Is oxygen supply a limiting factor for survival during rewarming from profound hypothermia?

It has been postulated that unsuccessful resuscitation of victims of accidental hypothermia is caused by insufficient tissue oxygenation. The aim of this study was to test whether inadequate O2 supply and/or malfunctioning O2 extraction occur during rewarming from deep/profound hypothermia of different duration. Three groups of rats (n = 7 each) were used: group 1 served as normothermic control for 5 h; groups 2 and 3 were core cooled to 15 degrees C, kept at 15 degrees C for 1 and 5 h, respectively, and then rewarmed. In both hypothermic groups, cardiac output (CO) decreased spontaneously by > 50% in response to cooling. O2 consumption fell to less than one-third during cooling but recovered completely in both groups during rewarming. During hypothermia, circulating blood volume in both groups was reduced to approximately one-third of baseline, indicating that some vascular beds were critically perfused during hypothermia. CO recovered completely in animals rewarmed after 1 h (group 2) but recovered to only 60% in those rewarmed after 5 h (group 3), whereas blood volume increased to approximately three-fourths of baseline in both groups. Metabolic acidosis was observed only after 5 h of hypothermia (15 degrees C). A significant increase in myocardial tissue heat shock protein 70 after rewarming in group 3, but not in group 2, indicates an association with the duration of hypothermia. Thus mechanisms facilitating O2 extraction function well during deep/profound hypothermia, and, despite low CO, O2 supply was not a limiting factor for survival in the present experiments.     

Effect of Selective Brain Hypothermia on Regional Cerebral Blood Flow and Tissue Metabolism Using Brain Thermo-Regulator in Spontaneously Hypertensive Rats

To investigate the effect of selective hypothermia of the brain (brain cooling) on regional cerebral blood flow and tissue metabolism, we have developed a brain thermo-regulator. Brain temperature was modulated by a water-cooled metallic plate placed on the surface of the rats' scalp to get the appropriate brain temperature precisely with ease. Regional cerebral blood flow and brain temperature were measured simultaneously using a Teflon-coated platinum electrode and thermocouple probe inserted stereotaxically into the parietal cortex and thalamus in spontaneously hypertensive rats. Experimental forebrain ischemia was induced by the occlusion of bilateral common carotid artery under normo- and hypothermic brain condition, and the supratentorial brain tissue metabolites were measured enzymatically after 60 min of forebrain ischemia. When cortical temperature was set to hypothermia, cortical blood flow was significantly lowered by 40% at 30°C and 20% at 33°C as compared with that at 36°C (p < 0.0001 and p < 0.05, respectively). Thalamic blood flow was also significantly reduced by 20% when cortical temperature was set to 30°C as compared with 36°C (p < 0.05). There were no significant differences in arterial blood pressure and gas parameters throughout these experiments. In the rats with selective brain hypothermia (30°C) immediately after the induction of cerebral ischemia, the level of brain ATP concentration after 60 min of ischemia was significantly higher than that in normothermia rats (36°C) (p < 0.05). Our findings indicate that: 1) the metallic plate brain thermo-regulator is useful in small animal experiments; 2) regional brain temperature regulates regional cerebral blood flow; and 3) selective brain hypothermia, even started after the forebrain ischemia, ameliorates the derangement of brain metabolism, suggesting its effectiveness as a cytoprotective strategy.     

Regional cerebral blood flow changes during hypothermia

1. 1. When brain temperature was decreased from 38 to 22 °C using selective hypothermia, tissue blood flow decreased significantly in cerebral cortex, cerebellum, and thalamus, but did not significantly change in hypothalamic or brain stem tissue.

2. 2. A further decrease in brain temperature to 8 °C produced an increase in blood flow in all tissues except cerebral cortex compared to tissue blood flow measured at 22 °C. Compared to normothermic values, blood flow remained significantly decreased at 8 °C in cerebral and cerebellar cortex and was increased in brain stem.

3. 3. After rewarming, tissue blood flow returned to original baseline values in all tissues except cerebral cortex where blood flow was slightly but significantly decreased and brain stem, where blood flow was increased.

4. 4. These results indicate that the cerebrovascular effects of selective brain cooling are regionally specific. These changes appear to be due to both direct and indirect effects of cerebral hypothermia since brain tissue blood flow changes are apparent, compared to control values, after rewarming of the brain.

     

Effect of hypothermia on brain multi-parametric activities in normoxic and partially ischemic rats

Hypothermia, as well as anesthesia, are known to protect the brain against ischemia, hypoxia and other pathological damages. One of the mechanisms of this improvement could be by lowering brain function, and thereby lowering oxygen demand. We examined the effect of hypothermia on brain function and blood supply in awake and anesthetized rats and studied the interaction between partial ischemia and the responses to hypothermia. The brain function multiprobe (BFM) used enabled simultaneous measurements of cerebral blood flow (CBF), mitochondrial NADH redox state, extracellular K(+) concentration, DC potential and ECoG from the cerebral cortex in rats whose brain temperature was lowered by 5 degrees C. Hypothermia was induced in awake, anesthetized and brain ischemic-anesthetized rats. In anesthetized and ischemic-anesthetized rats, the time required for lowering the brain temperature by 5 degrees C was five times less than in the normal awake animals. No significant changes in CBF and NADH levels were found in response to hypothermia in the awake animals. In contrast, a significant decrease in extracellular K(+) concentration was recorded under hypothermia, probably due to the lower rate of depolarization. Hypothermia in anesthetized and in ischemic-anesthetized rats did not significantly affect the levels of mitochondrial NADH, CBF and extracellular K(+). Hypothermia under ischemia was expected to be more effective.     

Tissue blood flow in control and cold-adapted hyperthyroid rats

Chronic injections (once daily for 10-14 days) of triiodothyronine (T3) stimulated oxygen consumption by 50 and 15% in anaesthetized, control (24 degrees C), and cold-adapted (5 degrees C) rats, respectively, compared with euthyroid controls. Tissue blood flow, determined from the distribution of radioactive microspheres, was unaffected by T3 treatment in skeletal muscle, scrotum, brain, bone, skin, diaphragm, and brown adipose tissue (BAT) of rats housed at 24 degrees C, but was decreased in spleen (53% of control) and significantly increased in three white adipose tissue depots (average 267% increase) and liver (56%). Blood flow to epididymal fat and leg muscle of cold-adapted rats was increased by T3 treatment (100 and 138% increases, respectively), but other tissues were unaffected. Blood oxygen extraction and oxygen consumption in vivo by interscapular BAT was increased in hyperthyroid rats compared with euthyroid controls, but was reduced by T3 treatment in cold-adapted animals. These data show that BAT makes only a minor contribution (7%) to thyroid thermogenesis, but suggest that kidney, liver, gut, and particularly white adipose tissue may be involved.     

The effect of surface cooling on blood flow distribution in infant pigs with mature left to right shunts

Surface cooling as an adjunct to cardiopulmonary bypass, core cooling, and circulatory arrest has been effectively used to produce more homogeneous cooling and better tissue preservation. A previous study, using pigs with newly created aortopulmonary shunts, revealed a redistribution of blood flow away from the kidneys and viscera during surface cooling that did not occur in normal pigs. The present study tests the hypothesis that pigs with mature aortopulmonary shunts behave in a similar manner. Group I (N = 7, unshunted pigs) and Group II (N = 7, shunted pigs) underwent surface cooling and blood flow distribution measurements by microspheres at 37, 32, 28, and 25 degrees C. Both Groups I and II experienced a decrease in cardiac output with hypothermia. Group II had decreased absolute tissue flow to the viscera, kidneys, muscle, and skin at 37 degrees C compared with Group I, even before the onset of hypothermia. During hypothermia, Group I experienced a decrease in all tissue flows, but Group II had a decrease only in visceral and renal flows at 25 degrees C. Blood flow distribution, as a percentage of cardiac output, showed little change (decrease only in skin) in Group I with hypothermia. In Group II, however, a maldistribution of cardiac output developed resulting in decreased percentage of cardiac output to the kidneys and viscera and an increased percentage of cardiac output to the lungs that was confirmed by an increase in the Qp/Qs ratio.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of moderate hypothermia on O2 consumption at various O2 deliveries in a sheep model.

The effects of modest hypothermia on oxygen consumption (VO2) were studied at various levels of oxygen delivery (DO2) in six sheep. Each animal was placed on cardiopulmonary bypass by extrathoracic cannulations. DO2 was varied by changing blood flow through an extracorporeal circuit. VO2 was measured spirometrically across a membrane lung. VO2 was initially measured at various levels of DO2 at normothermic temperatures (39 degrees C). The animals were then cooled to 33 degrees C. DO2 was varied, and the corresponding VO2's were determined. The data at both temperatures demonstrated the biphasic relationship of VO2 to various levels of DO2. A critical level of DO2 (DO2 crit) was defined to reflect the transition area between the dependent and independent portions of the consumption-delivery curve. The average baseline VO2's on the delivery independent portion of the curve were calculated to be 5.33 and 3.17 ml O2.kg-1.min-1 at 39 and 33 degrees C, respectively (P less than 0.001). The corresponding DO2 crit's were 6.17 and 4.57 ml O2.kg-1.min-1 (P less than 0.05). The oxygen extraction ratios at DO2 crit for each of these temperatures did not differ significantly. We conclude that hypothermia, by lowering baseline VO2, reduces DO2 crit. Hypothermia may therefore reduce or eliminate the anaerobic metabolism and subsequent acidosis that would otherwise occur during normothermia at low levels of DO2.     

Preservation of guinea pig hearts by hypothermic gas perfusion

The lack of a satisfactory method for long-term preservation of hearts during transport limits the source of human hearts for transplant to the geographic vicinity of the transplant center. Experimentally, reduction of myocardial oxygen requirements with hypothermia and cardioplegia prolong storage time to 48 h, but always with some evidence of myocardial damage. In this study, the combination of hypothermia with a procedure known to increase oxygen tension in cardiac muscle, gas perfusion, preserved contractile activity in guinea pig hearts for 24 h and did not cause edema. Cardioplegia or gas perfusion at temperatures below 10 degrees C or above 20 degrees C resulted in failure of hearts to contract upon rewarming. Contracture, dehydration, elevation of tissue calcium, reduced perfusate flow, and elevated creatine kinase levels occurred if liquid reperfusion was begun at 15 degrees C but not 25 degrees C. The results suggest that under the appropriate conditions, hypothermic gas perfusion is a potentially useful means of extending storage time of hearts for transplant.     

Some aspects of metabolism following a 35 km road run.

The metabolism of eight men (mean: age, 26.0 years; maximal oxygen consumption, 65.0 ml.kg-1.min-1; body fat, 10.3%) was measured on counterbalanced control (baseline values for 8 h) and experimental (post 35 km run values for 8 h) days. The excess postexercise volume of oxygen consumed of 32.37 l and increase in energy used of 594 kJ during the 8 h after completion of the run were equivalent to average increases of 23.7 and 21.1%, respectively, when compared with time-matched controls. Furthermore, the oxygen uptake and energy expenditure were still elevated by 12.7 (P less than 0.0005) and 9.7% (P = 0.001), respectively, at the end of this period but the fact that they had returned to baseline 24 h after the 35 km road run contrasts with some reports in the literature that metabolism is still elevated at this time following less demanding exercise intensities. Rectal temperature was elevated by 2.3 degrees C at the end of the run but the difference had decreased to 0.2 degrees C by 7 h postexercise. The respiratory exchange ratio and changes in blood metabolites (nonesterified fatty acids, glycerol and ketone bodies) indicated a greater postexercise utilisation of fat notwithstanding a 6300 kJ meal ingested on both control and experimental days. The highest measured serum creatine kinase enzyme activity of 1151 U.l-1 (P less than 0.05) occurred 24 h postexercise, as compared with the control value of 145 U.l-1, and indicates the possibility of skeletal muscle damage.     

Neuroprotective effects of MK 801 and hypothermia used alone and in combination in hypoxic-ischemic brain injury in neonatal rats.

Although accumulating evidence suggests that increased extracellular glutamate concentrations may play an important role in hypoxic-ischemic brain injury, dopamine and other catecholamines also seem to be involved. The N-methyl-D-aspartate receptor antagonist MK 801 and moderate hypothermia (32-34 degrees C) are each known to be neuroprotective, but their combined effect on the release and metabolism of neurotransmitters is unknown. Seven-day-old pups (n: 150) underwent right common carotid artery ligation to induce hemispheric ischemia, and were later subjected to 120 minutes of hypoxia with 8% O2 and 92% N2O. Half the rats (Group I, n: 74) were subjected to normothermic conditions throughout the hypoxic period. Moderate hypothermia (30-32 degrees C) was induced in the other pups (Group II, n: 76) immediately after artery occlusion, and was maintained throughout the hypoxic period. Prior to inducing hypoxia, half of the rats in each group (Groups IA and IIA) received vehicle solution (0.9% NaCI) and the other rats (Groups IB and IIB) received MK 801 (0.5 mg/kg) subcutaneously at 45 and 120 minutes after occlusion. Intracerebral temperature was recorded every 15 minutes after occlusion. Infarct area (n: 40) was calculated after staining with 2% 2,3,5 triphenyltetrazolium chloride. Neuronal damage (n: 42) was assessed by quantifying CA1-CA3 neuronal loss at five hippocampal levels. The amount of damage to the monoamine system of the corpus striatum was determined based on the dopamine and 3,4 dihydroxyphenylacetic acid levels in the corpus striatum in both hemispheres (n: 46), as measured by high-pressure liquid chromatography and compared with normal control pups' values (n: 10). The normothermia/saline-treated pups had significantly larger infarct areas than the MK 801 only, hypothermia only, or MK 801/hypothermia combination groups. Neuropathological examination and striatal tissue monoamine data also confirmed marked neuronal damage in this group. Although MK 801 treatment alone resulted in significantly smaller infarct area and less tissue damage than was observed in the normothermia/saline-treated group, the moderate hypothermia and the MK 801/hypothermia combination treatment groups both exhibited better neuronal protection, especially in the corpus striatum. The rats that received combined treatment also had a significantly lower mortality rate.     

Progenitor cell injury after irradiation to the developing brain can be modulated by mild hypothermia or hyperthermia

Ionizing radiation induced acute cell death in the dentate gyrus subgranular zone (SGZ) and the subventricular zone (SVZ). Hypomyelination was also observed. The effects of mild hypothermia and hyperthermia for 4 h after irradiation (IR) were studied in postnatal day 9 rats. One hemisphere was irradiated with a single dose of 8 Gy and animals were randomized to normothermia (rectal temperature 36 degrees C for 4 h), hypothermia (32 degrees C for 4 h) or hyperthermia (39 degrees C for 4 h). Cellular injury, e.g. chromatin condensation and nitrotyrosine formation, appeared to proceed faster when the body temperature was higher. Caspase-3 activation was more pronounced in the hyperthermia group and nuclear translocation of p53 was less pronounced in the hypothermia group 6 h after IR. In the SVZ the loss of nestin-positive progenitors was more pronounced (48%) and the size was smaller (45%) in the hyperthermia group 7 days post-IR. Myelination was not different after hypo- or hyperthermia. This is the first report to demonstrate that hypothermia may be beneficial and that hyperthermia may aggravate the adverse side-effects after radiation therapy to the developing brain.     

Differential cerebral hypothermia

Differential cerebral hypothermia was induced in these experiments by isolating the cerebral circulation in the halothane-anesthetized goat. The brain was perfused through isolated cerebral branches of the internal maxillary artery using a height-adjusted reservoir system which provided a constant inflow pressure. Cerebral blood flow (CBF) and cerebral O₂ metabolic rate (CMRO₂) were measured continuously as brain temperatures were decreased from 38 to 28, 18 and 8 °C and during rewarming. Arterial blood gases were maintained constant. During hypothermia CBF decreased at brain temperatures of 28 °C and did decrease further at 18 or 8 °C. CMRO₂ decreased linearly from 38 to 8 °C and was 7% control levels at 8 °C. CBF and CMRO₂ returned to control levels upon rewarming. Cerebral lactate metabolism did not change significantly during hypothermia or rewarming. Evoked cortical potentials were abolished at 8 °C but recovered upon rewarming. These results indicate that if adequate brain perfusion is maintained during hypothermia and rewarming, recovery of CBF, metabolism, and brain neural activity can be obtained.     

Metabolic demand,oxygen supply,and critical temperatures in the Antarctic bivalve Laternula elliptica

Oxygen consumption (Mo(2)), heartbeat rate and form, and circulating hemolymph oxygen content were measured in relation to temperature in the large Antarctic infaunal bivalve Laternula elliptica. After elevations in temperature from 0 degrees to 3 degrees, 6 degrees, and then 9 degrees C, Mo(2) and heartbeat rate rose to new levels, whereas maximum circulating hemolymph oxygen content fell. At 0 degrees C, Mo(2) was 19.6 micromol O(2) h(-1) for a standard animal of 2-g tissue ash-free dry mass, which equates to a 8.95-g tissue dry-mass or 58.4-g tissue wet-mass animal. Elevation of metabolism following temperature change had acute Q(10) values between 4.1 and 5, whereas acclimated figures declined from 3.4 (between 0 degrees and 3 degrees C) to 2.2 (3 degrees -6 degrees C) and 1.9 (6 degrees -9 degrees C). Heartbeat rate showed no acclimation following temperature elevations, with Q(10) values of 3.9, 3.2, and 4.3, respectively. Circulating hemolymph oxygen content declined from 0 degrees to 3 degrees and 6 degrees C but stayed at a constant Po(2) (73-78 mmHg) and constant proportion ( approximately 50%) of the oxygen content of the ambient water. At 9 degrees C, Mo(2) and heartbeat rate both peaked at values 3.3 times those measured at 0 degrees C, which may indicate aerobic scope in this species. After these peaks, both measures declined rapidly over the ensuing 5 d to the lowest measured in the study, and the bivalves began to die. Hemolymph oxygen content fell dramatically at 9 degrees C to values between 2% and 12% of ambient water O(2) content and had a maximum Po(2) of around 20 mmHg. These data indicate an experimental upper lethal temperature of 9 degrees C and a critical temperature, where a long-term switch to anaerobic metabolism probably occurs, of around 6 degrees C for L. elliptica. Concurrent measures of mitochondrial function in the same species had indicated strong thermal sensitivity in proton leakage costs, and our data support the hypothesis that as temperature rises, mitochondrial maintenance costs rapidly outstrip oxygen supply mechanisms in cold stenothermal marine species.     

Effect of hypothermia on radiosensitization

Hypothermia reduces metabolism and oxygen utilization by tissues. If the blood supply to a solid tumour can be maintained at a sufficient level, the hypoxic fraction of tumour cells may be reduced and radiosensitivity increased. This may be achieved if hyperbaric oxygen is used in combination with the hypothermia. The blood supply and oxygen tension have been measured in C3H mouse mammary tumours under hypothermia and hyperbaric oxygen, and the enhancement of radiosensitivity by hyperbaric oxygen has been estimated in mice irradiated at different temperatures with and without anaesthesia. Measurement of xenon-133 clearance showed that the blood supply of a tumour tended to increase when anaesthetized mice became hypothermic. Oxygen cathode data showed that the oxygen tension tended to be relatively higher in tumours and lower in subcutaneous tissue when mice exposed to hyperbaric oxygen became hypothermic under anaesthesia. Hyperbaric oxygen enhanced the radiation response of the tumour in terms of an increase in regrowth delay by a factor of 1.7 when the mice had been anaesthetized, whether or not they became hypothermic. A lower factor of 1.4 was obtained without anaesthesia although induced hypothermia increased the response to a small extent. We conclude that anaesthesia and hypothermia affect oxygen metabolism in tumours by different mechanisms.     

Dynamics of free amino acids in rat brain tissue during hypothermia

A comparative study is conducted for the effect of one-, three- and six-hour artificial deep (20-19 degrees C) hypothermia on the content of free amino acids in the blood serum, tissue, nuclei and mitochondria of the rat brain. It is found out that the content is the highest in the blood serum after a three-hour cooling. In the brain tissue the amount of amino acids lowers, especially under conditions of a six-hour hypothermia. In nuclei a three-hour effect of hypothermia decreases sharply the content of free amino acids and the six-hour one increases the amount of most of them. Under hypothermia the content of nearly all amino acids in the brain mitochondria is higher than in the intact animals.     

Tissue-specific extravasation of albumin-bound Evans blue in hypothermic and rewarmed rats

The effects of hypothermia and rewarming on endothelial integrity were examined in intestines, kidney, heart, gastrocnemius muscle, liver, spleen, and brain by measuring albumin-bound Evans blue loss from the vasculature. Ten groups of twelve rats, normothermic with no pentobarbital, normothermic sampled at 2, 3, or 4 h after pentobarbital, hypothermic to 20, 25, or 30 degrees C, and rewarmed from 20, 25, or 30 degrees C, were cooled in copper coils through which water circulated. Hypothermic rats were cooled to the desired core temperature and maintained there for 1 h; rewarmed rats were cooled to the same core temperatures, maintained there for 1 h, and then rewarmed. Following Evans blue administration, animals were euthanized with methoxyflurane, tissues removed, and Evans blue extracted. Because hypothermia and rewarming significantly decrease blood flow, organ-specific flow rates for hypothermic and rewarmed tissues were used to predict extravasation. Hypothermia decreased extravasation in tissues with continuous endothelium (brain, muscle) and increased it in tissues with discontinuous endothelium (liver, lung, spleen). All tissues exhibited significant (p < 0.05) differences from normothermic controls. These differences are attributed to a combination of anesthesia, flow, and (or) change in endothelial permeability, suggesting that appropriate choice of organ and temperature would facilitate testing pharmacological means of promoting return to normal perfusion.     

Urban hypothermia and hyperglycemia in the elderly

From December 1993 to March 1999 we treated 18 elderly patients aged 66-87 years, suffering from urban hypothermia: 11 women and 7 men. Ten patients suffered from moderate hypothermia (rectal temperature 32-35 degrees C), and eight from severe hypothermia (rectal temperature < 32 degrees C). Regarding consciousness, in the group suffering from moderate hypothermia, 3 were somnolent and 6 in various degrees of comatose states. In the group suffering from severe hypothermia, 3 patients were somnolent or soporous and 5 in comatose states of various degrees. Values of arterial blood pressure in the group with moderate hypothermia was normal in one, in 3 arterial hypotension was observed and 6 were in a state of shock. In the group with severe hypothermia, 3 presented arterial hypotension and 5 were in a state of shock. In the group with moderate hypothermia the blood glucose level was elevated in six: 9.3-10.2-10.7-17.9-21.3-99.0, and in one patient the blood glucose level was low: 2.3 mmol/L, in correlation with hypoglycemic coma. In the group with severe hypothermia in all eight patients the values were elevated: 6.7-7.4-7.6-8.7-9.1-11.2-12.4-17.9 mmol/L.     

Differential effects of venous stasis and arterial insufficiency on tissue oxygenation in myocutaneous island flaps: an experimental study in pigs.

The supply, consumption, and tissue tension of oxygen were studied in experimental bilateral myocutaneous island flaps in five control pigs and in eight pigs during progressive 1-hour intervals of flap ischemia. Progressive ischemia was obtained by partial to complete clamping of the artery in one flap, producing arterial insufficiency, and simultaneous clamping of the vein in the other flap, producing venous stasis. Blood flow was reduced to 50, 25, and 0 percent of baseline. In the arterial insufficiency flaps, the oxygen tension in subcutaneous tissue, muscle, and venous outflow was significantly reduced once blood flow was reduced to 50 percent of baseline. Oxygen consumption during partial vessel occlusion was lower in the venous stasis flaps than in the arterial insufficiency flaps when blood flow was reduced to 25 percent of baseline, suggesting either that cellular metabolism is reduced in the venous stasis flaps or that the oxygen which is delivered is unavailable for the cells. Increased presence of tissue fluid in the venous stasis flap inhibits the diffusion of oxygen through the interstitial tissue, and this may explain the lower oxygen consumption. During 3 hours of reperfusion, increased blood flow was observed in the arterial insufficiency flaps, whereas blood flow in the venous stasis flaps was sluggish. The arterial insufficiency flaps recovered more rapidly than the venous stasis flaps during the first hour of reperfusion, judged by the rate of increase in oxygen tension and the higher venous oxygen tension. Oxygen tension increased more rapidly in muscle than in subcutaneous tissue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intensity of respiration and the metabolism of phospholipids in isolated brain tissues of rats at various temperatures in the presence of KCN]

The intensity of oxygen consumption, as well as phospholipid metabolism of minced rat brain tissue were studied at different temperature of the incubation media (37 degrees, 32 degrees and 27 degrees C) without cyanide and in the media containing KCN (0.5 and 1.0 mM). As shown, both parameters depended directly upon the incubation temperature within the range of 27 degrees-37 degrees. KCN inhibited both processes, but depression of phospholipid metabolism was more expressed. These data suggest that under conditions of cyanide poisoning phospholipid metabolism depends both on the toxic effect of KCN directly and on the temperature, whose reduction reinforces this effect.     

Time course of cytokine, corticosterone, and tissue injury responses in mice during heat strain recovery.

Elevated circulating cytokines are observed in heatstroke patients, suggesting a role for these substances in the pathophysiological responses of this syndrome. Typically, cytokines are determined at end-stage heatstroke such that changes throughout progression of the syndrome are poorly understood. We hypothesized that the cytokine milieu changes during heatstroke progression, correlating with thermoregulatory, hemodynamic, and tissue injury responses to heat exposure in the mouse. We determined plasma IL-1alpha, IL-1beta, IL-2, IL-4, IL-6, IL-10, IL-12p40, IL-12p70, IFN-gamma, macrophage inflammatory protein-1alpha, TNF-alpha, corticosterone, glucose, hematocrit, and tissue injury during 24 h of recovery. Mice were exposed to ambient temperature of 39.5 +/- 0.2 degrees C, without food and water, until maximum core temperature (T(c,Max)) of 42.7 degrees C was attained. During recovery, mice displayed hypothermia (29.3 +/- 0.4 degrees C) and a feverlike elevation at 24 h (control = 36.2 +/- 0.3 degrees C vs. heat stressed = 37.8 +/- 0.3 degrees C). Dehydration ( approximately 10%) and hypoglycemia ( approximately 65-75% reduction) occurred from T(c,Max) to hypothermia. IL-1alpha, IL-2, IL-4, IL-12p70, IFN-gamma, TNF-alpha, and macrophage inflammatory protein-1alpha were undetectable. IL-12p40 was elevated at T(c,Max), whereas IL-1beta, IL-6, and IL-10 inversely correlated with core temperature, showing maximum production at hypothermia. IL-6 was elevated, whereas IL-12p40 levels were decreased below baseline at 24 h. Corticosterone positively correlated with IL-6, increasing from T(c,Max) to hypothermia, with recovery to baseline by 24 h. Tissue lesions were observed in duodenum, spleen, and kidney at T(c,Max), hypothermia, and 24 h, respectively. These data suggest that the cytokine milieu changes during heat strain recovery with similarities between findings in mice and those described for human heatstroke, supporting the application of our model to the study of cytokine responses in vivo.