arterial pressure, cardiac output and stroke volume recovered to their baseline values, while central venous pressure and pulmonary capillary wedge pressure decreased. Although there were no significant differences between groups G and M, the heart rate, central venous pressure and pulmonary capillary wedge pressure, mean arterial pressure and stroke volume did not return to baseline values in group G. Milrinone administration produced a significant hemodynamic improvement without increasing the heart rate in the canine model of severe heart failure caused by propranolol. In the glucagon treatment group, central venous pressure and pulmonary capillary wedge pressure improved less than the milrinone group. Although more data are needed before a clinical recommendation, milrinone might be an effective drug to treat beta-blocker poisoning.
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PMID:Milrinone versus glucagon: comparative hemodynamic effects in canine propranolol poisoning. 800 35

Glucagon is a counter-regulatory hormone that is classically used to treat hypoglycemia. However, it can elicit the generation of cAMP within the myocardium to cause positive inotropic and chronotropic effects without the need for beta-1 adrenoceptor stimulation. Glucagon has been used extensively to treat beta-blocker overdose and has evidence for use in verapamil and imipramine overdose as well. Glucagon has been used as adjunctive therapy in shock situations and heart failure but is inferior to catecholamines. An interesting potential indication for glucagon is in treating postcountershock asystole.
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PMID:A review of potential cardiovascular uses of intravenous glucagon administration. 1023 90

Endothelial dysfunction is a major characteristic of the atherosclerotic process and can be used to predict the outcome of cardiovascular disease in humans. Together with obesity and insulin resistance, such dysfunction is common among patients with type 2 diabetes and may explain their poor prognosis in connection with such a disease. Insulin resistance in skeletal muscle, adipose tissue, and the liver, a well-characterized feature of obesity and type 2 diabetes, contributes to the impairment of glucose homeostasis. Furthermore, the myocardial muscle can also be resistant to insulin, which might, at least in part, explain the frequent development of heart failure in individuals suffering from type 2 diabetes. The relationship between insulin resistance and endothelial dysfunction has prompted investigations, which reveal that regular exercise, dietary changes, and/or pharmacological agents can both increase insulin sensitivity and improve endothelial function. Glucagon-like peptide-1, an incretin, lowers blood levels of glucose and offers a promising new approach to the treatment of type 2 diabetes mellitus. Its extensive extra-pancreatic effects, including a favorable influence on cardiovascular parameters, are extremely interesting in this connection. The potential pharmacological effects of glucagon-like peptide-1 and its analogues on the endothelium and the heart are discussed in the present review.
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PMID:The potential beneficial role of glucagon-like peptide-1 in endothelial dysfunction and heart failure associated with insulin resistance. 1879 70

Glucagon-like peptide-1 (GLP-1) is an incretin secreted in response to nutrient ingestion. Understanding the incretin effect on diabetes pathophysiology has led to development of a new class of agents termed incretin mimetics. Exenatide is the first GLP-1 agonist approved to treat type 2 diabetes mellitus (T2DM). Clinical studies have demonstrated exenatide's efficacy in improving glycemic control, often coupled with weight loss. Studies are investigating the potential cardiovascular benefits of GLP-1 agonists. Blood pressure, cholesterol levels, C-reactive protein, and insulin resistance may improve in patients treated with exenatide. The direct effect of GLP-1 on cardiac myocytes and vascular smooth muscle has been an active area of investigation. Infusions of GLP-1 in animal models and human subjects with heart failure have demonstrated significantly improved cardia parameters. In patients with T2DM, GLP-1 infusion has been shown to improve endothelial function, irrespective of changes in insulin sensitivity. These pilot studies provide a foundation for developing therapies aimed at modulating incretin physiology for the additional benefit on the cardiovascular system in patients with T2DM and heart disease.
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PMID:The role of incretins in cardiovascular control. 1914 96


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