UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
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To investigate the cause for the greater susceptibility of hypertrophied hearts to ischemic injury, we determined the interrelations of total work output, contractile function and energy metabolism in isolated, perfused normal and hypertrophied rat hearts subjected to graded global ischemia. Cardiac hypertrophy was induced by giving rats seven daily injections of either triiodothyronine (0.2 mg/kg) or isoproterenol (5 mg/kg). All hearts were perfused at an aortic pressure of 100 mmHg in the isovolumic mode in an NMR spectrometer (7.05 Tesla). Heart rate, developed pressure, and coronary flow were monitored simultaneously with changes in pH, creatine phosphate, ATP and inorganic phosphate. During pre-ischemic perfusion, the total work output (rate-pressure product) of hyperthyroid hearts was 28% higher than that of control hearts, whereas hearts from isoproterenol-treated animals showed no difference. However, when related to unit muscle mass, work was normal in hyperthyroid hearts and 26% lower after isoproterenol. Contractile function per unit myocardium (developed pressure/g wet weight) was lower in the hypertrophied hearts. ATP content was the same in all groups. Creatine phosphate decreased 41% after triiodothyronine and 25% after isoproterenol. Inorganic phosphate levels and intracellular pH were similar in control and isoproterenol-treated rat hearts, but were higher in the hyperthyroid rat hearts. The phosphorylation potential and the free energy change of ATP hydrolysis were lowered by hypertrophy, the levels correlating with the depressed contractile function. At each ischemic flow rate, both work and contractile function per unit myocardium were the same for all hearts, but the relations between flow and phosphorylation potential were different for each type of heart. Thus, at low flow rates, hypertrophied hearts perform the same amount of work and have the same contractile function as control hearts, but with abnormal changes in energy metabolism, indicating that the relations of energy status to coronary flow, total work output and contractile function are altered during the process of hypertrophy.
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PMID:31P NMR spectroscopy of hypertrophied rat heart: effect of graded global ischemia. 263 14

A combination of magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS) has been used to follow the time course of changes resulting from forebrain ischemia in the rat. The 31P MRS demonstrates that the level of high energy metabolites decreases significantly during the 10 min ischemic period but returns to normal after 1 h of reperfusion. MRI shows no change after 1 h of reperfusion but significant changes in the striatum after 24 h and in the hippocampus after 48 h. These changes correlate well with histopathology. Diabetic rats have shown the effect of hyperglycemia in accentuation of ischemic and post ischemic pH changes. Conversely, diabetic rats maintained severely hypoglycemic with insulin showed little variation in pH during or following the ischemic insult. The results emphasize the importance of both MRS and MRI in following the temporal profile and distribution of ischemic neuronal injury.
NMR Biomed 1989 Dec
PMID:Forebrain ischemia studied using magnetic resonance imaging and spectroscopy. 264 5

Coronary stenosis results in transmurally non-uniform blood flow with the inner layers of the left ventricular wall typically suffering a more severe hypoperfusion relative to the outer layers. Coupled with numerous other transmural non-uniformities such as systolic tension development and oxygen needs, the heterogeneous blood flow distribution in the presence of coronary stenosis is expected to result in transmurally heterogeneous ischemia. All previous NMR spectroscopy studies of myocardial metabolism and bioenergetics under normal and ischemic conditions treated the organ as a homogeneous tissue. We have utilized spatially localized 31P NMR spectroscopy together with non-NMR measurements of regional blood flow to study the myocardium with transmural spatial differentiation under normal and flow-restricted conditions. 31P NMR and blood flow data obtained concurrently on each heart revealed that sustained coronary artery stenosis resulted in transmurally non-uniform ischemia which largely paralleled the hypoperfusion pattern. The reduction in creatine phosphate content (with consequent elevation of Pi) and hypoperfusion was tightly correlated in the subendocardium for flow rates less than approximately 0.7 mL/min per g wet myocardium. The high energy phosphate and Pi content of the epicardium, however, was responsive not only to the flow to this region but also to the extent of ischemia in the subendocardial layers. These results document the utility of localized NMR spectroscopy in physiologic research and suggest potential biomedical applications due to the tight correlation noted between alterations in blood flow and changes in the phosphorylated metabolite levels detected by 31P NMR.
NMR Biomed 1989 Dec
PMID:Metabolic consequences of coronary stenosis. Transmurally heterogeneous myocardial ischemia studied by spatially localized 31P NMR spectroscopy. 264 6

For the validation of volume-selective 1H and 31P NMR spectroscopy of the brain methods are required that allow high resolution quantitative mapping of tissue pH and metabolites on intact brain slices. The following techniques are proposed for this purpose. Tissue pH is imaged on cryostat sections of in situ frozen brains, using umbelliferone as a fluorescent pH indicator (Csiba et al, Brain Res 289, 334-337 (1983]. Regional tissue ATP content is measured in adjacent cryostat sections, using the luciferine/luciferase system of fireflies for evoking substrate-specific bioluminescence (Kogure and Furones Alonso, Brain Res. 154, 273-284 (1978]. Lactate content is imaged in a similar way by inducing substrate-specific bioluminescence with lactate dehydrogenase and luciferase from vibrio Fischeri (Paschen, J. Cereb. Blood Flow Metab. 5, 609-612 (1985]. The spatial resolution of these techniques is better than 100 mu, as exemplified in experimental brain tumors and brain infarct of cats. The applicability of biochemical mapping for the validation of NMR spectroscopy was tested in a global brain ischemia model of cat by correlating surface coil 31P and 1H spectra with the corresponding regional biochemical data, measured in the sensitive volume of the coil. Correlation coefficients were r = 0.907, 0.852 and 0.924 for pH, lactate and ATP, respectively. These results demonstrate that the biochemical measurements obtained by bioluminescence and fluoroscopic imaging correlate closely with the NMR data and, therefore, are appropriate for the validation of more complex applications, such as volume-selective spectroscopy of brain infarcts or tumors.
NMR Biomed 1989 Dec
PMID:Imaging of brain tissue pH and metabolites. A new approach for the validation of volume-selective NMR spectroscopy. 270 7

Initial levels of phosphate brain metabolites were measured using 31P NMR spectroscopy in rats which subsequently died or survived under bilateral ligation of common carotid arteries. A multidimensional analysis was applied. In the rats which died after the brain ischemia: (1), NAD and NADH+ concentrations were much higher than those of creatine phosphate or ATP (i.e. baseline dysbalance existed between the systems of hydrogen acceptors and major macroergic substances); (2), the force of relationships between parameters of NMR spectra in each correlation matrix were 10 times higher and the variability of elements in each matrix was significantly lower than those of the surviving group. These regularities can be used in detection of special groups at high professional risk and in designing individual procedures of prevention and treatment of cerebral circulation disorders. The data are valuable in terms of development of drugs which would correct the dysbalance between hydrogen acceptors and macroergic systems thus providing a metabolic defense for the ischemic brain.
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PMID:[Prognostically significant indices of the bioenergetic metabolism of the brain in experimental ischemia (a NMR spectroscopic study)]. 271 59

The activity of electroencephalogram (EEG) and cortical somatosensory evoked potential (SEP) was suppressed during cerebral ischemia in rats subjected to the 4-vessel occlusion. Considerable variations were demonstrated in the decrease of phosphocreatine and ATP concentration during ischemia among the rats measured with 31P-NMR, accompanied with cerebral acidification. Hypercapnia, induced in the rats studied by the inhalation of a gas mixture of 30-40% CO2, suppressed the activity of EEG and cortical SEP. The cerebral acidification observed during the ischemia was more severe than that under the hypercapnia, implying that cerebral acidification is one of the possible causes for the decrease in the electrical activity of the brain during ischemia.
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PMID:Effect of cerebral ischemia and hypercapnia on cerebral pH studied with 31P-NMR and electrical activity in rat brain. 272 63

Quantitative Evaluation of Relationship between Cardiac Energy Metabolism and Post-ischemic Recovery of Contractile Function. Mechanisms of ischemic damage were studied by defining the relationships between post-ischemic work recovery and tissue ATP levels in isolated rat hearts as well as mitochondrial respiration rates in skinned myofibrils. Pre-ischemic levels of ATP were reduced by 2-deoxyglucose treatment and assessed using 31P-NMR. A 70% fall of ATP was not associated with decreased functional recovery. Mitochondrial respiration was assessed without mitochondrial isolation in skinned cardiac fibers in physiological salt solution using a novel method developed by Veksler et al. Maximal rates of mitochondrial respiration were not changed after 35 min of normothermic ischemia using St. Thomas's Hospital cardioplegic solution followed by 30 min of aerobic reperfusion. Only a reversible increase in the rate of basal respiration and a decrease in creatine-stimulated oxygen uptake were observed. Thus, mitochondrial oxidative phosphorylation, as assessed in skinned myofibrils, was tolerant to an ischemic period which induced permanent depression of contractile function along with alterations in metabolite distribution. As a result, tissue level of ATP and rates of mitochondrial respiration provided an estimate of ischemic damage only in cases where damage reached a very severe extent.
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PMID:Quantitative evaluation of relationship between cardiac energy metabolism and post-ischemic recovery of contractile function. 273 31

Glucose metabolism is altered in various pathologic conditions in the brain, i. e. ischemia, epilepsy and hypoglycemia. Therefore, analysis of glucose metabolism in pathologic conditions needs careful investigation of that in steady state. 13C-NMR method allows continuous sequential monitoring of changes in metabolism of glucose in vivo. The natural abundance of 13C is quite low (1.1%) and by administering 13C labelled in various skeleton in glucose, it is possible to monitor the metabolites in vivo. In this study, 13C glucose labelled in 1-position of carbon was employed to investigate the metabolic pathways in the control and transient ischemic gerbil brain with reperfusion. Male mongolian gerbils weighing 60-80 g were employed in this study. The gerbils were anesthetized by intraperitoneal administration of pentobarbital. The right skull was exposed and a surface coli was placed directly above the skull bone. After the operation, the animals were fastened to the NMR probe vertically. 500 mg/kg of [1-13C] glucose was injected via femoral catheter. 13C-NMR spectra were serially obtained before and after injection with GX-270 NMR spectrometer (JEOL, Tokyo, Japan, 6.34 T). In other series of experiments, 30 minutes of cerebral ischemia were induced after 15 minutes of glucose injection by the bilateral common carotid artery occlusion. In the normal gerbil brain, after administration of [1-13C] glucose (500 mg/kg), alpha and beta-anomers of [1-13C] glucose peak appeared abruptly and reached its peak level at 7.5-15 min acquisition period. The C2 peak representing glutamate and/or glutamine appeared later. The C3 and C4 peak started to appear even later at 30-40 min.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[The metabolism of glucose monitored by 13C-NMR in the gerbil brain in vivo-natural course and application to the ischemic model]. 273 47

In the normal and post-ischemic, isovolumic Langendorff perfused rat hearts, 31P NMR spectra and mechanical performance were evaluated over a wide range of myocardial oxygen consumption rates (MVO2). Hearts were perfused with either glucose and insulin, palmitate and glucose, or pyruvate and glucose as exogenous carbon sources. After ischemia at 38 degrees C until the onset of ischemic contracture and subsequent reperfusion, the "free" ADP levels were significantly reduced as compared to controls. In the control palmitate + glucose and glucose + insulin groups, the ADP levels were virtually independent of approximately 2.5-fold variation in MVO2; in contrast, they changed 4-fold with a approximately 30% variation in MVO2 in the post-ischemic myocardium following ischemia to contracture. In the pyruvate + glucose group, ADP levels varied with MVO2 in controls and post-ischemia; however, MVO2-ADP relationship was significantly altered following ischemia. Analysis of these observations within the concept of kinetic regulation of oxidative phosphorylation yielded the following significant conclusions: 1) the mode of respiratory regulation changed from a non-ADP to an "ADP:Pi limited" domain with non-pyruvate carbon sources; 2) respiratory regulation was in the ADP:Pi limited domain before and after ischemia in the pyruvate + glucose group; however, the Km for the relationship between MVO2 and ADP was reduced following the ischemia/reperfusion insult; 3) the post-ischemic oxidative capacity (Vmax for MVO2) was significantly reduced in all groups and this reduction would limit maximal post-ischemic mechanical performance.
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PMID:Alterations in oxidative function and respiratory regulation in the post-ischemic myocardium. 274 49

13C NMR spectroscopy may offer a unique ability to characterize the metabolic response to graded reduction in coronary flow since it allows repeated, nondestructive identification of products of intermediary metabolism in the same heart. The sensitivity of 13C parameters of glucose metabolism was compared with changes in levels of phosphocreatine, ATP, and pH as determined by 31P NMR in the intact, beating rat heart model during graded reductions in coronary flow. Experiments were performed during 60 min of perfusion with [1-13C]glucose (5 mM) at normal flow (15 ml/min) and at the reduced flow rates of 5 and 2 ml/min. During flow at 5 ml/min, isovolumic developed pressure fell to 51 +/- 4% of control. Although phosphocreatine, ATP, and pH were not changed, [3-13C]lactate was increased (1.46 +/- 0.12 mumol/g of wet weight vs. 0.63 +/- 0.08 during normal flow). In addition, the time to 50% maximum enrichment of [2-13C]glutamate was prolonged (17 +/- 1 min vs. 9 +/- 1 min during normal flow), indicating that glucose-supported flux through the tricarboxylic acid (TCA) cycle was decreased. The relative anaplerotic contribution to citrate synthase-supported TCA flux was increased from 6% to 35%. These 13C metabolic changes could not be reproduced by reduced [1-13C]glucose delivery in the absence of ischemia, although similar reduced TCA flux indices were reproduced in additional hearts when workload was reduced by low calcium (0.7 mM) perfusion. Therefore, the information provided by 13C NMR spectroscopy can be a more sensitive indicator of flow-induced alterations in cardiac metabolism than that provided by the much more commonly used 31P NMR technique.
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PMID:Comparative 13C and 31P NMR assessment of altered metabolism during graded reductions in coronary flow in intact rat hearts. 276 33

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