Effect of Mild Hypothermia on the Coagulation-Fibrinolysis System and Physiological Anticoagulants after Cardiopulmonary Resuscitation in a Porcine Model

The aim of this study was to evaluate the effect of mild hypothermia on the coagulation-fibrinolysis system and physiological anticoagulants after cardiopulmonary resuscitation (CPR). A total of 20 male Wuzhishan miniature pigs underwent 8 min of untreated ventricular fibrillation and CPR. Of these, 16 were successfully resuscitated and were randomized into the mild hypothermia group (MH, n = 8) or the control normothermia group (CN, n = 8). Mild hypothermia (33°C) was induced intravascularly, and this temperature was maintained for 12 h before pigs were actively rewarmed. The CN group received normothermic post-cardiac arrest (CA) care for 72 h. Four animals were in the sham operation group (SO). Blood samples were taken at baseline, and 0.5, 6, 12, 24, and 72 h after ROSC. Whole-body mild hypothermia impaired blood coagulation during cooling, but attenuated blood coagulation impairment at 72 h after ROSC. Mild hypothermia also increased serum levels of physiological anticoagulants, such as PRO C and AT-III during cooling and after rewarming, decreased EPCR and TFPI levels during cooling but not after rewarming, and inhibited fibrinolysis and platelet activation during cooling and after rewarming. Finally, mild hypothermia did not affect coagulation-fibrinolysis, physiological anticoagulants, or platelet activation during rewarming. Thus, our findings indicate that mild hypothermia exerted an anticoagulant effect during cooling, which may have inhibitory effects on microthrombus formation. Furthermore, mild hypothermia inhibited fibrinolysis and platelet activation during cooling and attenuated blood coagulation impairment after rewarming. Slow rewarming had no obvious adverse effects on blood coagulation.     

Whole-body temperature gradients under surface,perfusion, and combined surface/perfusion hypothermia

Using various methods of hypothermia and halothane-diethyl ether azeotrope anesthesia whole-body temperature gradients were evaluated in 20 adult mongrel dogs. Simultaneous measurements were taken of brain, rectal, esophageal, pharyngeal, liver, jugular vein, shoulder muscle, thigh muscle, and subcutaneous temperatures during (i) surface, (ii) perfusion (slow and rapid cooling), and (iii) combined surface/perfusion methods of hypothermia. Throughout cooling and rewarming core temperature gradients averaged 1.2 °C and during circulatory arrest core temperatures decreased an average of 0.3 °C under pure surface hypothermia. Animals, thermoregulated by extracorporeal methods only, developed larger core temperature gradients during cooling and a significant increase (average = 3.1 °C) was noted in core temperatures during circulatory arrest. This pattern was particularly pronounced during rapid perfusion cooling. Hypothermia induction by combined surface/perfusion, in contrast to pure perfusion methods, resulted in smaller gradients without remarkable increase in core temperature (average = 1.3 °C) during the arrest period. These findings when correlated with the shorter total operating time and ease of operative management and resuscitation lead us to the conclusion that combined surface/ perfusion hypothermia techniques have certain advantages over either pure surface or pure perfusion techniques alone.     

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.     

Plasma catecholamines in rats during rewarming from induced hypothermia

The present study sought to quantitate the levels of plasma catecholamines [norepinephrine (NE), epinephrine (E), and dopamine (DA)] during induction and rewarming from hypothermia. Male rats (317 +/- 8 g) were made hypothermic by exposure to 0.9% halothane at -10 to -15 degrees C while blood pressure (carotid artery), heart rate, and colonic temperature (Tc) were monitored. Anesthesia was discontinued when Tc reached 28 degrees C. Tc continued to fall but was held at 20-20.5 degrees C for 30 min. Rewarming was then initiated by raising ambient temperature to 22 degrees C. Arterial blood samples were taken 1) before cooling, 2) just before rewarming, 3) when Tc reached 22 degrees C during rewarming, and 4) when Tc reached 27 degrees C during rewarming. Plasma was assayed radioenzymatically for catecholamines using both phenylethanolamine-N-methyltransferase and catechol-O-methyltransferase procedures, and hypothermic induction resulted in significant increases in NE, E, and DA above control levels (P less than 0.01). With rewarming to Tc = 22 degrees C, all catecholamines increased above the level observed during hypothermia (P less than 0.01), and NE and DA increased still further (P less than 0.01) when Tc reached 27 degrees C. The levels of plasma catecholamines observed during hypothermia and during the rewarming phase indicate a role of the sympathoadrenal medullary system in the metabolic adjustments associated with hypothermia and recovery. During rewarming, the levels of E and NE attained exceed those at which both substances may be expected to act as circulating hormones.     

Treatment of accidental hypothermia: a prospective clinical study.

A 15-year prospective study was carried out of 44 patients with accidental hypothermia (mean age 60 years) admitted to an intensive therapy unit. The lowest core temperature recorded in each patient ranged from 20.0 to 34.3 degrees C. The precipitating factors were poisoning (by drugs, alcohol, or coal gas) in 25 cases and various illnesses in 19. Rewarming was achieved in 42 patients by applying a radiant heat cradle over the torso, and in two patients by mediastinal irrigation with warmed fluids. Twelve patients died, but only two during the period of rewarming. Thus rewarming may be consistently and safely achieved irrespective of the cause of hypothermia, and normal body temperature may be regained as rapidly as is compatible with adequate tissue perfusion and oxygenation. Surface rewarming of the torso is perhaps the simplest technique available, but internal rewarming procedures may be desirable or essential in the presence of, for example, profound hypothermia, severe hypotension, or ventricular fibrillation. Mortality was attributable to underlying factors or disease and not to hypothermia.     

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.     

Temperature-dependent hysteresis in somatosensory and auditory evoked potentials

Fourteen adult patients undergoing open heart surgery under induced hypothermia had median nerve, short-latency somatosensory evoked potentials (SSEPs) recorded during cooling (from 36°C to 19°C) and subsequent rewarming. Similar data on another group of patients who had brain-stem auditory evoked potentials (BAEPs) were also analyzed. Hypothermia produced increased latencies of the major SSEP and BAEP components and the latencies returned to normal with subsequent warming. The temperature-latency relationship during the cooling phase was significantly different from that during the warming phase. For SSEP components the temperature-latency relationship was linear during cooling and curvilinear during warming, whereas for BAEP it was curvilinear both during cooling and warming. Furthermore, the regression curves were different during the two phases of temperature manipulation, particularly for temperatures below 30°C both for SSEP and BAEP components. At the onset of warming there was an initial exaggerated warming response on the evoked potential (EP) latencies and amplitude of the EP components. The temperature-latency regression curves were uniformly less steep during the warming phase compared to those during cooling. These findings suggest the existence of hysteresis in the relationship between temperature and EP latencies. The latencies at a given temperature below 30°C depend on whether that temperature is reached during cooling or during warming.     

Respiration during hypothermia: effect of rewarming intermediate areas of ventral medulla

We studied respiration (phrenic nerve activity) during progressive hypothermia to as low as 30.5 degrees C in five anesthetized, paralyzed, glomectomized, and vagotomized cats. PCO2 was maintained at a constant level throughout the experiments. We confirmed the results of a previous study (J. P. Kiley, F. L. Eldridge, and D. E. Millhorn, J. Appl. Physiol. 58: 295-312, 1985) in which respiratory minute output decreased progressively with cooling and respiratory frequency decreased markedly. In addition we show that focal rewarming to normal temperature (37.5 degrees C) of the structures in the intermediate areas on the ventral surface of the medulla resulted in a significant reversal of the depressed respiratory minute activity observed with hypothermia. Respiratory frequency, however, was unaffected by intermediate area rewarming. We conclude that the decreased respiratory activity during hypothermia is due to a generalized interference with neural function. A major portion of these effects is due to cooling of the intermediate areas, but the slowing of respiratory frequency appears to be an independent effect.     

Effects of Mild Cold Shock (25°C) Followed by Warming Up at 37°C on the Cellular Stress Response

Temperature variations in cells, tissues and organs may occur in a number of circumstances. We report here that reducing temperature of cells in culture to 25°C for 5 days followed by a rewarming to 37°C affects cell biology and induces a cellular stress response. Cell proliferation was almost arrested during mild hypothermia and not restored upon returning to 37°C. The expression of cold shock genes, CIRBP and RBM3, was increased at 25°C and returned to basal level upon rewarming while that of heat shock protein HSP70 was inversely regulated. An activation of pro-apoptotic pathways was evidenced by FACS analysis and increased Bax/Bcl2 and BclX_S/L ratios. Concomitant increased expression of the autophagosome-associated protein LC3II and AKT phosphorylation suggested a simultaneous activation of autophagy and pro-survival pathways. However, a large proportion of cells were dying 24 hours after rewarming. The occurrence of DNA damage was evidenced by the increased phosphorylation of p53 and H2AX, a hallmark of DNA breaks. The latter process, as well as apoptosis, was strongly reduced by the radical oxygen species (ROS) scavenger, N-acetylcysteine, indicating a causal relationship between ROS, DNA damage and cell death during mild cold shock and rewarming. These data bring new insights into the potential deleterious effects of mild hypothermia and rewarming used in various research and therapeutical fields.     

Effects of sympathetic stimulation during cooling on hypothermic as well as posthypothermic hemodynamic function

This experimental study was performed to explore hemodynamic effects of a moderate dose epinephrine (Epi) during hypothermia and to test the hypothesis whether sympathetic stimulation during cooling affects myocardial function following rewarming. Two groups of male Wistar rats (each, n=7) were cooled to 15 degrees C, maintained at this temperature for 1 h, and then rewarmed. Group 1 received 1 microg/min Epi, i.v., for 1 h during cooling to 28 degrees C, a dose known to elevate cardiac output (CO) by approximately 25% at 37 degrees C. Group 2 served a saline solution control. At 37 degrees C, Epi infusion elevated CO, left ventricular systolic pressure, maximum rate of left ventricle pressure rise, and mean arterial pressure. During cooling to 28 degrees C, these variables, with the exception of mean arterial pressure, decreased in parallel to those in the saline solution group. In contrast, in the Epi group, mean arterial pressure remained increased and total peripheral resistance was significantly elevated at 28 degrees C. Compared with corresponding prehypothermic values, most hemodynamic variables were lowered after 1 h at 15 degrees C in both groups (except for stroke volume). After rewarming, alterations in hemodynamic variables in the Epi-treated group were more prominent than in saline solution controls. Thus, before cooling, continuous Epi infusion predominantly stimulates myocardial mechanical function, materialized as elevation of CO, left ventricular systolic pressure, and maximum rate of left ventricle pressure rise. Cooling, on the other hand, apparently eradicates central hemodynamic effects of Epi and during stable hypothermia, elevation of peripheral vascular vasopressor effects seem to take over. In contrast to temperature-matched, non-Epi stimulated control rats, a significant depression of myocardial mechanical function occurs during rewarming following a moderate sympathetic stimulus during initial cooling.     

Coronary endothelium-derived vasodilation during cooling and rewarming of the in situ heart.

The integrity of coronary vascular endothelial vasodilator function during core cooling and rewarming was investigated in a pentobarbital-anesthetized open-chest dog model. Vasodilator response was assessed as the change from baseline blood flow by injecting the endothelial-dependent vasodilator acetylcholine (ACh) (1.0 microg) or the endothelial-independent vasodilator nitroglycerin (NTG) (50 microg) into the left anterior descending (LAD) coronary artery. Change in blood flow was measured using a transit time ultrasonic volume flowmeter technique. During cooling and rewarming LAD blood flow was significantly decreased. After rewarming, aortic pressure was artificially elevated to reach control. This procedure restored heart work (LV-RPP, left ventricular rate pressure product) and coronary perfusion pressure, but LAD blood flow remained lowered. Ability to dilate the vascular bed supplied by LAD, after injections of ACh or NTG, was present both during cooling and rewarming. At 25 degrees C coronary blood flow (LAD) increased from 3 +/- 1 to 9 +/- 1 mL x min(-1) in response to both ACh and NTG. Posthypothermic blood flow increased from 7 +/- 1 to 19 +/- 2 and 20 +/- 3 mL x min(-1) in response to ACh and NTG, respectively. Measured as the percent change from baseline LAD blood flow, the response was not significantly different from the one obtained in prehypothermic hearts. In conclusion, coronary vasodilator function, both endothelium dependent and endothelium independent, is present but not maintained at the same level during cooling to 25 degrees C and rewarming. In spite of the deterioration of cardiac function, no selective defect in the endothelium-dependent response was detected, either during hypothermia or after rewarming.     

Hematological changes in vervet monkeys (Chlorocebus aethiops) during eight months' adaptation to captivity

This study investigated fluctuations in hematological values of 50 wild-caught vervet monkeys (African green monkeys, grivets, Chlorocebus aethiops) during habituation to captivity. The monkeys were categorized into four groups according to age and sex viz adult males, adult females, juvenile males, and juvenile females. The erythrocyte values were significantly higher (P<0.05) in the adult males than in the other animals. There was an increase in most of the erythrocyte parameters studied during the monitoring period with the most significant being hemoglobin, hematocrit, and mean corpuscular volume. However, the red cell distribution widths, which were higher in adult females, declined. The total white blood cell (WBC) counts, which were higher in adult females than in the other animals, were closely correlated with granulocytes counts. The WBC levels decreased in all the animals throughout the 8 months study, indicating gradually decreasing stress, but they were relatively stable in males. The platelet counts declined significantly (P<0.05) and at 8 months post capture the counts were higher in females than in males. The juvenile female platelet counts were relatively stable during the monitoring period. The maintenance of the monkeys on an improved stable diet and in environment-controlled housing combined with progressing psycho-physiological adaptation may be important factors for the gradual improvements of the hematological values recorded. There were wide variations in these between individual animals emphasizing the need for long adaptation combined with establishment of individual baseline values before experimental studies.     

Alteration in the distribution of organ perfusion following profound hypothermia and circulatory arrest in the baboon.

The physiologic consequences of profound hypothermic circulatory arrest in infants are incompletely understood. Immature baboons underwent surface cooling, followed by core cooling using cardiopulmonary bypass, circulatory arrest for 30 min, and perfusion rewarming. Blood flow to and within organs was studied using the multiple-radionuclide-label microsphere technique. Marked redistribution of total and regional myocardial and cerebral flow occurred during cooling and rewarming.     

Platelet Dynamics during Natural and Pharmacologically Induced Torpor and Forced Hypothermia

Hibernation is an energy-conserving behavior in winter characterized by two phases: torpor and arousal. During torpor, markedly reduced metabolic activity results in inactivity and decreased body temperature. Arousal periods intersperse the torpor bouts and feature increased metabolism and euthermic body temperature. Alterations in physiological parameters, such as suppression of hemostasis, are thought to allow hibernators to survive periods of torpor and arousal without organ injury. While the state of torpor is potentially procoagulant, due to low blood flow, increased viscosity, immobility, hypoxia, and low body temperature, organ injury due to thromboembolism is absent. To investigate platelet dynamics during hibernation, we measured platelet count and function during and after natural torpor, pharmacologically induced torpor and forced hypothermia. Splenectomies were performed to unravel potential storage sites of platelets during torpor. Here we show that decreasing body temperature drives thrombocytopenia during torpor in hamster with maintained functionality of circulating platelets. Interestingly, hamster platelets during torpor do not express P-selectin, but expression is induced by treatment with ADP. Platelet count rapidly restores during arousal and rewarming. Platelet dynamics in hibernation are not affected by splenectomy before or during torpor. Reversible thrombocytopenia was also induced by forced hypothermia in both hibernating (hamster) and non-hibernating (rat and mouse) species without changing platelet function. Pharmacological torpor induced by injection of 5′-AMP in mice did not induce thrombocytopenia, possibly because 5′-AMP inhibits platelet function. The rapidness of changes in the numbers of circulating platelets, as well as marginal changes in immature platelet fractions upon arousal, strongly suggest that storage-and-release underlies the reversible thrombocytopenia during natural torpor. Possibly, margination of platelets, dependent on intrinsic platelet functionality, governs clearance of circulating platelets during torpor.     

Effect of alcohol on thermal balance of man in cold water.

The effects of alcohol on core cooling rates (rectal and tympanic), skin temperatures, and metabolic rate were determined for 10 subjects rendered hypothermic by immersion for 45 min in 10 degrees C water. Experiments were duplicated with and without a 20-min period of exercise at the beginning of cold water immersion. Measurements were continued during rewarming in a hot bath. With blood alcohol concentrations averaging 82 mg 100 mL-1, core cooling rates and changes in skin temperatures were insignificantly different from controls, even if the exercise period was imposed. Alcohol reduced shivering metabolic rate by an overall mean of 13%, insufficient to affect cooling rate. Alcohol had no effect on metabolic rate during exercise. During rewarming by hot bath, the amount of 'afterdrop' and rate of increase in core temperature were unaffected by alcohol. It was concluded that alcohol in a moderate dosage does not influence the rate of progress into hypothermia or subsequent, efficient rewarming. This emphasizes that the high incidence of alcohol involvement in water-related fatalities is due to alcohol potentiation of accidents rather than any direct effects on cold water survival, although very high doses of alcohol leading to unconsciousness would increase rate of progress into hypothermia.     

Changes in cardiovascular β-adrenoceptor responses during hypothermia

The purpose of this study was to determine cardiovascular β-adrenergic responses during hypothermia. In the present study, we used isoproterenol (Iso), a nonselective, potent β-adrenoceptor agonist, well known for its positive chronotropic and inotropic pharmacologic actions at normothermia. Rats were instrumented to measure mean arterial pressure (MAP) and left ventricular (LV) pressure–volume changes using a Millar pressure–volume conductance catheter. Core temperature was manipulated from 37 (normothermia) to 24 °C (hypothermia) and back to 37 °C (rewarming) using both internal and external heat exchangers. During cooling at each temperature (33, 30, 27, and 24 °C), central hemodynamic variables and MAP were measured while intravenously infusing Iso (doses of 1.7, 5, 10, and 20 ng/min). Seven animals underwent all phases of the protocol. At normothermia Iso infusion resulted in a significant, dose-dependent increase in heart rate (HR), stroke volume (SV), cardiac output (CO), LV dP/dt_max (left ventricular maximum derivative of systolic pressure over time) but no change in MAP. During cooling Iso infusion caused no dose-dependent change in any of the hemodynamic variables. After rewarming, baseline HR and LV dP/dt_max were increased, whereas SV was significantly reduced when compared with their pre-hypothermic baseline values. This study shows that physiological cardiovascular responses mediated by the β-adrenoceptor are significantly diminished during core hypothermia.     

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.

     

Myocardial gene expression profiling of rewarming shock in a rodent model of accidental hypothermia

Background

Severe accidental hypothermia represents a cardiovascular emergency associated with high mortality and poor recovery of cardiac function. The biochemical changes occurring within the heart during the development of hypothermia and subsequent resuscitation are not known.

Methods

By mRNA expression profiling, we have characterized gene expression changes occurring within the myocardium in an intact rat model of accidental hypothermia during cooling to a core temperature of 15 °C and subsequent rewarming to 37 °C. During the rewarming phase, these animals develop a profound low-output cardiac failure.

Results

Hypothermia induces expression of known mediators of thermotolerance, including heat-shock protein 70 and several factors involved in protection against apoptotic cell death. Upregulation of genes involved in autophagy and increased abundance of autophagosomal vesicles suggest involvement of autophagic degeneration in the development of myocardial dysfunction occurring during rewarming from hypothermia. Rewarming from hypothermia also induces expression of several pro-inflammatory genes involved in the nuclear factor kappa B (NFκB) signaling cascade.

Conclusions

Our data demonstrate that rewarming from hypothermia is associated with the induction of a cellular stress–response, including upregulation of autophagy and activation of pro-inflammatory signaling cascades. These data provide a framework for understanding the molecular changes that occur during induction of and rewarming from severe hypothermia, and identifies potential targets for cardioprotective interventions in resuscitation of victims of hypothermia.     

Peripheral blood flow during rewarming from mild hypothermia in humans

During the initial stages of rewarming from hypothermia, there is a continued cooling of the core, or after-drop in temperature, that has been attributed to the return of cold blood due to peripheral vasodilatation, thus causing a further decrease of deep body temperature. To examine this possibility more carefully, subjects were immersed in cold water (17 degrees C), and then rewarmed from a mildly hypothermic state in a warm bath (40 degrees C). Measurements of hand blood flow were made by calorimetry and of forearm, calf, and foot blood flows by straingauge venous occlusion plethysmography at rest (Ta = 22 degrees C) and during rewarming. There was a small increase in skin blood flow during the falling phase of core temperature upon rewarming in the warm bath, but none in foot blood flow upon rewarming at room air, suggesting that skin blood flow seems to contribute to the after-drop, but only minimally. Limb blood flow changes during this phase suggest that a small muscle blood flow could also have contributed to the after-drop. It was concluded that the after-drop of core temperature during rewarming from mild hypothermia does not result from a large vasodilatation in the superficial parts of the periphery, as postulated. The possible contribution of mechanisms of heat conduction, heat convection, and cessation of shivering thermogenesis were discussed.     

Whole body protection during three hours of total circulatory arrest: An experimental study

Survival following 3 hr of total circulatory arrest under profound hypothermic conditions was explored in 19 adult mongrel dogs. Thermoregulatory management included combined surface/perfusion hypothermia and azeotrope anesthesia in 95% O2/5% CO2. All animals were resuscitated and survived for at least 12 hr. During the last seven trials (Group II) the following principles were applied: uniform whole-body cooling where differences between rectal, esophageal, and pharyngeal temperatures averaged less than 1 degree C, induction of circulatory arrest at approximately 3 degrees C, constant lung inflation (10-12 cm H2O between 20 degrees C cooling and 20 degrees C rewarming, including the 3-hr arrest period) and ventilation assistance with positive end-expiratory pressure (4 cm H2O) after 20 degrees C rewarming, intraoperative maintenance of colloid osmotic pressure (COP) above 11 mm Hg, replacement of the cooling perfusate with a colloid-rich rewarming prime (COP = 15 mm Hg) and restoration of hemostasis with fresh whole blood transfusions. The application of these principles resulted in the long-term survival of five animals with four survivors displaying no clinically detectable neurological abnormalities. However, two animals developed optic impairment and one animal died from intusseption on the fourth postoperative day. Despite the improved results, it should also be noted that during pilot (Group I) studies (from which the aforementioned principles were derived) fatalities from complications attributed to systemic edema, central nervous system, or pulmonary or coagulation dysfunctions occurred in 9 out of 12 trials. We conclude that whole body protection following 3 hr of total circulatory arrest at a uniform temperature less than 5 degrees C can be successfully accomplished.