The metabolic effects of mild hypothermia on global cerebral ischemia and recirculation in the cat: comparison to normothermia and hyperthermia

Selective brain cooling during and after prolonged global ischemia reduces cortical damage in rats

BACKGROUND AND PURPOSE

Studies of the cerebroprotective effects of selective brain cooling have failed to show amelioration of ischemic injury in the cerebral cortex. This study was designed to test the hypothesis that mild-to-moderate selective brain cooling initiated after the onset of global brain ischemia in rats protects the cerebral cortex and improves neurological outcome.

METHODS

Global forebrain ischemia for 30 minutes in 27 fasted adult male Wistar rats was achieved by bilateral carotid occlusion and hypotension. In group 1, brain temperature, measured in the temporalis muscle, was maintained at 37-38 degrees C throughout the experiment. In group 2, brain temperature fell spontaneously during ischemia to 34.7 +/- 0.1 degrees C and rose spontaneously to 36-37 degrees C after 10 minutes of recirculation. In group 3, brain temperature was lowered with ice packs placed around the head after 15 minutes of ischemia to 24.1 +/- 0.9 degrees C by the end of ischemia, maintained at 30.0 +/- 1.0 degrees C for the first hour of recirculation, then allowed to rise to 36-37 degrees C.

RESULTS

Seven-day survival was 0% (0 of 6) in group 1, 73% (8 of 11) in group 2, and 100% (6 of 6) in group 3. Severity of neuronal damage was less in group 2 than in group 1 in the cortex (p < 0.05) and hippocampal CA1 (p < 0.05) and CA3 regions (p < 0.05). Group 3 had less neuronal damage than group 2 in both cortex (p < 0.02) and striatum (p < 0.02). Furthermore, postischemic weight loss was less and neurobehavioral scores were significantly higher in group 3.

CONCLUSIONS

This study shows that selective brain cooling increases survival from prolonged global ischemia and reduces neuronal injury in the cerebral cortex as well as the striatum and hippocampus.

The effect of mild hypothermia on permanent focal ischemia in the rat

The effect of mild hypothermia on cerebral injury was evaluated in a rat model of permanent middle cerebral artery (MCA) and ipsilateral carotid artery occlusion. The MCA occlusion was performed in rats at temporalis muscle temperatures of 30 degrees C, 33 degrees C, 34.5 degrees C and 36.5 degrees C (n = 10, 8, 10, and 13, respectively). The animals were kept at the desired temperature for 1 hour and rewarmed to 36.5 degrees C. In a separate group of animals (n = 11), the temperature was decreased to 33 degrees C 1 hour after performing the arterial occlusion at normothermia. These animals were rewarmed to 36.5 degrees C after another hour with side by side controls (n = 9) kept at 36.5 degrees C throughout the experiment. Twenty-four hours after the MCA occlusion, rats were killed and the percentage of infarcted right hemisphere was determined in coronal brain sections with 2,3,5-triphenyltetrazolium chloride. The percentage of infarcted volume at 30 degrees C, 33 degrees C, and 34.5 degrees C (9.3 +/- 2.1%, 8.2 +/- 2.2%, and 8.4 +/- 2.2%) (SEM) was significantly smaller than at 36.5 degrees C (19.6 +/- 1.6%, P < 0.01). There were no significant differences between the hypothermic groups. When rats were cooled to 33 degrees C 1 hour after the arterial occlusion, the percentage of infarcted volume was also significantly smaller than the control group (8.0 +/- 1.8% vs. 17.4 +/- 2.1%) (P < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Assessment of the role of adrenoceptor function in ischemia-induced impairment of 2-deoxyglucose uptake and CA1 field potential in rat hippocampal slices

The release of catecholamines, dopamine and noradrenaline has been suggested to play a role in mediating ischemic damage in susceptible brain regions, the hippocampus and striatum. We now provide evidence that suggests a role for adrenoceptors in the deficit of 2-deoxyglucose uptake and CA1 field potential induced in hippocampal slices by hypoxia/hypoglycemia (ischemia). Treatment with alpha 1- or beta-adrenoceptor agonists or cAMP potentiated an ischemia-induced decline of both 2-deoxyglucose uptake and CA1 field potential in hippocampal slices, whereas alpha 1- or beta-adrenoceptor antagonists, or alpha 2-adrenoceptor agonists produced a remarkable neuroprotective action against these deficits. The results indicate that stimulation of adrenoceptors may play a detrimental role in the development of ischemic damage, and suggest a neuroprotective action for adrenoceptor antagonists, which may lessen the functional deficits induced by ischemia.

Tirilazad mesylate does not improve early cerebral metabolic recovery following compression ischemia in dogs

BACKGROUND AND PURPOSE

Tirilazad mesylate (U74006F) has been reported to improve recovery following cerebral ischemia. We conducted a randomized blinded study to determine if the drug would improve immediate metabolic recovery after complete cerebral compression ischemia.

METHODS

Mongrel dogs were anesthetized with pentobarbital and fentanyl and treated with either vehicle (citrate buffer, n = 8) or tirilazad (1.5 mg/kg i.v. plus 0.18 mg/kg/hr, n = 8). Normothermic complete cerebral compression ischemia was produced for 12 minutes by lateral ventricular fluid infusion to raise intracranial pressure above systolic arterial pressure. Cerebral high-energy phosphate concentrations and intracellular pH were measured by phosphorus magnetic resonance spectroscopy. Cerebral blood flow was measured with radiolabeled microspheres, and oxygen consumption was calculated from sagittal sinus blood samples. Somatosensory evoked potentials were measured throughout the experiment.

RESULTS

During ischemia, both groups demonstrated complete loss of high-energy phosphates and a fall in intracellular pH (vehicle, 5.76 +/- 0.23; tirilazad, 5.79 +/- 0.26; mean +/- SEM). At 180 minutes of reperfusion, there were no differences between groups in recovery of intracellular pH (vehicle, 6.89 +/- 0.07; tirilazad, 6.88 +/- 0.18), phosphocreatine concentration (vehicle, 89 +/- 16%; tirilazad, 94 +/- 24% of baseline value), oxygen consumption (vehicle, 2.6 +/- 0.2 ml/min/100 g; tirilazad, 1.8 +/- 0.5 ml/min/100 g), or somatosensory evoked potential amplitude (vehicle, 11 +/- 6%; tirilazad, 7 +/- 4% of baseline value). Forebrain blood flow fell below baseline levels at 180 minutes of reperfusion in the tirilazad-treated animals but not in the vehicle-treated dogs (vehicle, 28 +/- 4 ml/min/100 g; tirilazad, 18 +/- 5 ml/min/100 g).

CONCLUSIONS

We conclude that tirilazad pretreatment does not improve immediate metabolic recovery 3 hours following 12 minutes of normothermic complete ischemia produced by cerebral compression.

Moderate hypothermia reduces blood-brain barrier disruption following traumatic brain injury in the rat

The effects of moderate hypothermia on blood-brain barrier (BBB) permeability and the acute hypertensive response after moderate traumatic brain injury (TBI) in rats were examined. TBI produced increased vascular permeability to endogenous serum albumin (IgG) in normothermic rats (37.5 degrees C) throughout the dorsal cortical gray and white matter as well as in the underlying hippocampi as visualized by immunocytochemical techniques. Vascular permeability was greatly reduced in hypothermic rats cooled to 30 degrees C (brain temperature) prior to injury. In hypothermic rats, albumin immunoreactivity was confined to the gray-white interface between cortex and hippocampi with no involvement of the overlying cortices and greatly reduced involvement of the underlying hippocampi. The acute hypertensive response in normothermic rats peaked at 10 s after TBI (187.3 mm Hg) and returned to baseline within 50 s. In contrast, the peak acute hypertensive response was significantly (P < 0.05) reduced in hypothermic rats (154.8 mm Hg, 10 s after TBI) and returned to baseline at 30 s after injury. These results demonstrate that moderate hypothermia greatly reduces endogenous vascular protein-tracer passage into and perhaps through the brain. This reduction may, in part, be related to hypothermia-induced modulation of the systemic blood pressure response to TBI.

Reduction by delayed hypothermia of cerebral infarction following middle cerebral artery occlusion in the rat: a time-course study

The effect of hypothermia on neuronal injury following permanent middle cerebral artery (MCA) occlusion in the rat was examined. Moderate hypothermia (body temperature 24 degrees C) was induced before MCA occlusion (0-minute delay group) in six rats, at 30 minutes in eight rats, and at 1 (seven rats), 2 (seven rats), and 3 (nine rats) hours after occlusion. The rats were kept at a 24 degrees C body temperature for 1 hour, then allowed to rewarm over 90 minutes. The animals were sacrificed 24 hours after MCA occlusion, and infarction was visualized by staining of coronal sections with 2,3,5-triphenyltetrazolium chloride. Infarct volumes were compared to matched normothermic control rats (body temperature 36 degrees C). Additional groups of 0-minute delay hypothermic (10 rats) and control animals (nine rats) were sacrificed 72 hours after MCA occlusion to examine the effects of prolonged survival. A significant reduction in the percentage of infarcted right hemisphere was seen in the animals sacrificed after 24 hours with 0-minute, 30-minute, and 1-hour delays in inducing hypothermia (mean +/- standard error of the mean: 2.2% +/- 0.7%, 4.4% +/- 0.9%, and 3.6% +/- 1.1%, respectively) as compared to normothermic control rats (10.8% +/- 1.5%, p less than 0.01 by Student's t-test). In the 2- and 3-hour delay groups, the percentage of infarcted right hemisphere was 17.1% +/- 2.4% and 12.0% +/- 2.7%, respectively, and no decrease in infarct volume was observed. The 0-minute delay hypothermia group sacrificed after 72 hours also displayed a significant reduction in right hemisphere infarct compared to their respective controls (4.8% vs. 11.7%, p less than 0.05). These findings indicate that, in the setting of permanent MCA occlusion, hypothermia markedly decreases brain injury even when its induction is delayed for up to 1 hour after the onset of ischemia. Ischemic damage does not appear to be merely retarded but permanently averted.

The effects of brain temperature on temporary global ischaemia in rat brain. A 31-phosphorous NMR spectroscopy study

31-Phosphorus magnetic resonance spectroscopy was used in a rat model of 10 min severe incomplete forebrain ischaemia (2-vessel occlusion with hypotension) to assess the effect of mild brain hypo- and hyperthermia (+/- 2 degrees C) on intracellular pH and high energy phosphates. In three experimental groups intracerebral temperature was maintained at levels of 34, 36 and 38 degrees C during ischaemia and early reperfusion. The steady level of intracellular pH during ischaemia was 6.63, 6.58 and 6.53 in the 34, 36, and 38 degrees C groups, respectively. The rate of initial recovery of intracellular pH in reperfusion was 0.046 +/- 0.012 pH units per min (+/- s.d.) in the 36 degrees C group compared to 0.056 +/- 0.010 (+/- s.d., P less than 0.05) in the 34 degrees C group and 0.032 +/- 0.009 (+/- s.d., P less than 0.01) in the 38 degrees C group. The recovery in early reperfusion of phosphocreatine and ATP was slower in the 38 degrees C group compared to the other groups. The findings were consistent with recent studies, suggesting that even mild hypothermia may afford protection to the ischaemic brain, and furthermore indicate that mild hyperthermia as fever or even subfebricity may be deleterious for the outcome in stroke patients.

Neuronal damage, glial response and cerebral metabolism after hypothermic forebrain ischemia in the rat

We investigated the effect of 30 degrees C whole body hypothermia on neuronal injury, astroglial reactivity and intracellular pH in rats subjected to 15 min of forebrain ischemia. Experimental groups included: (1) normothermic ischemia (n = 8), ischemia induced under 37 degrees C body temperature, (2) hypothermic ischemia (n = 6), ischemia induced under 30 degrees C body temperature. Cerebral intracellular pH was measured using in vivo 31P NMR spectroscopy over 7 days. Neuronal injury and astrocytic reactivity were evaluated using hematoxylin and eosin staining, and immunoreactivity to glial fibrillary acidic protein, respectively. Normothermic animals revealed significant alkalosis (P less than 0.01) at 48 h after ischemia compared to the pre-ischemic value. No significant intracellular pH change was detected after ischemia in the hypothermic group. Ischemic neuronal injury was prevented in the hypothermic animals, compared to the severe neuronal injury found in the normothermic animals (P less than 0.01). The marked astrocytosis of normothermic animals was significantly inhibited in the hypothermic animals (P less than 0.01). Our data indicate, that hypothermia significantly inhibits neuronal injury as well as post-ischemic alkaloids and astrocytosis, induced by 15 min of forebrain ischemia in the rat.

Prevention of ischemia-induced cerebral hypothermia by controlling the environmental temperature

Regulation of brain temperature during and after cerebral ischemia plays an important role in the evolution of neuronal damage. Therefore, it is essential to maintain brain temperature at 37 degrees C during and after the ischemic insult. To get information about brain temperature during the experimental procedure, researchers in previous works have made various attempts to correlate between brain and body temperature during and after ischemia. In the present study, brain temperature was measured when ischemia was performed either at 30 degrees C or at 20 degrees C environmental temperature. For this purpose a stainless-steel guide of a temperature probe was introduced through the bregma and implanted between both hemispheres of the rat. Rats were then subjected to a 10-min period of forebrain ischemia. Cerebral temperature was measured during ischemia and up to 90 min; in some experiments up to 4 hr after ischemia. In another group of experiments, ischemia was performed also at either 30 degrees C or 20 degrees C environmental temperature, and histological assessment of the rat hippocampus was carried out. In addition, the influence of chlorpromazine as a hypothermic agent on the cerebral temperature and the neuronal loss was also tested at both of the experimental conditions. Recording the brain temperature at both of the selected environmental temperatures suggests that it is possible to preserve cerebral normothermia during and after ischemia by working at 30 degrees C environmental temperature. On the other hand, brain temperature dropped sharply immediately after ischemia when working under 20 degrees C environmental temperature, and brain tissue was thereby protected against ischemia.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of post-ischemic hypothermia on the neuronal injury and brain metabolism after forebrain ischemia in the rat

We investigated the effect of moderate post-ischemic hypothermia on neuropathological outcome and cerebral high energy phosphate metabolism, intracellular pH and Mg2+ concentration in the rat. Three groups of animals were investigated: (1) Wistar rats subjected to 12 min of forebrain ischemia under normothermic conditions (n = 17), (2) rats subjected to the identical procedure of ischemia, except that 30 degrees C hypothermia was induced post-ischemia and maintained for 2 h of reperfusion (n = 6), and (3) control hypothermic rats not subjected to ischemia (n = 4). In vivo 31P NMR spectroscopy was performed prior to ischemia, and at intervals up to 168 h after ischemia. Histological analysis of brain tissues was performed 7 days after ischemia. No significant differences in cortical and hippocampal neuronal damage was detected between the two experimental groups. Significantly lower pH values were detected in the hypothermic ischemic animals at 24 h (P = 0.0001) and 48 h (P = 0.018) post-ischemia compared to the normothermic ischemic animals. Normothermic ischemic animals exhibited significantly lower [Mg2+] at 72 h (P less than 0.006) compared to the pre-ischemia level. Our data indicate that post-ischemic hypothermia modifies the profiles of post-ischemic brain tissue pH and Mg2+ concentration, and this modification is not associated with histopathological outcome 7 days after ischemia.

Hypothermia reduces 72-kDa heat-shock protein induction in rat brain after transient forebrain ischemia

BACKGROUND AND PURPOSE

We examined the influence of concurrent moderate hypothermia (30 degrees C) and transient forebrain ischemia on the induction of 72-kDa heat-shock protein and neuronal damage in male Wistar rats.

SUMMARY OF REPORT

Experimental groups included: normothermic with 8 minutes of transient forebrain ischemia (group 1, n = 7), hypothermic without ischemia (group 2, n = 9), and hypothermic (30 degrees C) with 8 minutes of transient forebrain ischemia (group 3, n = 5). Intense 72-kDa heat-shock protein immunoreactivity was demonstrated in rat forebrain 48 hours after induction of normothermic forebrain ischemia (group 1); it was not detected in the brain of animals subjected to hypothermia without ischemia (group 2), and hypothermia during ischemia (group 3) significantly inhibited its expression compared with that in normothermic ischemia animals (group 1).

CONCLUSIONS

These observations suggest that 72-kDa heat-shock protein induction is not the mechanism by which moderate hypothermia protects against ischemic cell damage.

Global cerebral ischemia in piglets under conditions of mild and deep hypothermia

BACKGROUND AND PURPOSE

To investigate the effects of hypothermia on the rate of change and degree of recovery of brain adenosine triphosphate and phosphocreatine concentrations and intracellular pH, we have developed a model that allows phosphorus nuclear magnetic resonance spectroscopy of the intact piglet brain during circulatory arrest.

METHODS

Three groups of piglets were studied. Three control animals underwent cardiopulmonary bypass at normothermia for 1 hour; five group 1 animals underwent bypass at a brain temperature of 15 degrees C, followed by a period of circulatory arrest such that adenosine triphosphate was absent for 21 minutes, followed by 1 hour of reperfusion; and five group 2 animals underwent bypass at a brain temperature of 37 degrees C, followed by a period of circulatory arrest such that adenosine triphosphate was absent for 21 minutes, followed by reperfusion for 1 hour.

RESULTS

Control animals showed no significant metabolic effects of bypass. Group 1 animals showed a slower decay of the adenosine triphosphate and phosphocreatine concentrations than group 2 animals, consistent with a lower metabolic rate, and had a higher pH at the onset of ischemia. Recovery of the adenosine triphosphate concentration was significantly better in group 1 animals (95%) than in group 2 animals (30%) (p less than 0.02), and recovery of the phosphocreatine concentration was also better in group 1 animals (93%) than in group 2 animals (32%) (p less than 0.02). Intracellular pH recovered in group 1 animals, but not in group 2 animals. Regional biochemical assays of metabolites performed in the group 2 piglets and in five pilot piglets exposed to deep hypothermia generally confirmed the spectroscopic findings but demonstrated considerable regional variation, specially in the group 2 piglets' brains.

CONCLUSIONS

We conclude that hypothermia exerts a protective effect on the piglet brain during global ischemia even after the adenosine triphosphate pool has been completely depleted.

Hypothermic protection following middle cerebral artery occlusion in the rat

The effects of deep hypothermia on ischemic neuronal injury were examined using a permanent middle cerebral artery occlusion model in the rat. Animals were maintained at temporalis temperatures of either 24 degrees C or 36 degrees C and killed 6 hours after arterial occlusion. Normothermic rats displayed an average infarct volume of 25.1% +/- 1.6% of the right hemisphere, whereas hypothermic rats had an average infarct volume of 4.1% +/- 1.3% (p less than 0.001). The right/left hemispheric ratio was 1.05 +/- 0.02 in the normothermic group and 1.00 +/- 0.02 in the hypothermic group (p less than 0.05). These results suggest that hypothermia to 24 degrees C may reduce cerebral infarction and edema formation following middle cerebral artery occlusion in the rat.

Relationship between body and brain temperature in traumatically brain-injured rodents

Recent work has shown that mild to moderate levels of hypothermia may profoundly reduce the histological and biochemical sequelae of cerebral ischemic injury. In the present study, the authors examined the effect of fluid-percussion injury on brain temperature in anesthetized rats and the effect of anesthesia on brain temperature in uninjured rats. The relationship between the brain, rectal, and temporalis muscle temperatures during normothermia, hypothermia, and hyperthermia was studied following a moderate magnitude of fluid-percussion brain injury (2.10 to 2.25 atmospheres) in rats. The results showed that mean brain temperature in 10 anesthetized injured rats, in 21 anesthetized uninjured rats, and in 10 unanesthetized uninjured rats was a mean (+/- standard error of the mean) of 36.04 degrees +/- 0.20 degrees C, 36.30 degrees +/- 0.08 degrees C, and 37.95 degrees +/- 0.09 degrees C, respectively. There was no significant difference in temperature under general anesthesia between injured and uninjured rats (p greater than 0.05). In the absence of brain injury, mean brain temperature was significantly lower in anesthetized rats than in unanesthetized rats (p less than 0.001). In anesthetized brain-injured rats, temporalis muscle temperature correlated well with brain temperature over a 30 degrees to 40 degrees C range, even when brain temperature was rapidly changed during induction of hypothermia or hyperthermia (r = 0.9986, p less than 0.0001). In contrast, rectal temperature varied inconsistently from brain temperature. These observations indicated that: 1) brain injury itself does not influence brain temperature in this model; 2) anesthesia alone decreases brain temperature to levels producing cerebral protection in this model; and 3) external monitoring of temporalis muscle temperature can provide a reliable indirect measure of brain temperature in the course of experimental brain injury. The authors believe that it is essential to monitor or control brain temperature in studies of experimental brain injury.

Marked protection by moderate hypothermia after experimental traumatic brain injury

These experiments examined the effects of moderate hypothermia on mortality and neurological deficits observed after experimental traumatic brain injury (TBI) in the rat. Brain temperature was measured continuously in all experiments by intraparenchymal probes. Brain cooling was induced by partial immersion (skin protected by a plastic barrier) in a water bath (0 degrees C) under general anesthesia (1.5% halothane/70% nitrous oxide/30% oxygen). In experiment I, we examined the effects of moderate hypothermia induced prior to injury on mortality following fluid percussion TBI. Rats were cooled to 36 degrees C (n = 16), 33 degrees C (n = 17), or 30 degrees C (n = 11) prior to injury and maintained at their target temperature for 1 h after injury. There was a significant (p less than 0.04) reduction in mortality by a brain temperature of 30 degrees C. The mortality rate at 36 degrees C was 37.5%, at 33 degrees C was 41%, and at 30 degrees C was 9.1%. In experiment II, we examined the effects of moderate hypothermia or hyperthermia initiated after TBI on long-term behavioral deficits. Rats were cooled to 36 degrees C (n = 10), 33 degrees C (n = 10), or 30 degrees C (n = 10) or warmed to 38 degrees C (n = 10) or 40 degrees C (n = 12) starting at 5 min after injury and maintained at their target temperatures for 1 h. Hypothermia-treated rats had significantly less beam-walking, beam-balance, and body weight loss deficits compared to normothermic (38 degrees C) rats. The greatest protection was observed in the 30 degrees C hypothermia group.(ABSTRACT TRUNCATED AT 250 WORDS)

Temperature modulation of ischemic neuronal death and inhibition of calcium/calmodulin-dependent protein kinase II in gerbils

We used brief bilateral carotid artery occlusion in gerbils to examine the effects of temperature on ischemia-induced inhibition of calcium/calmodulin-dependent protein kinase II activity and neuronal death. In normothermic (36 degrees C) gerbils, ischemia induced a severe loss of hippocampal CA1 pyramidal neurons measured 7 days after ischemia (28.4 neurons/mm, n = 10; control density in 10 naive gerbils 262.1 neurons/mm) and a significant decrease in forebrain calcium/calmodulin-dependent protein kinase II autophosphorylation measured 2 hours after ischemia (12.9 fmol/min, n = 6; control phosphorylation in six naive gerbils 23.5 fmol/min). The effect of temperature on these indicators of ischemic damage was examined by adjusting intracerebral temperature before and during the ischemic insult. Hyperthermic (39 degrees C) gerbils showed almost complete loss of neurons in the CA1 region (3.0 neurons/mm, n = 11) and extension of neuronal death into the CA2, CA3, and CA4 regions. In addition, hyperthermia exacerbated ischemia-induced inhibition of calcium/calmodulin-dependent protein kinase II activity (4.2 fmol/min, n = 6). Hypothermia (32 degrees C) protected against ischemia-induced CA1 pyramidal cell damage (257.0 neurons/mm, n = 20) and inhibition of calcium/calmodulin-dependent protein kinase II activity (26.0 fmol/min, n = 6). Our results are consistent with the hypothesis that loss of calcium/calmodulin-dependent protein kinase II activity may be a critical event in the development of ischemia-induced cell death.

Moderate hypothermia after cardiac arrest of 17 minutes in dogs. Effect on cerebral and cardiac outcome

Moderate hypothermia (30 degrees C) induced before circulatory arrest is known to improve neurologic outcome. We explored, for the first time in a reproducible dog outcome model, moderate hypothermia induced during reperfusion after cardiac arrest (resuscitation). In three groups of six dogs each (N = 18), normothermic ventricular fibrillation cardiac arrest (no blood flow) of 17 minutes was reversed by cardiopulmonary bypass--normothermic in control group I (37.5 degrees C) and hypothermic to 3 hours in groups II (32 degrees C) and III (28 degrees C). Defibrillation was achieved in less than or equal to 5 minutes and partial bypass was continued to 4 hours, controlled ventilation to 20 hours, and intensive care to 96 hours. All 18 dogs survived. Electroencephalographic activity returned significantly earlier in groups II and III. Mean +/- SD best neurologic deficit between 48 and 96 hours was 44 +/- 8% in group I, 38 +/- 12% in group II, and 35 +/- 7% in group III (differences not significant). Best overall performance category 2 (good outcome) between 48 and 96 hours was achieved in none of the six dogs in group I and in four of the 12 dogs in the combined hypothermic groups II and III (difference not significant). Mean +/- SD brain total histologic damage score was 130 +/- 22 in group I, 93 +/- 28 in group II (p = 0.05), and 80 +/- 26 in group III (p = 0.03). Gross myocardial damage was greater in groups II and III than in group I--numerically higher overall and significantly higher in group III for the right ventricle alone (p = 0.02). Moderate hypothermia after prolonged cardiac arrest may or may not improve cerebral outcome slightly and can worsen myocardial damage.

Hypothermia following acute carbon-monoxide poisoning increases mortality

The effect of body temperature during recovery from acute severe carbon monoxide (CO) poisoning on morbidity and mortality was investigated using an unanesthetized animal model. Levine prepared female rats were exposed to 2700 ppm CO for 90 min, displaying the usual hypothermia, hypotension and bradycardia. Body temperature in survivors was either maintained at the terminal CO exposure value for 4 h ('cooled'), rapidly raised to the pre-CO exposure value for 4 h ('heated') or allowed to return to normal naturally ('unheated'). Following this period of recovery, the 'heated' rats sustained the lowest mortality rate (22%), the 'unheated' rats a greater mortality rate (44%), and the 'cooled' rats the highest mortality rate (50%). Inclusive of the surviving rats, there were no significant differences in neurologic deficit between the three groups, after 4, 24 or 48 h of recovery. Aside from a significant delay in recovery of blood pressure in the 'heated' rats relative to the other two treatment groups post-CO, there were no differences in blood pressure, heart rate or plasma glucose. The results suggest that rapid return to euthermia improves survival following acute severe CO poisoning, contrasting with an earlier study showing the detrimental effect of euthermia during CO poisoning.

The novel dihydronaphthyridine Ca2+ channel blocker CI-951 improves CBF, brain pHi, and EEG recovery in focal cerebral ischemia

The effects of the novel dihydronaphthyridine Ca2+ antagonist CI-951 on focal cerebral ischemia were assessed during MCA occlusion in 30 white New Zealand rabbits under 1.0% halothane anesthesia. In vivo brain pHi and focal CBF were measured with umbelliferone fluorescence. Baseline normocapnic brain pHi and CBF were 7.02 +/- 0.02 and 48.4 +/- 2.9 ml/100 g/min, respectively. In the severe ischemic regions, 15 min postocclusion brain pHi and CBF were 6.62 +/- 0.04 and 14.4 +/- 0.7 ml/100 g/min in controls vs. 6.60 +/- 0.02 and 12.9 +/- 2.3 ml/100 g/min, respectively, in animals destined to receive CI-951. Twenty minutes after MCA occlusion, CI-951 was administered at 0.5 microgram/kg/min and brain pHi and CBF were determined in both regions of severe and moderate ischemia for 4 h postocclusion. Control severe ischemic sites demonstrated no significant improvement in brain pHi and only mild increases in CBF over the next 4 h. CI-951 caused significant improvement in both of these parameters. Postocclusion 4 h brain pHi and CBF measured 6.69 +/- 0.04 and 18.5 +/- 3.2 ml/100 g/min in controls vs. 7.01 +/- 0.04 and 41.7 +/- 5.3 ml/100 g/min, respectively, in CI-951 animals (p less than 0.001). Similar improvements were observed in moderate ischemic sites. In animals that demonstrated postocclusion EEG attenuation, 75% of CI-951 animals had EEG recovery as compared to 18% in controls. CI-951 may be a useful therapeutic agent for focal cerebral ischemia if histological and outcome studies verify these data.

Mild cerebral hypothermia during and after cardiac arrest improves neurologic outcome in dogs

We previously found mild hypothermia (34-36 degrees C), induced before cardiac arrest, to improve neurologic outcome. In this study we used a reproducible dog model to evaluate mild hypothermia by head cooling during arrest, continued with systemic cooling (34 degrees C) during recirculation and for 1 h after arrest. In four groups of dogs, ventricular fibrillation (no flow) of 12.5 min at 37.5 degrees C was reversed with cardiopulmonary bypass and defibrillation in less than or equal to 5 min, and followed by controlled ventilation to 20 h and intensive care to 96 h. In Study A we resuscitated with normotension and normal hematocrit; Control Group A-I (n = 12) was maintained normothermic, while Treatment Group A-II (n = 10) was treated with hypothermia. In Study B we resuscitated with hypertension and hemodilution. Control Group B-I (n = 12) was maintained normothermic (6 of 12 were not hemodiluted), while Treatment Group B-II (n = 10) was treated with hypothermia. Best overall performance categories (OPCs) achieved between 24 and 96 h postarrest were in Group A-I: OPC 1 (normal) in 0 of 12 dogs, OPC 2 (moderate disability) in 2, OPC 3 (severe disability) in 7, and OPC 4 (coma) in 3 dogs. In Group A-II, OPC 1 was achieved in 5 of 10 dogs (p less than 0.01), OPC 2 in 4 (p less than 0.001), OPC 3 in 1, and OPC 4 in 0 dogs. In Group B-I, OPC 1 was achieved in 0 of 12 dogs, OPC 2 in 6, OPC 3 in 5, and OPC 4 in 1 dog. In Group B-II, OPC 1 was achieved in 6 of 10 dogs (p less than 0.01), OPC 2 in 4 (p less than 0.05), and OPC 3 or 4 in 0 dogs. Mean neurologic deficit and brain histopathologic damage scores showed similar significant group differences. Morphologic myocardial damage scores were the same in all four groups. We conclude that mild brain cooling during and after insult improves neurologic outcome after cardiac arrest.