Endocrine regulation of carbohydrate metabolism in hypometabolic animals

Experimental hypothermia and natural hibernation are two forms of hypometabolism with recognized physiological changes, including depression of endocrine and metabolic functions. To better understand functional changes, helox (i.e., helium and oxygen (80:20) mixtures) and low ambient temperatures have been used to induce hypothermia in hamsters and rats. Both clinical and biological survival, i.e., survival without recovery and survival with recovery from hypothermia, respectively, are related to depth and length of hypothermia. In the rat, body temperatures of 15 degrees C for periods greater than 6-10 h greatly restrict biological survival. The role of glucocorticoids in enhancing thermogenic capacity of rats was assessed using triamcinolone [correction of triamcinalone] acetonide. In the hamster, treatment with cortisone acetate prolonged both clinical and biological survival. Hypothermic hamsters continue utilizing circulating glucose until they become hypoglycemic and die. Hypothermic rats do not utilize glucose and respond with a significant hypoinsulinema. The role of endocrines in the regulation of carbohydrate homeostasis and metabolism differs in hibernation and hypothermia. Glucocorticoids influence the hypothermic response in both species, specifically by prolonging induction of hypothermia in rats and by prolonging survival in hypothermic hamsters.     

Systemic Administration of the TRPV3 Ion Channel Agonist Carvacrol Induces Hypothermia in Conscious Rodents

Therapeutic hypothermia is a promising new strategy for neuroprotection. However, the methods for safe and effective hypothermia induction in conscious patients are lacking. The current study explored the Transient Receptor Potential Vanilloid 3 (TRPV3) channel activation by the agonist carvacrol as a potential hypothermic strategy. It was found that carvacrol lowers core temperature after intraperitoneal and intravenous administration in mice and rats. However, the hypothermic effect at safe doses was modest, while higher intravenous doses of carvacrol induced a pronounced drop in blood pressure and substantial toxicity. Experiments on the mechanism of the hypothermic effect in mice revealed that it was associated with a decrease in whole-body heat generation, but not with a change in cold-seeking behaviors. In addition, the hypothermic effect was lost at cold ambient temperature. Our findings suggest that although TRPV3 agonism induces hypothermia in rodents, it may have a limited potential as a novel pharmacological method for induction of hypothermia in conscious patients due to suboptimal effectiveness and high toxicity.     

The hypothermic hamster brain: Its water and electrolyte content and perfusion

The data suggest that cold swelling of the brain does not occur in hypothermic hamsters for up to 48 hr or in the hypothermic rat for 2 hr. It may be possible that the adaptation of the Na⁺,K⁺-activated ATPase system as well as lipid changes occurs during the 6- to 8-hr induction period of hypothermia in the hamster. The absence of swelling in the rat, a species which does not hibernate, may be due to both the lack of hypercapnia and the brevity of the hypothermic period. It is noteworthy that in the hamster the distribution of cardiac output to the brain and the respiratory centers of the brain system is unaffected by hypothermia of up to 18 hr. Actual perfusion is, however, dramatically reduced. The data suggest that the helium-cold hypothermic hamster retains the ability to maintain solute gradients in hypothermia, and that hypothermic death is not due to an increase in cerebral water content or in the percentage of cardiac output received by the brain.     

Glucose, glycogen, and insulin responses in the hypothermic rat

The rat appears to be unable to utilize glucose during hypothermia. The objective of this study was to examine carbohydrate homeostasis during induction, hypothermia, and rewarming phases. Groups of normothermic animals were euthanized to serve as time controls for comparison. Hypothermia (15 degrees C) was produced by exposure to helox (80% helium:20% oxygen) at 0 +/- 1 degree C. Hyperglycemia was noted during the induction process (169 +/- 8 in control vs 326 +/- 49 mg/dl). Serum glucose increased further during 4 hr of hypothermia, but following rewarming (Tre of 33 +/- 1 degrees C) was reduced (153 +/- 16 mg/dl) significantly (P less than 0.05). Serum insulin was depressed during hypothermic induction (from 48 +/- 4 in controls to 19 +/- 3 microU/ml in hypothermic rats) and increased only slightly during the arousal process, remaining significantly lower than in normothermic subjects. Initial hepatic, skeletal muscle, and cardiac glycogen concentrations were reduced 34, 68, and 75%, respectively, during hypothermic induction. While liver glycogen decreased further during 4 hr of hypothermia, skeletal and cardiac stores increased markedly. During rewarming, hepatic glycogen was markedly decreased, while skeletal and cardiac stores were maintained. These data suggest that hyperglycemia in the hypothermic rat can be accounted for by glycogenolysis and hypoinsulinemia. In addition, this study indicates repletion of skeletal and cardiac muscle glycogen during maintained hypothermia and sparing of muscle glycogen during rewarming.     

Central A1-receptor activation associated with onset of torpor protects the heart against low temperature in the Syrian hamster

Body temperature drops dramatically during hibernation, but the heart retains the ability to contract and is resistant to induction of arrhythmia. Although adaptive changes in the heart prior to hibernation may be involved in the cold-resistant property, it remains unclear whether these changes are sufficient for maintaining cardiac pulsatility under an extreme hypothermic condition. We forcibly induced hypothermia in Syrian hamsters by pentobarbital anesthesia combined with cooling of the animals. This allows reproduction of a hypothermic condition in the absence of possible hibernation-specific reactions. Unlike hypothermia in natural hibernation, the forced induction of hypothermia caused atrioventricular block. Furthermore, J-waves, which are typically observed during hypothermia in nonhibernators, were recorded on an ECG. The origin of the J-wave seemed to be related to irreversible injury of the myocardium, because J-waves remained after recovery of body temperature. An abnormal ECG was also found when hypothermia was induced in hamsters that were well adapted to a cold and darkened environment or hamsters that had already experienced hibernation. These results suggest that acclimatization prior to hibernation does not have a crucial effect at least on acquisition of cardiac resistance to low temperature. In contrast, an abnormal ECG was not observed in the case of hypothermia induced by central administration of an adenosine A1-receptor agonist and subsequent cooling, confirming the importance of the adenosine system for inducing hibernation. Our results suggest that some specific mechanisms, which may be driven by a central adenosine system, operate for maintaining the proper cardiac pulsatility under extreme hypothermia.     

The costs of being cool: a dynamic model of nocturnal hypothermia by small food-caching birds in winter

Many birds could expend substantially less energy at night by using hypothermia, but generally do not. This suggests that the potential savings are offset by costs; one of these costs is presumed to be the risk of predation at night. If this assumption is correct, a bird will face one of two tradeoffs: (1) it can avoid the cost of hypothermia by gaining fat to decrease the risk of starvation, but this increases energetic costs of fat maintenance and risk of diurnal predation, or (2) it can maintain lower fat reserves and use hypothermia at night, but this option increases the risk of nocturnal predation. We used a dynamic model to investigate these trade-offs and how the use of nocturnal hypothermia changes energy management tactics in food-caching birds. Our model predicted that: (i) optimal daily routines of fat reserves, feeding rate, food caching, and cache retrieval should be similar in hypothermic and non-hypothermic birds; (ii) low fat reserves, small cache size, low ambient temperature, and high variability in foraging success favor increased use of hypothermia; (iii) the effect of ambient temperature on the use of hypothermia is especially important at higher levels of variance in foraging success; (iv) hypothermic birds are predicted to have lower mass at dusk than non-hypothermic individuals while their morning mass should be more similar. Many of these predictions have been supported by empirical data. Also, survival rates are predicted to be higher for birds using hypothermia, especially in the most severe environmental conditions. This is the first attempt to evaluate the role of cache maintenance and variance in foraging success in the use of hypothermia. This is also the first discussion of the relationship between behavior hypothermia and diurnal patterns of energy management.     

Comparative physiological and biochemical aspects of hypothermia as a model for hibernation

It is obvious that research is far from the last chapter in developing a model for natural hibernation. The relationships and comparative mechanisms for thermogenesis and survival in hibernation and experimental hypothermia are still unclear. Yet, two primary areas appear to be most promising, namely, the control of thermogenesis via the glucocorticoids and the specific role of the central nervous system (CNS) in survival of hypothermic subjects and arousal of hibernating subjects. Although there have been several approaches to understanding the role of the CNS in terms of circulation, integrity of the blood-brain barrier (BBB) system, and CNS sites of activity, it may appear that more questions have been raised than have been answered. However, a more optimistic view can also be taken. The development of a laboratory model, using experimental hypothermia for natural hibernation, is progressing. This view is justified in terms of results from the use of glucocorticoids in metabolic regulation of available carbohydrates, i.e., available glucose in hypothermia, and the continued promising parallel studies of physiological and biochemical integrity of areas of the CNS in hypothermic and hibernating subjects.     

Glucocorticoids and hypothermic induction and survival in the rat

Glucocorticoids (GC) are important for thermoregulatory responses to low environmental temperatures. Pretreatment of hamsters, which are capable of natural hibernation, with cortisone acetate has been demonstrated to improve carbohydrate homeostasis during hypothermia. The objectives of the current studies were to evaluate the effects of GC pretreatment of a nonhibernator, the rat, on (i) cooling time, (ii) carbohydrate homeostasis (in terms of liver and cardiac glycogen concentrations and plasma glucose concentration), and (iii) duration of survival in hypothermia. In addition, the effects of liver glycogen depletion on cooling times and survival were examined. Hypothermia was induced in rats by exposure to a helium:oxygen (80:20, Helox) atmosphere at 0 degree C. Pretreatment of rats with triamcinolone acetonide (1.5 mg/kg/day, sc, 48, 24, and 1 hr prior to induction) significantly (P less than 0.05) lengthened induction time, while fasting was associated with a significant decrement (25%). While liver and cardiac glycogen levels in control and GC-treated rats fell approximately 45% during cooling, this reduction occurred over a significantly greater period of time in treated rats and suggests a sparing of glycogen or increased capacity for its production in response to GC. Glycogen utilization was accompanied by a hyperglycemia in control, GC-treated, and fasted groups. Survival in hypothermia at a rectal temperature of 14-15 degrees C in GC-treated (9.5 +/- 1.2 hr) and fasted (10.9 +/- 0.9 hr) rats was not significantly different from control (10.5 +/- 1.1 hr) values. These findings suggest that treatment with GC can increase the thermogenic capacity of the rat (as evidenced by an increased induction time) and promote carbohydrate homeostasis, but does not contribute to an enhancement of survival in the hypothermic nonhibernator.     

Effects of prostaglandin antagonist SC-19220 on body temperature and on hyperthermic responses to prostaglandin E-1 and leukocytic pyrogen in the cat.

Intravenous injection of SC-19220 (3-9 mg/kg) caused dose-related hypothermic responses in cats. Repeated administration of SC-19220 resulted in tolerance to its hypothermic action. During SC-19220-induced hypothermia, the hyperthermic activity of both prostaglandin E-1 and leukocytic pyrogen was reduced or abolished. Neither prostaglandin E-1 nor leukocytic pyrogen was antagonized when given shortly after recovery from SC-19220-induced hypothermia or by doses of SC-19220 which did not cause hypothermia. Although these results may indicate a role of prostaglandins in normal physiological thermoregulation, it is also possible that production of hypothermia by SC-19220 is unrelated to prostaglandin antagonism.     

Factors influencing survival of mammalian cells exposed to hypothermia. V. Effects of hepes, free radicals, and H2O2 under light and dark conditions

Cytotoxicity resulting from the interaction of fluorescent light from a flow hood with Hepes-buffered cell culture medium at room temperature was demonstrated. Toxicity was prevented by keeping both cells (V79 Chinese hamster) and medium shielded from direct fluorescent light ("dark conditions") or by supplementing the medium with 10 micrograms/ml catalase; this suggests that extracellular hydrogen peroxide is a major cause of the lethal effect under "lighted conditions." No sensitization resulted from the exposure of cells in a sodium bicarbonate (SBC)-buffered medium to fluorescent light, nor in a catalase supplemented SBC-buffered medium. The Hepes/light reaction during routine cell manipulations presensitized cells to hypothermia damage in the dark with the presensitization being more severe for 5 than for 10 degrees C hypothermic exposure. Presensitization was prevented by performing the complete experiment under dark conditions or by supplementing the medium with 10 micrograms/ml catalase. However, catalase did not improve the hypothermic survival when experiments were performed under dark conditions. Hence, 10 micrograms/ml catalase does not protect cells from hypothermic (5 and 10 degrees C) damage per se, but rather from Hepes/light sublethal damage which interacts with hypothermic sublethal damage to result in lethal lesions. Additionally, under dark conditions, superoxide dismutase (SOD), allopurinol, catalase plus SOD, DMSO, or mannitol did not improve survival when present during hypothermic storage, suggesting that extracellular superoxide anion, hydrogen peroxide, or hydroxyl radicals are not the cause of cell killing under conditions of pure hypothermia uncomplicated by prehypothermic ischemia or hypoxia.     

Effects of prostaglandin antagonist SC-19220 on body temperature and on hyperthermic responses to prostaglandin E1 and leukocytic pyrogen in the cat

Intravenous injection of SC-19220 (3–9 mg/kg) caused dose-related hypothermic responses in cats. Repeated administration of SC-19220 resulted in tolerance to its hypothermic action. During SC-19220-induced hypothermia, the hyperthermic activity of both prostaglandin E₁ and leukocytic pyrogen was reduced or abolished. Neither prostaglandin E₁ nor leukocytic pyrogen was antagonized when given shortly after recovery from SC-19220-induced hypothermia or by doses of SC-19220 which did not cause hypothermia. Although these results may indicate a role of prostaglandins in normal physiological thermoregulation, it is also possible that production of hypothermia by SC-19220 is unrelated to prostaglandin antagonism.     

Effects of hypothermia and re-warming on the inflammatory response in a murine multiple hit model of trauma

INTRODUCTION: Although, hypothermia is a frequent event after trauma, it is unclear whether its beneficial or detrimental effects are more important. This study aims to quantify the effects of hypothermia and re-warming on the inflammatory response after fracture/hemorrhage and subsequent fracture stabilization with resuscitation. MATERIALS AND METHODS: Eighty-one male C57Bl/6 mice (aged 8-10 weeks, weighing 22.0+/-3.0 g) underwent femoral fracture and hemorrhage followed by resuscitation and splint fixation of the fracture. Animals were sacrificed 3h after induction of hemorrhage and fracture. Besides a sham group (n=6), four experimental groups were created: A: normothermia (n=12), B: hypothermia after trauma (n=21), C: re-warming after resuscitation and before stabilization (n=21), and D: hypothermia before trauma (n=21). Groups B-D were further subdivided into three subgroups according to the degree of hypothermia (subgroup 1: 35-33 degrees C, subgroup 2: 32.9-30.0 degrees C, and subgroup 3: 29.9-27.0 degrees C). Plasma cytokine (TNF-alpha, IL-6, and IL-10) and chemokine (MCP-1) concentrations were determined by ELISA, pulmonary permeability changes were quantified, and histological analysis of lung and liver tissues was performed. RESULTS: Normothermia resulted in a significantly increased early mortality rate. A significantly increased pro-inflammatory and decreased anti-inflammatory responses were also observed in normothermia as compared to hypothermia. The extent of these changes was most pronounced in the severe hypothermic group. Re-warming after mild hypothermia resulted in a pro-inflammatory response comparable to normothermia. CONCLUSION: Hypothermia has a beneficial effect on early survival after trauma, which appears to be independent of the level of hypothermia and re-warming. Re-warming, however, enhanced the pro-inflammatory response. Further studies with a longer posttraumatic observation period are required to investigate the long term effects of the hypothermia and re-warming-induced changes on the pro- and anti-inflammatory responses.     

Model‐based investigation of intracellular processes determining antibody Fc‐glycosylation under mild hypothermia

Despite the positive effects of mild hypothermic conditions on monoclonal antibody (mAb) productivity (q_mAb) during mammalian cell culture, the impact of reduced culture temperature on mAb Fc‐glycosylation and the mechanism behind changes in the glycan composition are not fully established. The lack of knowledge about the regulation of dynamic intracellular processes under mild hypothermia restricts bioprocess optimization. To address this issue, a mathematical model that quantitatively describes Chinese hamster ovary (CHO) cell behavior and metabolism, mAb synthesis and mAb N‐linked glycosylation profile before and after the induction of mild hypothermia is constructed. Results from this study show that the model is capable of representing experimental results well in all of the aspects mentioned above, including the N‐linked glycosylation profile of mAb produced under mild hypothermia. Most importantly, comparison between model simulation results for different culture temperatures suggests the reduced rates of nucleotide sugar donor production and galactosyltransferase (GalT) expression to be critical contributing factors that determine the variation in Fc‐glycan profiles between physiological and mild hypothermic conditions in stable CHO transfectants. This is then confirmed using experimental measurements of GalT expression levels, thereby closing the loop between the experimental and the computational system. The identification of bottlenecks within CHO cell metabolism under mild hypothermic conditions will aid bioprocess optimization, for example, by tailoring feeding strategies to improve NSD production, or manipulating the expression of specific glycosyltransferases through cell line engineering. Biotechnol. Bioeng. 2017;114: 1570–1582. © 2016 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals Inc.     

Effects of chemically- and environmentally-induced hypothermia on micronucleus induction in rats

We investigated micronucleus induction in rats treated with chlorpromazine and reserpine, drugs that induce hypothermia. We administered chlorpromazine (31.3--250mg/kg) or reserpine (500--2000 mg/kg) intraperitoneally and measured temperature rectally. Chlorpromazine at 62.5-250mg/kg and reserpine at all doses significantly decreased rectal temperature, although the hypothermic response was weaker than previously reported in mice. Only chlorpromazine at 250mg/kg decreased rectal temperature transiently to <33 degrees C for 20h and induced a statistically significant increase in micronucleated polychromatic erythrocyte frequency. When rats treated with reserpine at 500mg/kg were exposed to an environmental temperature of 16 degrees C for 6, 12, or 24h to keep their body temperature under 33 degrees C, only the 24h treatment group significantly induced micronuclei. In addition, relatively large micronuclei (diameter of micronucleus> or = 1/4 diameter of cytoplasm) accounted for 33.0% of the induced micronuclei, suggesting that hypothermia affected the mitotic apparatus. The hypothermic response to chlorpromazine and reserpine was weaker in rats than in mice, and it was correspondingly more difficult to induce micronuclei in rats with those drugs.     

Nocturnal hypothermia impairs flight ability in birds: a cost of being cool

Many birds use regulated drops in night-time body temperature (T_b) to conserve energy critical to winter survival. However, a significant degree of hypothermia may limit a bird''s ability to respond to predatory attack. Despite this likely energy–predation trade-off, the behavioural costs of avian hypothermia have yet to be examined. We thus monitored the nocturnal hypothermia of mourning doves (Zenaida macroura) in a laboratory setting in response to food deprivation. Nocturnal flight tests were used to quantify the flight ability of hypothermic doves. Many hypothermic doves (39% of tests) could not fly while carrying a small weight, but could do so after quickly warming up to typical daytime T_b. Doves that were unable to fly during their first test were more hypothermic than those that could fly, with average T_b reductions of 5.3°C and 3.3°C, respectively, but there was no overall indication of a threshold T_b reduction beyond which doves were consistently incapable of flight. These results suggest that energy-saving hypothermia interferes with avian antipredator behaviour via a reduction in flight ability, likely leading to a trade-off between energy-saving hypothermia and the risk of predation.     

Rewarming of the hypothermic rhesus monkey with electromagnetic radiation

To obtain more detailed information relative to the potential usefulness of using radio frequency (RF) energy in treating hypothermia, anesthetized rhesus monkeys were used in a rewarming study that compared a conventional method (heating pad) with an RF induction coil system. Rectal temperature (Tre) of each subject was monitored, and enzyme and isoenzyme levels were determined from blood samples collected before, during, and up to 48 h after hypothermia in order to assess the effects of each rewarming method. The previously observed postprocedure rise in serum enzymes (most visible at 24 h) was again seen, with no statistically significant difference in the time course of serum enzyme levels between the two treatments for comparable durations of hypothermia. To test the limits of the ability of the RF induction coil system, successively more severe hypothermia was induced in the subjects to the point of cardiovascular collapse (Tre less than 20 degrees C); RF energy was successful in resuscitating the profoundly hypothermic subjects without discernible harmful effects.     

Heart rate variability and electrocardiogram waveform as predictors of morbidity during hypothermia and rewarming in rats

This study examined electrocardiogram (ECG) waveform, heart rate (HR), mean blood pressure (BP), and HR variability as potential autonomic signatures of hypothermia and rewarming. Adult male Sprague-Dawley rats had telemetry transmitters surgically implanted, and 2 weeks were allowed for recovery prior to induction of hypothermia. Rats were lightly anesthetized (sodium pentobarbital, 35 mg/kg i.p.) and placed in a coil of copper tubing through which temperature-controlled water was circulated. Animals were cooled to a core temperature (Tc) of 20 degrees C, maintained there for 30 min, and then rewarmed. Data (Tc, BP, HR from ECG, and 10-s strips of ECG waveforms) were collected every 5 min throughout hypothermia and rewarming. Both HR and BP declined after initial increases with the drop in HR starting at a higher Tc than the drop in BP (29.6 +/- 2.4 degrees C vs. 27.1 +/- 3.3 degrees C, p < 0.05). Animals that were not successfully rewarmed exhibited a significant (p < 0.05) increase in the normalized standard deviation of interbeat intervals (IBI) throughout cooling compared with animals that were successfully rewarmed. The T wave of the ECG increased in amplitude and area with decreasing Tc. T-wave amplitude and IBI variability show potential as predictors of survival in hypothermic victims.     

The radioprotective effect of hypothermia on the immune and hematopoietic systems in mammals

The functional activity of the synthetic apparatus (parameter alpha) in blood lymphocytes, bone marrow hemopoietic cells, and thymus cells, as well as the total number of blood and bone marrow cells in rats after y-irradiation at a dose of 8 Gy in the conditions of normothermia and hypothermia (16-18 degrees C) with hypoxia-hypercapnia were investigated after 2 h and on days 1 and 4. The recovery processes in blood in both groups of rats after acute X-irradiation at a dose of 7 Gy for 36 days were analyzed too. Under hypothermia, on days 1-4 after acute gamma-irradiation, a decrease in the synthetic activity in remaining cells and devastation in the hemopoietic system were pronounced to a lesser degree. After X-irradiation, the restoration of synthetic activity in blood lymphocytes was shown to begin earlier and to finish faster in "hypothermic" rats as compared with the animals irradiated in the state of normothermia. The survival of "hypothermic" rats was 100% as compared with 30% in "normothermic" animals. Thus, the data show that hypothermia exerts a radioprotective effect on the cells of the immune and hemopoietic systems, thus enhancing the resistance of the organism to radiation.     

Thermic response of selective muscarinic agonists and antagonists in rat

Effect of some selective agonists and antagonists of cholinergic M receptor subtypes on rectal temperature was investigated in rats at an ambient temperature of 25 degrees +/- 2 degrees C. Centrally administered acetylcholine (ACh) induced transient hypothermia, whereas the muscarinic M1 receptor agonists, arecholine (ip) and McN-A-343 (McN) (icv), induced sustained and dose-related hypothermia. However, the nonspecific muscarinic receptor agonist, oxotremorine, and physostigmine, induced hypothermia at a lower dose and hyperthermia, accompanied by tremors, at higher doses. The muscarinic M2 receptor agonist, carbachol (icv) also produced a dose-related dual effect, hyperthermia and hypothermia being induced by the lower and higher doses, respectively. The M1 receptor antagonists, scopolamine (ip) and pirenzepine (icv), induced hyperthermia, whereas the M2 receptor antagonists, gallamine (icv) and AF-DX 116 (AFDX) (ip), produced hypothermia. The hypothermic effects of ACh. arecholine, McN, physostigmine, oxotremorine and carbachol were attenuated by scopolamine and pirenzepine. However, although scopolamine also inhibited the hyperthermic and tremorogenic effects of the higher dose of oxotremorine, it had a synergistic effect with the hyperthermia-inducing higher dose of physostigmine. AFDX attenuated the hyperthermic effect of the lower dose of carbachol, indicating that it was M2 receptor-mediated. Hemicholinium, an ACh synthesis inhibitor, had a transient hypothermic effect followed by slight hyperthermia. However, it markedly antagonized the hypothermic effects of gallamine and AFDX, indicating that their effects were dependent upon the availability of neuronal ACh. The results indicate that cholinergic hypothermia is a function of central muscarinic M1 receptors, with the M2 receptors serving as automodulators.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of insulin and beta-adrenergic blockade on certain indicators of carbohydrate metabolism in the blood and tissues of rats during short-lasting hypothermia

Administration of insulin 1 i.u./100 g of body weight to hypothermic rats causes a fall of glucose and lactate levels in the serum and a rise in myocardial glycogen level in relation to the group of control rats kept at room temperature and to the group of rats subjected only to hypothermia. Beta-adrenergic blockade (propranolol 0.6-1 mg/kg) caused no changes in the levels of carbohydrate metabolites in the serum of hypothermic rats but raised the myocardial glycogen level by 42% in relation to the animals subjected only to hypothermia. Simultaneous administration of both these agents during hypothermia produces a fall of the serum levels of glucose and pyruvate with a rise in the level of lactate, and raises the glycogen level in the myocardium (by about 161%) and in the skeletal muscle (by 54%) in relation to the rats subjected to hypothermia alone. Insulin and/or propranolol fail to prevent glycogen reserve exhaustion in the liver of hypothermic rats which could be due to activation of non-blocked alpha-adrenergic receptors or to the action of yet another glycogenolytic agent, e.g. glucagon, during hypothermia.