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

To study the cerebral protective effects of hypothermia in arterial hypoxia, anesthetized (70% N2O), mechanically ventilated rats were cooled to a body temperature of 27 C. Hypoxia was induced by decreasing the oxygen content in the inspired gas mixture either to 6-7 per cent or to 2.5-3 per cent. This reduced mean PaO2 to about 25 and 11-12 torr, respectively. At PaO2 torr, there was no change in cerebral blood flow (CBF), cerebrla oxygen consumption (CMRO2), or labile tissue metabolites. The absence of signs of cerebral hypoxia could be attributed to an effect of temperature and pH on the hemoglobin-oxygen dissociation curve. Thus, at 27 C with a PaO2 of 25 torr the total oxygen content (TO2) of arterial blood remained greater than 15 ml (100 ml)-1, about three times the value obtained at this PO2 in normothermic rats. At PaO2 11-12 torr, arterial TO2 was reduced to about 5 ml (100 ml) (-1). The hypoxia induced no change in CMRO2, a threefold increase in CBF, a moderate lactacidosis in the tissue, and a small decrease in phosphocreatine content, but no change in ATP, ADP, or AMP. These changes are less marked than those occurring at the same arterial TO2 in normothermic rats. It is concluded that hypothermia exerts a pronounced protective effect on the brain in hypoxic hypoxia, and that two mechanisms are involved. First, since hypothermia shifts the oxyhemoglobin-dissociation curve towards the left, and prevents or minimizes a rightward shift due to acidosis, it maintains a high TO2 in arterial blood at a given PaO2. Second, by reducing CMRO2, and thereby presumably also cellular energy requirements, hypothermia exerts a protective effect at the cellular level.
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PMID:Protective effect of hypothermia in cerebral oxygen deficiency caused by arterial hypoxia. 0 Sep 30

In order to study the relationship between arterial PCO2 and cerebral blood flow (CBF) in hypothermia, the body temperature of artifically ventilated rats was decreased to 22 degreesC, and changes in CBF were evaluated from arteriovenous differences in oxygen content (AVDO2) at PaCO2 values of 15, 30, 40 and 60 mm Hg. The results were compared to those obtained at normal body temperature (37 degrees C) over the PaCO2 range 15-60 mm Hg. Separate experiments were performed to evaluate CBF and CMRO2 at 22 degrees C and a PaCO2 of 15 mm Hg, using an inert gas technique for CBF. The tissue contents of phosphocreatine, ATP, ADP, AMP and lactate were measured in hypothermic animals at PaCO2 values of 15, 30 and 60 mm Hg. The results showed that changes in CBF were of the same relative magnitude in hypothermia and normothermia when PaCO2 was increased from about 35 to about 60 mm Hg. However, with a decrease in PaCO2 the reduction in CBF was much more pronounced in hypothermia, and at PaCO2 15 Mm Hg CBF was less then 20% of the value measured in normothermic and normocapnic animals. The results of the metabolite measurements gave no evidence of tissue hypoxia in spite of the pronounced reduction in CBF. Although the results demonstrate that the brain of a hypothermic animal is protected against the harmful effects of a lowered CBF, it may not warrant recommending hyperventilation in clinical cases of hypothermia, especially not in patients with arteriosclerosis or cerebrovascular diseases.
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PMID:Influence of changes in arterial PCO2 on cerebral blood flow and cerebral energy state during hypothermia in the rat. 0 61

1. Adenosine 3',5'-monophosphate (cAMP), its dibutyryl derivative (Db-cAMP) and other adenine nucleotides have been micro-injected into the hypothalamic region of the unanaesthetized cat and the effects on body temperature, and on behavioural and autonomic thermoregulatory activities observed. 2. Db-cAMP and cAMP both produced hypothermia when applied to the pre-optic anterior hypothalamus. With Db-cAMP the hypothermia was shown to be dose dependent between 50 and 500 mug (0-096-0-96 mumole). 3. AMP, ADP and ATP also produced hypothermia when injected into the pre-optic anterior hypothalamus. 4. The order of relative potencies of the adenine nucleotides with respect both to the hypothermia produced and to the autonomic thermoregulatory effects observed were similar. Db-cAMP was most potent and cAMP least. 5. Micro-injection into the pre-optic anterior hypothalamus of many substances including saline produced in most cats a non-specific rise in body temperature apparently the result of tissue damage. Intraperitoneal injection of 4-acetamidophenol (paracetamol 50 mg/kg) reduced or abolished this febrile response. 6. The hypothermic effect of the adenine nucleotides has been compared with the effects produced in these same cats by micro-injections of noradrenaline, 5-hydroxytryptamine, a mixture of acetylcholine and physostigmine (1:1), EDTA and excess Ca2+ ions. 7. It is concluded that as Db-cAMP and cAMP both produce hypothermia, it is unlikely that endogenous cAMP in the pre-optic anterior hypothalamus mediates the hyperthermic responses to pyrogens and prostaglandins.
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PMID:The effects of cyclic adenosine 3',5'-monophosphate and other adenine nucleotides on body temperature. 17 Mar 96

The influence of elevated and reduced body temperatures upon the metabolic state of the brain was evaluated from the tissue concentrations of phosphocreatine (PCr) ATP, ADP and AMP and from the concentrations of glucose, lactate and pyruvate in immobilized and artificially ventilated rats anesthetized with 70% N2O. The results were compared to the results obtained in normothermic animals. It was found that rats with body temperatures of 32 degrees and 22 degrees C had the same brain tissue concentrations of high energy phosphates and the same adenylate energy charge as the controls, but hypothermia led to a progressive decrease of both cerebral and arterial lactate and pyruvate concentrations. A metabolic acidosis but no excess lactate appeared in the blood. At a body temperature of 42 degrees C, the metabolic pattern in the brain agreed with a state of hypoxia at a time when there was no sign of substrate depletion. Arterial blood showed excess lactate which may indicate an inadequacy of the oxygen supply also to other tissues.
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PMID:Effects of hypothermia and hyperthermia on brain energy metabolism. 24 Nov 93

Potassium (34 mEq/L) cardioplegia was induced with cold blood (CBK) in three groups of six dogs undergoing 60 minutes of myocardial ischemia at a systemic temperature of 27 degrees +/- 2 degrees and a myocardial temperature of 7 degrees +/- 2 degrees C (crushed ice). Group 1 (CBK) animals were reperfused initially with 400 ml cold blood over 8 to 10 minutes at increasing pressures of up to 75 mm Hg. Group II (CBK-K) dogs were reperfused in the same manner as Group I with the addition of potassium chloride, 30 mEq/L. In Group III (CBKG-KG) glutathione, 30 mg/100 ml, was added to both the pre- and postischemic perfusions with CBK. After 30 minutes of reperfusion control studies were repeated. Heart rate, peak systolic pressure, rate of rise of left ventricular pressure, maximum velocity of contractile element, pressure-volume curves, coronary flow distribution, muscle stiffness, and heart water were not significantly different from control values. Total coronary flow and myocardial uptake of oxygen, lactate, and pyruvate did not serve to separate the three groups; the same was true for right ventricular creatine phosphate, adenosine triphosphate, and adenosine diphosphate during ischemia and recovery. Ultrastructural myofibrillar lesions were noted in all groups. thus, postischemic cardioplegia and use of a physiological reducing agent do not enhance CBK cardioplegia with topical and systemic hypothermia.
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PMID:Cold-blood potassium cardioplegia: evaluation of glutathione and postischemic cardioplegia. 50 72

Cold blood with potassium, 34 mEq/L, was compared with cold blood and with a cardioplegic solution. Three groups of 6 dogs had 2 hours of aortic cross-clamp while on total bypass at 28 degrees C with the left ventricle vented. An initial 5-minute coronary perfusion was followed by 2 minutes of perfusion every 15 minutes for the cardioplegic solution (8 degrees C) and every 30 minutes for 3 minutes with cold blood or cold blood with potassium (8 degrees C). Hearts receiving cold blood or cold blood with potassium had topical cardiac hypothermia with crushed ice. Peak systolic pressure, rate of rise of left ventricular pressure, maximum velocity of the contractile element, pressure volume curves, coronary flow, coronary flow distribution, and myocardial uptake of oxygen, lactate, and pyruvate were measured prior to ischemia and 30 minutes after restoration of coronary flow. Myocardial creatine phosphate (CP), adenosine triphosphate (ATP), and adenosine diphosphate (ADP) were determined at the end of ischemia and after recovery. Changes in coronary flow, coronary flow distribution, and myocardial uptake of oxygen and pyruvate were not significant. Peak systolic pressure and lactate uptake declined significantly for hearts perfused with cold blood but not those with cold blood with potassium. ATP and ADP were lowest in hearts perfused with cardioplegic solution, and CP and ATP did not return to control in any group. Heart water increased with the use of cold blood and cardioplegic solution. Myocardial protection with cold blood with potassium and topical hypothermia has some advantages over cold blood and cardioplegic solution.
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PMID:Cold blood as the vehicle for potassium cardioplegia. 51 80

The catabolism of 5'-adenine nucleotides in the cortex of the rabbit kidney was studied during normothermic and hypothermic ischaemia. Changes were found in the cortical content of ATP, ADP, AMP, and SAN (the sum of 5'-adenine nucleotides) during ischaemia; those changes were delayed by hypothermia. The loss of SAN was found to be significantly correlated to the duration of normothermic as well as hypothermic ischaemia. The oxypurines hypoxanthine and xanthine and the nucleoside inosine were shown to be the final products of the catabolism of 5'-adenine nucleotides. An accumulation of hypoxanthine-xanthine and inosine in the tissue and a corresponding excretion in the perfusion fluid occurred simultaneously with the catabolism of 5'-adenine nucleotides, in equivalent amounts. It is concluded that determination of the amount of oxypurines excreted during kidney preservation is an indirect measure of the loss of SAN in the tissue, and a reflection of the changes in the metabolic state.
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PMID:Breakdown of 5'-adenine nucleotides in ischaemic renal cortex estimated by oxypurine excretion during perfusion. 115 18

The objective of this study was to assess the influence of temperature on the coupling among energy failure, depolarization, and ionic fluxes during anoxia. To that end, we induced anoxia by cardiac arrest in anesthetized rats maintained at a body temperature of either 34 degrees C or 40 degrees C, measured extracellular K+ concentration (K+e), and froze the neocortex through the exposed dura for measurements of phosphocreatine (PCr), creatine (Cr), ATP, ADP, and AMP, glucose, glycogen, pyruvate and lactate content after ischemic intervals of maximally 130 s. Free ADP (ADPf) concentrations were derived from the creatine kinase equilibrium. Hypothermia reduced the initial rate of rise in K+e, and delayed the terminal depolarization; however, both hypo- and hyperthermic animals showed massive loss of ion homeostasis at a K+e of 10-15 mM. The initial rate of rise in K+e did not correlate to changes in ATP, or ATP/ADPf ratio, suggesting that temperature changes per se may control the degree of activation of K+ conductances. The results clearly showed that, in both hyper- and hypothermic subjects, energy failure preceded the sudden activation of membrane conductances for ions. The results indicate that temperature primarily influences membrane permeability to ions like K+e (and Na+), and that cerebral energy state is secondarily affected. It is proposed that the higher rate of rise of K+e at high temperatures accelerates ATP hydrolysis primarily by enhancing metabolic rate in glial cells.
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PMID:Changes of labile metabolites during anoxia in moderately hypo- and hyperthermic rats: correlation to membrane fluxes of K+. 142 48

Canine hearts were arrested with crystalloid cardioplegic solution (45 minutes at 7 degrees C) to determine whether either cardioplegia or hypothermia impairs the production of endothelium-derived relaxing factor or damages the vascular smooth muscle of epicardial coronary arteries. In addition, isolated coronary artery segments were exposed to either cold (7 degrees C) or warm (37 degrees C) crystalloid cardioplegic solution and physiologic salt solution in vitro for 45 minutes. After cardiac arrest or incubation with the solutions, segments of epicardial coronary artery were prepared and studied in organ chambers. Cardioplegic arrest of the heart or exposure to cardioplegic solution in vitro (7 degrees or 37 degrees C) did not alter endothelium-dependent relaxation of epicardial coronary artery segments in response to adenosine diphosphate or acetylcholine (10(-9) to 10(-4) mol/L). Cardioplegic arrest did not alter G protein-mediated, endothelium-dependent relaxation in response to sodium fluoride. In addition, smooth muscle contraction in response to potassium ions (voltage-dependent) or prostaglandin F2 alpha (receptor-dependent) and relaxation in response to isoproterenol (cyclic adenosine monophosphate-mediated) or sodium nitroprusside (cyclic guanosine monophosphate-mediated) was unaltered after exposure to cardioplegic solution or hypothermia. These experiments demonstrate that hyperkalemic crystalloid cardioplegia does not irreversibly alter function of epicardial coronary arteries. We hypothesize that coronary artery endothelial cell dysfunction identified in previous studies of cardioplegia may have been due to the effects of barotrauma or shear stress on the vasculature and not the effect of cardioplegia per se.
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PMID:Crystalloid cardioplegia and hypothermia do not impair endothelium-dependent relaxation or damage vascular smooth muscle of epicardial coronary arteries. 143 18

Purine nucleotide catabolism was examined during 24 hours of cold (0.5 degree C) storage of human transplant recipient hearts, baboon hearts, and dog hearts. The hearts were excised either after cold hyperkalemic cardioplegic arrest or after simple hypothermic arrest (25 degrees C). In human myocardium, hypothermia alone preserved the adenosine triphosphate pool markedly. Even after 24 hours of cold storage, adenosine triphosphate was still 9.5 +/- 2.5 mumol/gm dry weight (58% of the preischemic value). The major fraction of catabolites remained nucleotides: adenosine triphosphate plus adenosine diphosphate plus adenosine monophosphate decreased only from 99% +/- 1% (preischemic value) to 80% +/- 13% of the total purine content. The remaining catabolites were mainly nucleosides (adenosine 0.2% +/- 0.1% and inosine 19% +/- 13% of the total purine content). Cardioplegic arrest before cold storage did not change the pattern of purine nucleotide catabolism in any respect (p greater than 0.05). In baboon myocardium, hypothermia alone preserved the adenosine triphosphate content somewhat less than in human myocardium. Adenosine triphosphate content after 24 hours was 5.2 +/- 1.6 mumol/gm dry weight (40% of the preischemic value). The catabolism of adenosine triphosphate, however, did not proceed far beyond the level of adenosine monophosphate, so that the sum of nucleotides remained the same as in human hearts. Adenosine was 0.2% +/- 0.3% and inosine 17% +/- 4% of the total sum of purines. Also in the baboon heart, cardioplegia did not influence the pattern of catabolism significantly (p greater than 0.05). In the dog myocardium, hypothermia alone did not protect against severe catabolism of adenosine triphosphate. The adenosine triphosphate content at 24 hours of storage was 3.5 +/- 2.5 mumol/g dry weight (25% of the preischemic value). Catabolism of adenosine triphosphate proceeded far beyond the level of the nucleotides (63% +/- 17% of the total sum of purines), resulting in an accumulation of adenosine and inosine (5% +/- 4% and 30% +/- 13% of the total sum of purines) and even of hypoxanthine (1% +/- 1% of the total sum of purines). In the dog heart cardioplegic arrest inhibited adenosine triphosphate catabolism considerably. Adenosine triphosphate content at 24 hours was 8.1 +/- 1.8 mumol/gm dry weight (56% of the preischemic value); 83% +/- 5% of the total purine content remained present as nucleotides, and the nucleoside content was reduced to 2% +/- 3% for adenosine and 11% +/- 6% for inosine.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Degradation of myocardial high-energy phosphates during twenty-four hours of cold storage. Effects of cardioplegic versus noncardioplegic arrest. 156 80


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