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Query: UMLS:C0020672 (hypothermia)
 17,327 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Glycolysis, glucose oxidation, palmitate oxidation, and cardiac function were measured in isolated working hearts from ground squirrels and rats subjected to a hypothermia-rewarming protocol. Hearts were perfused initially for 30 min at 37 degrees C, followed by 2 h of hypothermic perfusion at 15 degrees C, after which hearts were rewarmed to 37 degrees C and further perfused for 30 min. Functional recovery in ground squirrel hearts was greater than in rat hearts after rewarming. Hypothermia-rewarming had a similar general effect on the various metabolic pathways in both species. Despite these similarities, total energy substrate metabolic rates were greater in rat than ground squirrel hearts during hypothermia despite a lower level of work being performed by the rat hearts, indicating that rat hearts are less efficient than ground squirrel hearts during hypothermia. After rewarming, energy substrate metabolism recovered completely in both species, although cardiac work remained depressed in rat hearts. The difference in functional recovery between rat and ground squirrel hearts after rewarming cannot be explained by general differences in energy substrate metabolism during hypothermia or after rewarming.
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PMID:Effects of hypothermia on energy metabolism in rat and Richardson's ground squirrel hearts. 910 58

The effect of hypothermia on isolated perfused rat hearts was studied with 31P NMR. Hearts were continuously perfused with phosphate-free Krebs-Henseleit buffer while the perfusate temperature was adjusted. Perfusate pH was kept at 7.40 +/- 0.02 throughout the experiments. Using the chemical shift difference between PCr and Pi the intracellular pH was estimated. At 36, 20, and 10 degreesC a cytosolic alkalinization at a pH of 7.05 +/- 0.04, 7.21 +/- 0.05, and 7.40 +/- 0.03 was observed, respectively. At 10 degreesC two Pi resonances were observed with a separation of 0.25 ppm. This resonance corresponded to a Pi resonance of a cellular compartment with a local pH of 7.78 +/- 0.06, likely mitochondrial. This additional resonance disappeared upon warming of the hearts back to 36 degreesC.
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PMID:Observation of two inorganic phosphate NMR resonances in the perfused hypothermic rat heart. 991 52

During organ ischemia, oxygen (O2) is the first "substrate", which is depleted. However, during ischemic storage in hypothermia (0-4 degrees C), a sufficient oxygenation is attainable by means of gaseous O2. The results of organ preservation were (mostly) better than those obtained with other methods at the respective times. O2 can be supplied via organ surfaces: Applying high O2-pressures (3040-15,200 hPa), ileum and lungs or hearts had some functions after 48 and 72 h storage, respectively; life-supporting functions regained kidneys and pancreas after 48 and 22 h storage, respectively. At normobaric conditions, intestine supplied with O2 via its lumen had during ischemic storage an aerobic metabolism and a better post-ischemic function. Using the "two-layer-method" (TLM), pancreas was stored for 96 h and after 90 min anaerobic warm ischemia (aWI) for 48 h with life-supporting functions after transplantation (Tx). Ischemic organs can be persufflated normobarically with gaseous O2 via their vessels. Hearts, skeletal muscles and kidneys in normothermia or frogs' spinal cords-remained viable for many hours. In hypothermia, kidneys damaged by 30 or 60 min aWI could be preserved for 48 and 24 h, respectively, with life-supporting functions after Tx. Hearts subjected to several hours of aerobic ischemia performed post-ischemically better. Livers aerobically stored for 48 h, or for 24 or 4 h after 30 or 60 min aWI, respectively, exhibited greatly improved post-ischemic functions. After 60 min aWI and 2 h persufflation for reconditioning, livers could be stored for another 22 h period of anaerobic ischemia. With normobaric O2-persufflation or TLM during ischemia, energy supply in form of ATP and its demand-meeting utilisation during hypothermia are apparently guaranteed, so that even longer periods of ischemia for Tx-related measures can be overcome. Not only the maintenance of cell and organ integrity or of cellular functions, but also the repair of damaged structures and functions have become possible with less expenditures and risks than with perfusion. The composition of the solutions for preservation or reconditioning of the ischemic organs is pivotal.
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PMID:[Gaseous oxygen for protection and conditioning of organs during ischemia]. 1035 78

Hypothermia improves resistance to subsequent ischemia in the cardioplegic-arrested heart (CAH). This adaptive process produces mRNA elevation for heat shock protein (HSP) 70-1 and mitochondrial proteins, adenine nucleotide translocator (ANT(1)), and beta-F(1)-ATPase. Glucose in cardioplegia also enhances myocardial protection. These processes might be linked to reduced ATP depletion. To assess for synergism between these protective processes, isolated rabbit hearts (n = 91) were perfused at 37 degrees C and exposed to ischemic cardioplegic arrest for 2 h. Hearts were in four groups: control (C), hypothermia adapted (H) perfused to 31 degrees C 20 min before ischemia, 22 mM glucose (G) in cardioplegia, and hypothermic adaptation and glucose (HG). Developed pressure (DP), dP/dt(max), and pressure-rate product (PRP) improved (P < 0.05) in G, H, and HG compared with C during reperfusion. DP and PRP were elevated in HG over H and G. ATP was higher in G, H, and HG, although no additional increase in HG over H was found. Lactate and CO(2) production were elevated in G only. The mRNA expression for HSP70-1, ANT(1), and beta-F(1)-ATPase was elevated severalfold in H and HG, but not G over C during reperfusion. In conclusion, glucose provides additional functional improvement in H. Additionally, neither ATP levels nor anaerobic metabolism are linked to mRNA expression for HSP70, ANT(1), or beta-F(1)-ATPase in CAH.
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PMID:Mitochondrial protein and HSP70 signaling after ischemia in hypothermic-adapted hearts augmented with glucose. 1040 52

This research was undertaken to determine potential interactions among chemical and physical agents. Radiofrequency (RF) radiation is used in numerous workplaces, and many workers are concurrently exposed to RF radiation and various chemicals. The developmental toxicity of RF radiation is associated with the degree and duration of hyperthermia induced by the exposure. Previous animal research indicates that hyperthermia induced by an elevation in ambient temperature can potentiate the toxicity and teratogenicity of some chemical agents. We previously demonstrated that combined exposure to RF radiation (10 MHz) and the industrial solvent, 2-methoxyethanol (2ME), enhanced teratogenicity in rats. Interactions were noted at even the lowest levels of 2ME tested, but only at hyperthermic levels of RF radiation. The purpose of the present research is to investigate if the interactive effects noted for RF radiation and 2ME are unique to these agents, or if similar interactions might be seen with other chemicals. Because methanol is widely used as a solvent as well as fuel additive, and, at high levels, is teratogenic in animals, we selected methanol as a chemical to address generalizability. Based on the literature and our pilot studies, 0, 2, or 3 g/kg methanol (twice, at 6-hour intervals) were administered on gestation day 9 or 13 to groups of 10 Sprague-Dawley rats. Dams treated on day 9 were given methanol and exposed to RF radiation sufficient to maintain colonic temperature at 41 degrees C for 60 minutes (or sham). Those treated on day 13 were given methanol plus either 0 or 100 mg/kg 2ME. Because we observed that methanol produced hypothermia, some groups were given the initial dose of methanol concurrently with the RF or 2ME, and others were given the first dose of methanol 1.5 hours prior to RF or 2ME. Dams were sacrificed on gestation day 20, and the fetuses were examined for external malformations. The results indicate that RF radiation or methanol on day 9 increased the incidence of resorbed fetuses, but no interactive effects were observed. The resorptions were highest in groups given the experimental treatments 1.5 hours apart. The higher dose of methanol also reduced fetal weights. Administration of 2ME or methanol on day 13 increased the rate of malformations, and there was evidence of a positive interaction between 2ME and methanol. Fetal weights were reduced by 2ME and methanol alone, but no interaction was observed. Also, separation of the dosing with the teratogens did not affect the results. These results point out that interactions in developmental toxicology, such as those of RF radiation, 2ME, and methanol that we have studied, are complex, and such interactions cannot be fully understood or predicted without more research. It is important that combined exposure effects be considered when developing both physical agent and chemical agent exposure guidelines and intervention strategies.
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PMID:Developmental toxicity interactions of methanol and radiofrequency radiation or 2-methoxyethanol in rats. 1135 70

This study examines the electrophysiological and metabolic changes that occur in rabbit hearts during hypothermic storage in vitro. Hearts were microperfused at 4 degrees C for 6 or 24 h with either normal Krebs-Henseleit buffer (KHB) or KHB containing 2,3-butanedione monoxime (BDM). After hypothermic storage, hearts were rewarmed to 37 degrees C with KHB. Cardiac function was then assessed in Langendorff perfusion mode. Electrophysiological changes were also assessed from the ventricular paced-evoked responses. After storage, mitochondria were isolated from the hearts and their respiratory control ratio, rate of ATP synthesis and outer membrane intactness were assessed. Compared with values from fresh non-stored hearts, hearts stored hypothermically for 24 h showed significant decreases in both left ventricular developed pressure and coronary flow when reperfused in Langendorff mode. On the other hand, the decrease in left ventricular developed pressure in hearts that were stored for only 6 h (with or without BDM) was not significant. Compared with values obtained from fresh non-stored hearts, hypothermic storage significantly decreased the R-wave amplitude, and both the R-E and ST-E intervals of paced-evoked responses. This was true for hearts microperfused for 6 h (with or without BDM) and for hearts microperfused with buffer containing BDM for 24 h. The ST-R intervals in hearts microperfused hypothermically for 6 h were prolonged, but this change was not statistically significant compared with those obtained from unstored hearts. In hearts microperfused with KHB containing BDM for 24 h, the ST-R interval was significantly prolonged. Hypothermic microperfusion for 24 h significantly decreased both the mitochondrial coupling ratio and the rate of ATP synthesis. In hearts microperfused with BDM for 6 h, mitochondrial coupling ratios and the rate of ATP synthesis were not significantly different from those in fresh hearts. In conclusion, the present study has shown that long-term hypothermic storage significantly impaired both paced-evoked responses and mitochondrial function. Inclusion of BDM in the perfusion buffer during storage significantly ameliorated some of these changes.
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PMID:Electrophysiological and biochemical changes in rabbit hearts stored at 4 degrees C for 6 or 24 h. 1156 74

This work investigates whether purine metabolism and release is related to cardioprotection with hyperkalemia and hypothermia. Langendorff guinea-pig hearts were used to either monitor metabolism during ischemia or to measure functional recovery, myocardial injury and release of purine during reperfusion. Hearts underwent 30 min ischemia using one of the following protocols: control (normothermic buffer), hyperkalaemia (high-potassium buffer), hypothermia (20 degrees C) and hyperkalemia + hypothermia. At the end of 30 min ischemia, hyperkalemia was associated with similar metabolic changes (rise in purine and lactate and fall in adenine nucleotides) to control group. Accumulation of purine was due to a rise in inosine, xanthine and hypoxanthine and was largely prevented by hypothermia and hyperkalemia + hypothermia. Upon reperfusion, there was a time-dependent release of all purine, lactate and AMP. A fast (peak in less than 20 sec) release of inosine, xanthine, hypoxanthine and lactate was highest in control followed by hyperkalemia then hypothermia and little release in hyperkalemia + hypothermia. Adenosine and AMP release was slow (peak at 3 min), only significant in control and was likely to be due to sarcolemmal disruption as the profile followed lactate dehydrogenase release. Recovery (left ventricular developed pressure) was 63% control, 82% hyperkalemia, 77% hypothermia and 98% for hyperkalemia + hypothermia. The loss of purine during reperfusion but not their production during ischemia is related to cardioprotection with hyperkalemia. The possibility that the consequences of hyperkalemia modulate a sodium-dependent purine efflux, is discussed. The reduced loss of purine in hypothermia or in hyperkalemia + hypothermia is likely to be due to a lower metabolic activity during ischemia.
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PMID:Purine metabolism and release during cardioprotection with hyperkalemia and hypothermia. 1223 79

Hypothermic perfusion of the heart decreases oxidative phosphorylation and increases NADH. Because O(2) and substrates remain available and respiration (electron transport system, ETS) may become impaired, we examined whether reactive oxygen species (ROS) exist in excess during hypothermic perfusion. A fiberoptic probe was placed on the left ventricular free wall of isolated guinea pig hearts to record intracellular ROS, principally superoxide (O(2)(-).), and an extracellular reactive nitrogen reactant, principally peroxynitrite (ONOO(-)), a product of nitric oxide (NO.) + O(2)(-). Hearts were loaded with dihydroethidium (DHE), which is oxidized by O(2)(-). to ethidium, or were perfused with l-tyrosine, which is oxidized by ONOO(-) to dityrosine (diTyr). Shifts in fluorescence were measured online; diTyr fluorescence was also measured in the coronary effluent. To validate our methods and to examine the source and identity of ROS during cold perfusion, we examined the effects of a superoxide dismutase mimetic Mn(III) tetrakis(4-benzoic acid)porphyrin chloride (MnTBAP), the nitric oxide synthase inhibitor N(G)-nitro-l-arginine methyl ester (l-NAME), and several agents that impair electron flux through the ETS: menadione, sodium azide (NaN(3)), and 2,3-butanedione monoxime (BDM). Drugs were given before or during cold perfusion. ROS measured by DHE was inversely proportional to the temperature between 37 degrees C and 3 degrees C. We found that perfusion at 17 degrees C increased DHE threefold versus perfusion at 37 degrees C; this was reversed by MnTBAP, but not by l-NAME or BDM, and was markedly augmented by menadione and NaN(3). Perfusion at 17 degrees C also increased myocardial and effluent diTyr (ONOO(-)) by twofold. l-NAME, MnTBAP, or BDM perfused at 37 degrees C before cooling or during 17 degrees C perfusion abrogated, whereas menadione and NaN(3) again enhanced the cold-induced increase in ROS. Our results suggest that hypothermia moderately enhances O(2)(-). generation by mitochondria, whereas O(2)(-). dismutation is markedly slowed. Also, the increase in O(2)(-). during hypothermia reacts with available NO. to produce ONOO(-), and drug-induced O(2)(-). dismutation eliminates the hypothermia-induced increase in O(2)(-).
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PMID:Hypothermia augments reactive oxygen species detected in the guinea pig isolated perfused heart. 1464 63

This study was undertaken to explore the myocardioprotective effects of the combination of ischemic preconditioning (IP) with hypothermia and St.II Thomas crystalloid cardioplegic solution (CCS) on immature hearts in the rabbit. Isolated immature rabbit hearts were perfused with Krebs-Henseleit bicarbonate buffer on Langendorff apparatus. In experiment 1, 24 hearts were divided into 4 groups (n=6 in each group): Con, IP1, IP2 and IP3 group. Hearts of the four groups underwent 0, 1, 2 or 3 cycles of IP respectively. Then all the hearts were subjected to a sustained ischemia period of 2 h at 20 degrees C and a postischemic reperfusion period of 30 min at 37 degrees C. In experiment 2, 48 hearts were divided into 6 groups (n=8 in each group): SCon1, SIP1, SCon2, SIP2, SCon3 and SIP3 group, according to hypothermia and the duration of sustained ischemia (30 min at 32 degrees C; 90 min at 25 degrees C, 2 h at 20 degrees C). The SIP1, SIP2 and SIP3 groups were preconditioned twice before the sustained hypothermic ischemia, while the SCon1, SCon2 and SCon3 groups were not preconditioned. CCS was applied during sustained ischemia, all the hearts were reperfused for 30 min at 37 degrees C. Heart rate (HR), left ventricular developed pressure (LVDP) and peak rate of increase or decrease of left ventricular pressure (+/-dp/dt(max)) were recorded. Tissue concentration of adenosine triphosphate (ATP), malondialdehyde (MDA) and the activity of superoxide dismutase (SOD) were measured. At the end of reperfusion, values of product of LVDP and HR, +/-dp/dt(max) in IP2 group were 96%+/-21%, 101%+/-19% and 84% +/-15% of the baseline values respectively, which were significantly higher than those of Con group and IP3 group (P<0.01, P<0.05); also, the ATP content of IP2 group was higher than that of the Con group (P<0.01). When CCS was applied during sustained period of hypothermic ischemia at 32 degrees C or 25 degrees C, recovery rates of RPP (rate product, =LVDPxHR) and +dp/dt(max) in SIP1 group were 87% +/-14% or 99% +/-26% of the baseline values respectively (P<0.05, vs SCon1 group), the values in SIP2 group changed to 87% +/-16% or 102% +/-20% respectively (P<0.05, vs SCon2 group). Contents of ATP in SIP1 and SIP2 groups were significantly higher than those of SCon1 or SCon2 groups respectively (P<0.05), but MDA content of the two groups were significantly lower than those of SCon1 or SCon2 groups (P<0.05) respectively. The study indicates that IP attenuates hypothermic ischemia/reperfusion injury to immature rabbit hearts under 20 degrees C ischemia, two cycles of IP showing better myocardioprotective effects than 1 or 3 cycles of IP. When IP was combined with CCS which were applied during hypothermic ischemia period, the beneficial effects of IP were weakened as the temperature during the hypothermic period was elevated.
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PMID:Myocardioprotective effects of the combination of ischemic preconditioning with hypothermia and crystalloid cardioplegia in immature rabbits. 1522 56

Aim of our study was to measure conduction velocity and pattern of excitation during hypothermia in hearts of ground squirrels Citellus undulatus, known to be most resilient hibernators. We imaged electrical conduction in intact isolated hearts of summer active and winter hibernating ground squirrels at temperatures varying from +37 degrees C to +3 degrees C. Electrical activity was mapped using CCD camera (500 frames/sec) and voltage-sensitive dye di-4-ANEPPS during normal sinus rhythm and ventricular pacing. No spontaneous tachyarrhythmia was observed in all hearts at any temperature. Hearts were able to maintain spontaneous sinus rhythm and normal pattern of epicardial excitation throughout the whole range of studied temperatures. Despite responsiveness to pacing in all hearts ventricular conduction velocity was significantly reduced (about 10-fold) at low temperatures +3 degrees C. Our data provides the first direct demonstration that isolated heart of the summer active and winter hibernating ground squirrel Citellus undulatus is able to maintain normal excitation pattern in a range of temperatures from +37 degrees C to +3 degrees C.
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PMID:[Pattern of excitation in isolated heart of hibernator ground squirrel Citellus undulatus]. 1594 Jan 84


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