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:C0011570 (depression)
172,036 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The association of verapamil with halothane causes ischaemic-like myocardial dysfunction. Using an isolated rat heart model perfused with a radiolabelled fatty acid (123I-labelled iodohexadecenoic acid) as a sensitive marker of ischaemia this study investigated whether or not this dysfunction is of ischaemic origin. Hearts were perfused with a control solution or with solutions containing either 1% of halothane or 150 ng ml-1 of verapamil or the association of 0.75% halothane + 120 ng ml-1 verapamil. The ischaemic group was perfused at a reduced perfusion rate (-50%). Intracellular fate of IHA was assessed, and its esterification ratio computed. Ischaemia and the drugs induced a similar depression of haemodynamics. The esterification ratio in the ischaemic group was significantly higher (0.723 +/- 0.04) than in controls (0.0526 +/- 0.03) and than in the treated groups: halothane (0.533 +/- 0.06), verapamil (0.411 +/- 0.027) or the association halothane+verapamil (0.408 +/- 0.05), suggesting a non-ischaemic origin for the dysfunction caused by halothane-verapamil.
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PMID:Comparative effects of halothane associated with verapamil and ischaemia on myocardial metabolism in isolated perfused rat hearts. 142 13

Obesity is a major risk factor for cardiovascular disease. However, a direct link between these two states is difficult to establish, since obesity frequently occurs with other disease states such as diabetes, hypertension and atherosclerosis. Clinical studies have clearly shown that uncorrected obesity is associated with cardiac hypertrophy and compromised ventricular function. A number of rodent models of obesity have been studied in terms of cardiovascular adaptations. Cardiac function of the obese Zucker rat appears to be normal at a younger age. Only after several months is depression in cardiac function discernable. These animals are mildly hypertensive, but do not exhibit the characteristic increase in cardiac output associated with human obesity. A unique characteristic of JCR:LA-cp rat is that they develop atherosclerotic and myocardial lesions. Hearts from these animals will maintain normal function when perfused with physiological levels of calcium. At higher calcium concentrations, however, mechanical function becomes impaired. Dietary-induced obese rats exhibit many of the hemodynamic alterations associated with human obesity, but there is no evidence to-date that these animals will develop severe cardiac depression. Short-term weight reduction apparently has beneficial cardiovascular effects, but weight cycling may be harmful. Given the widespread occurrence of obesity, further studies are warranted to characterize the cardiac manifestations of this condition.
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PMID:Cardiovascular abnormalities associated with human and rodent obesity. 143 63

The effect of dipyridamole (DYP) on postischemic myocardial function and metabolism was studied using the isolated rabbit heart model. Twenty-one isolated rabbit heart preparations were divided into two groups: KH (control N = 10) were reperfused after 24 min normothermic hyperkalemic arrest with modified Krebs-Henseleit buffer (KH) while DYP (N = 11) were reperfused with KH and 5 X 10(-6) M DYP. Hearts were analyzed for myocardial function (DP, developed pressure, +dp/dt, -dp/dt) and metabolic function (ATP, CrP, ADP, AMP, purines, and lactate levels). Data analysis revealed significant reperfusion depression in DYP myocardial function compared with KH (P less than 0.05): DP (42 +/- 6 vs 89 +/- 7 mm Hg), +dp/dt (390 +/- 21.6 vs 1227 +/- 48.4), and -dp/dt (280 +/- 20.1 vs 677 +/- 19.8). Comparison of DYP to KH metabolic parameters was also significantly different (P less than 0.05): ATP (5.8 +/- 0.7 vs 9.5 +/- 1.4), ADP (2.1 +/- 0.2 vs 3.2 +/- 0.6), CrP (9.6 +/- 0.3 vs 17.2 +/- 1.3). Tissue purines (adenosine and inosine) were significantly elevated (P less than 0.01) in the DYP group, while coronary sinus purines and lactate loss were similar. Thus, the data suggest that DYP, present during postischemic reperfusion, depresses myocardial function by inhibiting adenosine phosphorylation, thereby decreasing the generation of high-energy phosphates without increased substrate loss or ischemia.
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PMID:Metabolic and functional cardiac impairment after reperfusion with persantine. 186 75

Changes in myocardial antioxidants due to different durations of hypoxia at normal or lower temperatures were correlated with the recovery of structure and function on reoxygenation. Hearts perfused with substrate-free hypoxic buffer at 37 degrees C for 5 or 10 min and at 22 degrees C for 10 min showed a significant depression in the contractile function and rise in resting tension. Reoxygenation of these hearts at 37 degrees C for 20 min resulted in a recovery of these functions. On reoxygenation, hearts made hypoxic for 10 min at 37 degrees C showed poor recovery of the contractile function, increase in malondialdehyde content and a dramatic increase in the creatine phosphokinase activity in the coronary effluent. Addition of catalase to the perfusion medium markedly improved function recovery of these hearts. Hypoxia at 37 degrees C for 5 min or at 22 degrees C for 10 min with or without reoxygenation had no effect on superoxide dismutase (SOD) or glutathione peroxidase (GSHPx) activities. These antioxidants were depressed in hearts made hypoxic for 10 min at 37 degrees C with no further change on reoxygenation. Neither SOD nor GSHPx was detected in the coronary effluent during hypoxia or reoxygenation. Hypoxia at 37 or 22 degrees C for 10 min caused significant ultrastructural changes, and on reoxygenation 37 degrees C hypoxic hearts showed exacerbation, whereas the 22 degrees C hypoxic hearts showed recovery. These data support the hypothesis that reduced antioxidant reserve during hypoxia may contribute to the oxidative injury on reoxygenation, suggesting that maintenance of endogenous antioxidant levels during hypoxia may be important for recovery.
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PMID:Correlation between antioxidant changes during hypoxia and recovery on reoxygenation. 188 13

When cold storage techniques used in cardiac transplantation are extended beyond 3 hours, there is significant depression in ventricular function. This study was undertaken to determine whether the addition of the amino acid L-glutamate or the oxygen free-radical scavengers superoxide dismutase (SOD) and catalase (CAT) during extended periods of cold storage would improve ventricular function. Fifteen rabbit hearts were placed on a Langendorff apparatus, arrested with crystalloid potassium cardioplegia, stored in iced saline solution (3 degrees C) for 5 hours, and then reperfused at 37 degrees C for 1 hour. In five hearts L-glutamate (4 mmol/L) was added to the cardioplegic and reperfusate solutions, and five hearts received SOD (1500 units/kg/L) and CAT (3500 units/kg/L), whereas in five others the cardioplegic and reperfusate solutions were unmodified. Hearts treated with L-glutamate had the best recovery of positive dP/dt (79%* glutamate vs 49%* SOD and CAT vs 36% unmodified), negative dP/dt (76%* glutamate vs 53% SOD and CAT vs 45% unmodified), developed pressure (67%* glutamate vs 51% SOD and CAT vs 45% unmodified), and coronary flow (81%* glutamate vs 79%* SOD and CAT vs 62% unmodified). We conclude that substrate enhancement with L-glutamate provides superior myocardial protection than is possible with the oxygen free-radical scavengers SOD and CAT during extended periods of cold storage for cardiac transplantation.
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PMID:Superiority of substrate enhancement over oxygen free-radical scavengers during extended periods of cold storage for cardiac transplantation. 197 66

This study tests the hypothesis that multidose, hypocalcemic aspartate/glutamate-enriched blood cardioplegia provides safe and effective protection during prolonged aortic clamping of immature hearts. Of 17 puppies (6 to 8 weeks of age, 3 to 5 kg) placed on vented cardiopulmonary bypass, five were subjected to 60 minutes of 37 degrees C global ischemia without cardioplegic protection and seven underwent 120 minutes of aortic clamping with 4 degrees C multidose aspartate/glutamate-enriched blood cardioplegia ([Ca++] = 0.2 mmol/L), preceded and followed by 37 degrees C blood cardioplegic induction and reperfusion. Five puppies underwent blood cardioplegic perfusion for 10 minutes without intervening ischemia to assess the effect of the cardioplegic solution and the delivery techniques. Left ventricular performance was assessed 30 minutes after bypass was discontinued (Starling function curves). Hearts were studied for high-energy phosphates and tissue amino acids. One hour of normothermic ischemia resulted in profound functional depression, with peak stroke work index only 43% of control (0.7 +/- 0.1 versus 1.7 +/- 0.2 gm x m/kg, p less than 0.05). There was 70% depletion of adenosine triphosphate (7.6 +/- 1 versus control 20.3 +/- 1 mumol/gm dry weight, p less than 0.05) and 75% glutamate loss (6.6 +/- 1 versus control 26.4 +/- 3 mumol/gm, p less than 0.05). In contrast, after 2 hours of aortic clamping with multidose blood cardioplegia preceded and followed by 37 degrees C blood cardioplegia, there was complete recovery of left ventricular function (peak stroke work index 1.6 +/- 0.2 gm x m/kg) and maintenance of adenosine triphosphates, glutamate, and aspartate levels at or above control levels adenosine triphosphate 18 +/- 2 mumol/gm, aspartate 21 +/- 1 versus control 2 mumol/gm, and glutamate 25.4 +/- 2 mumol/gm). Puppy hearts receiving blood cardioplegic perfusion without ischemia had complete recovery of control stroke work index. We conclude that methods of myocardial protection used in adults, with amino acid-enriched, reduced-calcium blood cardioplegia, can be applied safely to the neonatal heart and allow for complete functional and metabolic recovery after prolonged aortic clamping.
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PMID:Studies of myocardial protection in the immature heart. V. Safety of prolonged aortic clamping with hypocalcemic glutamate/aspartate blood cardioplegia. 198 68

The present investigation studied the effect of increasing severities of ischemic injury on recovery of oxidative metabolism after reperfusion in isolated rat hearts perfused retrogradely with erythrocyte-containing medium. Hearts subjected to 60 minutes of low-flow ischemia (5% of control perfusion) exhibited delayed but sustained recovery of left ventricular pressure development during reperfusion and preservation of ultrastructure delineated with electron microscopy. Immediately after reperfusion, myocardial oxygen consumption returned to control values, well before left ventricular pressure development recovered. Early after reperfusion release of 14CO2 from [1-14C]palmitate was reduced (-53%, p less than 0.01). Conversely, release of 14CO2 from [U-14C]glucose was increased (+131%, p less than 0.05). After 60 minutes of reperfusion 14CO2 release had completely returned to normal for both labeled substrates. Pulse-labeling experiments indicated that during transient depression of [1-14C]palmitate oxidation more tracer was incorporated into myocardial lipid esters, primarily triglycerides. In contrast to hearts subjected to low-flow ischemia, hearts subjected to 60 minutes of no-flow ischemia exhibited poor recovery of contractile function during the reperfusion period. Electron microscopic examination of reperfused hearts showed advanced myocyte damage consistent with irreversible injury. Interestingly, myocardial oxygen consumption in this group also recovered to control values. The substrate pattern during the early reperfusion period was similar to that of hearts subjected to low-flow ischemia. After 120 minutes of no-flow ischemia, recovery of oxidative metabolism was virtually absent. The results indicate a pronounced dissociation between recovery of oxidative metabolism and of contractile function in reperfused myocardium. The oxidative metabolic rate was disproportionately high compared with contractile function, not only in reversibly "stunned" hearts, but also in severely damaged hearts exhibiting signs of irreversible injury.
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PMID:Effect of increasing degrees of ischemic injury on myocardial oxidative metabolism early after reperfusion in isolated rat hearts. 203 18

Chronic alcoholism causes a cardiac contractile dysfunction which, in rats, may occur after 6 mo to 1 yr of alcohol consumption. Sepsis, on a more acute basis, can also induce intrinsic cardiac dysfunction. We tested the hypothesis that 2 mo of chronic alcohol feeding, while not directly causing overt depression of the myocardium, might sensitize the heart to a known cardiac stress, i.e., sepsis. We proposed that sepsis, induced in an alcoholic animal, would cause a more severe myocardial depression than in a nonalcoholic rat. Thus rats were fed a liquid diet with 36% of the total calories as alcohol for 8-10 wk and were then anesthetized and received an injection of live Escherichia coli (approximately 10(10) E. coli) through a dorsal subcutaneous catheter followed by a second dose approximately 5 h later. The following day, hearts were removed and, using the isolated working heart preparation, intrinsic contractile performance was assessed by generating ventricular function curves. Four groups of animals were studied. Hearts from the nonalcoholic-nonseptic group and the alcoholic-nonseptic group showed identical cardiac work (cardiac output x peak systolic pressure at the highest preload was 6,113 +/- 324 and 5,955 +/- 406 ml.min-1.mmHg-1, respectively). Work in the nonalcoholic-septic and the alcoholic-septic groups was decreased by 30 and 50%, respectively (4,806 +/- 478 vs. 2,917 +/- 435 ml.min-1.mmHg-1 at the highest preload). Thus 2 mo chronic alcohol consumption caused no overt cardiac dysfunction by itself but did exacerbate the myocardial injury induced by sepsis.
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PMID:Chronic alcohol consumption enhances sepsis-induced cardiac dysfunction. 205 23

Effects of insulin on contractile and energy metabolic dysfunctions during hypoperfusion (2 ml/min/g heart wt., 60 min) with 10(-6) M norepinephrine were studied in paced hearts isolated from streptozotocin-diabetic rats. Insulin (2 mU/min/g heart wt.) was infused 20 min before and during hypoperfusion (pre-treated group) or 30 min after the onset of hypoperfusion (post-treated group). Hearts in the non-treated group were hypoperfused without insulin and other hearts in the control group were not hypoperfused. In the non-treated group, resting contractile force (CF) and resting left ventricular pressure (LVP) were significantly elevated to maximum levels within 30 min after hypoperfusion and these elevations were restored in the pre-treated group but not in the post-treated group. Developed CF was depressed in the non-treated group and improved significantly in the pretreated group but not in the post-treated group. Developed LVP was depressed in the non-treated group, and depression was slightly larger in the pre-treated group. In the non-treated group, ATP and creatine phosphate contents in the left ventricle significantly decreased. Decreases in ATP and creatine phosphate contents in the inner layer were partially restored in the pre-treated group but not in the post-treated group. Lactate significantly increased in the non-treated group and increased even further in the insulin treated groups. These results indicate that contractile dysfunction during hypoperfusion with norepinephrine is improved by pre-treated insulin, as is partial recovery of energy metabolism.
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PMID:Improvement of hypoperfusion with norepinephrine injury by ex vivo insulin in isolated diabetic rat hearts. 209 Aug 38

We have previously demonstrated that induction of the heat-shock response in rats results in improved recovery of isolated Langendorff-perfused rat hearts subjected to low-flow ischemia followed by reperfusion (Currie et al., 1988). The mechanisms underlying this protective effect of heat-shock are uncertain although the protection was associated with enhanced content of the antioxidant enzyme catalase but not superoxide dismutase or glutathione peroxidase (Currie et al., 1988). Various investigators have suggested the importance of improved energy metabolism in determining recovery following ischemia (Pasque and Wechsler, 1984; Haas et al., 1984; Devous and Lewandowski, 1987). We therefore examined, using a working rat heart model subjected to 10 or 15 min zero flow ischemia whether changes in energy metabolites could account for the protective effect of the heat-shock response. Hearts perfused 24 h after induction of heat-shock failed to demonstrate significant improvement of recovery following 10 min ischemia, however recovery was significantly enhanced in hearts reperfused after 15 min ischemia. Ischemia produced a depression in both ATP and creatine phosphate (CP) content whereas a moderate elevation in ADP and AMP and a marked increase in tissue lactate were evident. These changes were unaffected by prior heat-shock treatment. For both durations of ischemia tissue metabolites were determined during early (5 min) and late (30 min) reperfusion. Although partial recovery in high energy phosphates and a return of ADP, AMP and lactate to near-normal levels were evident, no differences in energy products were observed between hearts from normal or heat-shocked animals, in spite of significantly enhanced recovery.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Improved post-ischemic ventricular recovery in the absence of changes in energy metabolism in working rat hearts following heat-shock. 223 33


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