Regional differences in vascular autoregulation in the rat brain in severe insulin-induced hypoglycemia

The present experiments were undertaken to determine if loss of vascular autoregulation during severe hypoglycemia shows regional differences that could help to explain the localization of hypoglycemic cell damage. Artificially ventilated rats (70% N2O) were subjected to a 30-min insulin-induced hypoglycemic coma (with cessation of EEG activity), with mean arterial blood pressure being maintained at 140, 120, 100, and 80 mm Hg. After 30 min of hypoglycemia, local cerebral blood flow (CBF) in 25 brain structures was measured autoradiographically with a [14C]iodoantipyrine technique. Since local CBF values did not differ between the 120 and the 100 mm Hg groups, the animals of these groups were pooled (110 mm Hg group). The results showed that at a blood pressure of 140 mm Hg, CBF was increased in 22 of 25 structures analyzed, the maximal values approximating 300% of control. At 110 mm Hg, cerebral cortical structures had CBF values that were either decreased, normal, or slightly increased; however, many subcortical structures (and cerebellum) showed markedly increased flow rates. Although a lowering of blood pressure to 80 mm Hg usually further reduced flow rates, some of these latter structures also had well-maintained CBF values at that pressure. Thus, there were large interstructural variations of local CBF at any of the pressures examined. Analysis of the pressure-flow relationship showed loss of autoregulation in some structures, whereas others had remarkably well-preserved CBF values at low pressures. The results indicate that during severe hypoglycemia, even relatively moderate arterial hypotension may add a circulatory insult to the primary one, and they strongly suggest that any such insult affects some brain structures more than others.     

Hypoglycemic brain injury: potentiation from respiratory depression and injury aggravation from hyperglycemic treatment overshoots.

Hypoglycemia can cause brain dysfunction, brain injury, and death. The present study seeks to broaden current information regarding mechanisms of hypoglycemic brain injury by investigating a novel etiology. The cat's high resistance to brain injury from hypoglycemia suggested that additional influences such as respiratory depression might play a facilitating role. Three groups of cats were exposed to fasting and insulin-induced hypoglycemia (HG; n = 6), euglycemic respiratory depression (RD; n = 5), and combined hypoglycemic respiratory depression (HG/RD; n = 10). The HG animals were maintained at <1.5 mmol (mean 1 mmol) serum glucose concentration for 2 to 6.6 hours. The respiratory depression was associated with PaO2 and PaCO2 values of approximately 50 mm Hg for 1 hour and of approximately 35 and approximately 75 mm Hg, respectively, for the second hour. Magnetic resonance diffusion-weighted imaging estimated brain energy state before, during, and after hypoglycemia. The hypoglycemic respiratory depression exposures were terminated either to euglycemia (n = 4) or to hyperglycemia (n = 6). Brain injury was assessed after 5 to 7 days of survival. Cats exposed to hypoglycemia alone maintained unchanged diffusion coefficients; that is, they lacked evidence of brain energy failure and all six remained brain-intact. Only 1 of 5 euglycemic RD but 10 of 10 HG/RD cats developed brain damage (HG and RD vs. HG/RD, P < 0.01). This difference in brain injury rates suggests injury potentiation by hypoglycemia and respiratory depression acting together. Three injury patterns emerged, including activation of microglia, selective neuronal necrosis, and laminar cortical necrosis. Widespread activation of microglia suggesting damage to neuronal cell processes affected all damaged brains. Selective neuronal necrosis affecting the cerebral cortex, hippocampus, and basal ganglia was observed in all but one case. Instances of laminar cortical necrosis were limited to cats exposed to hypoglycemic respiratory depression treated with hyperglycemia. Thus, treatment with hyperglycemia compared with euglycemia after hypoglycemic respiratory depression exposures significantly increased the brain injury scores (24 +/- 6 vs. 13 +/- 2 points; P < 0.05). This new experimental hypoglycemia model's contribution lies in recognizing additional factors that critically define the occurrence of hypoglycemic brain injury.     

The distribution of hypoglycemic brain damage

Summary Rats were exposed to insulin-induced hypoglycemia resulting in periods of cerebral isoelectricity ranging from 10 to 60 min. After recovery with glucose, they were allowed to wake up and survive for 1 week. Control rats were recovered at the stage of EEG slowing. After sub-serial sectioning, the number and distribution of dying neurons was assessed in each brain region. Acid fuchsin was found to stain moribund neurons a brilliant red.Brains from control rats showed no dying neurons. From 10 to 60 min of cerebral isoelectricity, the number of dying neurons per brain correlated positively with the number of minutes of cerebral isoelectricity up to the maximum examined period of 60 min.Neuronal necrosis was found in the major brain regions vulnerable to several different insults. However, within each region the damage was not distributed as observed in ischemia.A superficial to deep gradient in the density of neuronal necrosis was seen in the cerebral cortex. More severe damage revealed a gradient in relation to the subjacent white matter as well. The caudatoputamen was involved more heavily near the white matter, and in more severely affected animals near the angle of the lateral ventricle. The hippocampus showed dense neuronal necrosis at the crest of the dentate gyrus and a gradient of increasing selective neuronal necrosis medially in CA1. The CA3 zone, while relatively resistant, showed neuronal necrosis in relation to the lateral ventricle in animals with hydrocephalus. Sharp demarcations between normal and damaged neuropil were found in the hippocampus. The periventricular amygdaloid nuclei showed damage closest to the lateral ventricles. The cerebellum was affected first near the foramina of Luschka, with damage occurring over the hemispheres in more severely affected animals. Purkinje cells were affected first, but basket cells were damaged as well. Rare necrotic neurons were seen in brain stem nuclei. The spinal cord showed necrosis of neurons in all areas of the gray matter. Infarction was not seen in this study.The possibility is discussed that a neurotoxic substance borne in the tissue fluid and cerebrospinal fluid (CSF) contributes to the pathogenesis of neuronal necrosis in hypoglycemic brain damage.Supported by the Swedish Medical Research Council (projects 12X-03020 and 14X-263) and the National Institutes of Health of the United States Public Health Service (grant no. 5 R01 NS07838)     

Hippocampal damage following repeated brief hypotensive episodes in the rat

We examined the brain damage following repeated hypotensive episodes in the rat. Severe hypotension was induced by withdrawal of arterial blood. The MABP was maintained at about 25 mm Hg with isoelectric EEG and the shed blood was retransfused. After 1 week of recovery, histopathological changes were examined. No brain damage was observed after 1 min of isoelectric EEG. Mild neuronal damage to the hippocampal CA1 subfield was seen in some animals after two episodes of 1-min isoelectric EEG at a 1-h interval. Significant and consistent neuronal loss in the hippocampal CA1 subfield was observed after three episodes of 1-min isoelectric EEG. Scattered neuronal damage in the thalamus was additionally seen in some animals. The present study indicates that repeated brief hypotensive episodes produce brain damage depending on the number of episodes, even though no brain damage results when induced as a single insult. This animal model may reproduce hemodynamic transient ischemic attacks in humans.     

Delayed hypovolemic hypotension exacerbates the hemodynamic and histopathologic consequences of thromboembolic stroke in rats.

Abnormalities in cerebrovascular reactivity or hemodynamic reserve are risk factors for stroke. The authors determined whether hemodynamic reserve is reduced in an experimental model of thromboembolic stroke. Nonocclusive common carotid artery thrombosis (CCAT) was produced in rats by a rose bengal-mediated photochemical insult, and moderate hypotension (60 mm Hg/30 min) was induced 1 hour later by hemorrhage. Alterations in local cerebral blood flow (ICBF) were assessed immediately after the hypotensive period by 14C-iodoantipyrine autoradiography, and histopathologic outcome was determined 3 days after CCAT. Compared to normotensive CCAT rats (n = 5), induced hypotension after CCAT (n = 7) led to enlarged regions of severe ischemia (i.e., mean ICBF < 0.24 mL/g/min) in the ipsilateral hemisphere. For example, induced hypotension increased the volume of severely ischemic sites from 16 +/- 4 mm3 (mean +/- SD) to 126 +/- 99 mm3 (P < 0.05). Histopathologic data also showed a larger volume of ischemic damage with secondary hypotension (n = 7) compared to normotension (22 +/- 15 mm3 versus 5 +/- 5 mm3, P < .05). Both hypotension-induced decreases in ICBF and ischemic pathology were commonly detected within cortical anterior and posterior borderzone areas and within the ipsilateral striatum and hippocampus. In contrast to CCAT, mechanical ligation of the common carotid artery plus hypotension (n = 8) did not produce significant histopathologic damage. Nonocclusive CCAT with secondary hypotension therefore predisposes the post-thrombotic brain to hemodynamic stress and structural damage.     

Insulin attenuates ischemic brain damage independent of its hypoglycemic effect

Insulin, an endogenously produced circulating peptide that enters the brain, has been shown to reduce ischemic brain and spinal cord damage in several animal models. Because of its potential clinical use in humans, the present study was undertaken to test the hypotheses that (a) survival and regional ischemic brain necrosis are improved by insulin; (b) insulin requires concomitant hypoglycemia to exert its neuroprotective effect; (c) insulin is still neuroprotective with delayed administration after an episode of postischemic hypotension; and (d) insulin is beneficial after normoglycemic, as well as hyperglycemic ischemia. Rats were subjected to 10.5 min two-vessel occlusion forebrain ischemia followed by 30 min of hypotension to increase the infarction rate. Insulin administered concomitantly with glucose significantly reduced the seizure rate, as well as cortical and striatal neuronal necrosis below that seen in untreated animals. Neuroprotection was seen whether insulin was given before or after a 30-min episode of postischemic hypotension. Insulin reduced pan-necrosis in addition to selective neuronal necrosis: The infarction rate was reduced in the cerebral cortex, thalamus, and substantia nigra pars reticulata. Normoglycemic ischemia produced only selective neuronal necrosis, but a beneficial effect on structural damage was also seen. The results indicate that insulin acts directly on the brain, independent of hypoglycemia, to reduce ischemic brain necrosis. Possible direct CNS mechanisms of action include an effect on central insulin receptors mediating inhibitory neuromodulation, an effect on central neurotransmitters, or a growth factor effect of insulin.     

Neuropathologic consequences of internal carotid artery occlusion and hemorrhagic hypotension in baboons

We studied eight anesthetized and physiologically monitored adult baboons (Papio cyanocephalus); four were subjected to hemorrhagic hypotension alone and four to hemorrhagic hypotension plus unilateral carotid artery occlusion. Cerebral blood flow was measured using xenon-133, the electroencephalogram was recorded using silver-silver chloride epidural electrodes, and histologic examination was carried out after perfusion-fixation. In the baboons subjected to hypotension alone (mean arterial blood pressure of 28 mm Hg) cerebral blood flow was 28.5 +/- 5.0 ml/100 g/min, whereas in the baboons subjected to hypotension plus unilateral carotid artery occlusion it was 21.8 +/- 1.8 ml/100 g/min at a mean arterial blood pressure of 27 mm Hg. There was no ischemic damage in the former group, but in the latter group there was necrosis in the arterial boundary zones of three baboons and in the distribution of the middle cerebral artery in one. We conclude that, when combined with hypotension, unilateral carotid artery occlusion may lead to hemodynamic ischemia accentuated in the arterial boundary zones of the ipsilateral cerebral hemisphere.     

Hypoxia, hyperoxia, ischemia, and brain necrosis

BACKGROUND: Human brains show widespread necrosis when death occurs after coma due to cardiac arrest, but not after hypoxic coma. It is unclear whether hypoxia alone can cause brain damage without ischemia. The relationship of blood oxygenation and vascular occlusion to brain necrosis is also incompletely defined. METHODS: We used physiologically monitored Wistar rats to explore the relationship among arterial blood oxygen levels, ischemia, and brain necrosis. Hypoxia alone (PaO2 = 25 mm Hg), even at a blood pressure (BP) of 30 mm Hg for 15 minutes, yielded no necrotic neurons. Ischemia alone (unilateral carotid ligation) caused necrosis in 4 of 12 rats, despite a PaO2 > 100 mm Hg. To reveal interactive effects of hypoxia and ischemia, groups were studied with finely graded levels of hypoxia at a fixed BP, and with controlled variation in BP at fixed PaO2. In separate series, focal ischemic stroke was mimicked with transient middle cerebral artery (MCA) occlusion, and the effect of low, normal, and high PaO2 was studied. RESULTS: Quantitated neuropathology worsened with every 10 mm Hg decrement in BP, but the effect of altering PaO2 by 10 mm Hg was not as great, nor as consistent. Autoradiographic study of cerebral blood flow with 14C-iodoantipyrine revealed no hypoxic vasodilatation during ischemia. In the MCA occlusion model, milder hypoxia than in the first series (PaO2 = 46.5 +/- 1.4 mm Hg) exacerbated necrosis to 24.3 +/- 4.7% of the hemisphere from 16.6 +/- 7.0% with normoxia (PaO2 = 120.5 +/- 4.1 mm Hg), whereas hyperoxia (PaO2 = 213.9 +/- 5.8 mm Hg) mitigated hemispheric damage to 7.50 +/- 1.86%. Cortical damage was strikingly sensitive to arterial PaO2, being 12.8 +/- 3.1% of the hemisphere with hypoxia, 7.97 +/-4.63% with normoxia, and only 0.3 +/- 0.2% of the hemisphere with hyperoxia (p < 0.01), and necrosis being eliminated completely in 8 of 10 animals. CONCLUSIONS: Hypoxia without ischemia does not cause brain necrosis but hypoxia exacerbates ischemic necrosis. Hyperoxia potently mitigates brain damage in this MCA occlusion model, especially in neocortex.     

Return of neuronal functions after prolonged cardiac arrest

Cardiociculatory and respiratory arrest of 30 min was produced in normothermic cats by electrical ventricular fibrillation and tracheal occlusion. Resuscitation after cardiac arrest was attempted by open-chest manual heart massage and electrical fibrillation combined with pharmacological treatment of postischemic hypotension. In 8 out of 15 animals spontaneous heart action with systolic arterial blood pressure above 80 mm Hg returned. In these 8 cats cerebral blood flow was temporarily increased and signs of neuronal functions returned: the evoked pyramidal response started to reappear after 5 min, the cortical evoked potentials after 40 min, and spontaneous electrocortical activity after 45 min. Within 6 h the pyramidal response returned to 100%, the evoked potential to 75% and the EEG to 60% of their control amplitudes. In the cats in which systolic blood pressure was below 80 mm Hg, cerebral blood flow was not increased, and signs of functional recovery did not return or returned only transitorily. It is concluded that, with the techniques used, the return of neuronal functions after cardiac arrest is limited by the vulnerability of the heart and not that of the brain.     

Amlodipine lowers blood pressure without significant effect on cerebral blood flow in hypertensive patients with a history of stroke: a quantitative single photon emission computed tomography study

Appropriate antihypertensive therapy is important to prevent cerebrovascular disease. The purpose of the present study was to investigate the effect of such therapy on cerebral blood flow in stroke patients. Twenty hypertensive patients with a history of ischemic stroke received amlodipine 2.5 or 5 mg daily for 12 weeks. Blood pressure and cerebral blood flow as measured by ¹³³Xe single photon emission computed tomography at baseline and were compared at 12 weeks. There were statistically significant reductions in both systolic (167.0 to 140.9 mm Hg) and diastolic (97.8 to 81.8 mm Hg) blood pressures after 12 weeks of amlodipine treatment. No statistically significant effect was observed on cerebral blood flow (46.7 to 46.9 ml/100g brain/min). A weak but statistically significant change was observed in cerebellar blood flow (44.1 to 46.9 ml/100g brain/min). We concluded that amlodipine reduces blood pressure without affecting cerebral blood flow in hypertensive patients with a history of ischemic stroke. Investigation about its effect on cerebellar blood flow is mandatory.     

Brief hypoxia-ischemia initially damages cerebral neurons.

Rats were studied during cerebral hypoxic ischemia to determine whether neurons or blood vessels suffered the first damage. Ten or more minutes of unilateral carotid artery occlusion combined with systemic hypoxemia (PaO-2, 21 mm Hg) produced neuronal but not vascular damage in the ipsilateral cerebral hemispheres of 18 of 29 rats (62%); two and five minute stresses caused no visible neuronal abnormalities. The longer exposures produced more widespread damage, and neuronal loss and gliomesodermal reaction were evident after prolonged survival. Early neuronal changes correlated with abnormalities of motor behavior (P less than .005). Despite neuronal damage that was sometimes extensive, vascular no-reflow developed in only one of 24 animals after 20 and 30 minutes of hypoxia-ischemia. Production of neuronal and neurological abnormalities in the absence of hypotension or vascular no-reflow indicates that hypoxia-ischemia initially damaged cerebral neurons.     

Cerebral carbohydrate metabolism during hypoglycemia and anoxia in newborn rats

The cerebral metabolic responses to perinatal hypoglycemia and anoxia were studied in newborn rats given regular insulin (30 units per kilogram of body weight). Animals were observed for up to 2 hours with no apparent ill effects in spite of blood glucose concentrations of 0.75 mmol per liter. When exposed to 100% nitrogen at 37°C, hypoglycemic animal survived only one-tenth as long as littermate controls with normal blood glucose levels (4.7 mmol/L). Pretreatment of hypoglycemic rats with glucose (10 mmol/kg) 10 and 30 minutes prior to nitrogen exposure nearly completely reversed the anoxic vulnerability. Hypoglycemia led to progressive reductions in crebral glycogen and glucose; however, only glucose reverted to normal levels 20 minutes after systemic glucose administration. The glycolytic intermediates glucose 6-phosphate and lactate were also lower during hypoglycemia. Brain glucose levels below 0.1 mmol per kilogram were associated with a disrupted cerebral energy state, reflected by declines in phosphocreatine (33%) and adenosine triphosphate (ATP) (10%). Cerebral energy utilization (metabolic rate) was minimally reduced (?7.2%) by hypoglycemia and returned to the control value (2.36 mmol ～ P/kg/min) with glucose treatment. The cerebral energy reserves ATP, adenosine diphosphate, and phosphocreatine delined more rapidly and to a lower level in hypoglycemic rats subjected to 2 1/2 minutes of anoxia than in normoglycemic animals rendered similarly hypoxic. The findings suggest that decreased anoxic resistance of hypoglycemic newborn rats is not primarily a function of reduced brain glycogen or altered cerebral metabolic rate. The presence of endogenous cerebral glucose stores combined with continued circulating glucose (cerebrovascular perfusion) appear to be critical factors for maintaining perinatal hypoxic survival.     

Computer-regulated constant pressure ischemia in the rat: the animal model

A system permitting computer control of partial ischemia in the normotensive rat brain was developed. Right carotid cannulation and bilateral subclavian artery occlusion made the input of blood to the brain dependent solely on left carotid artery flow. Perfusion pressure was controlled by partial compression of this artery with a balloon. The system can produce a range of partial ischemic states maintaining perfusion pressures from 4 to 20 mm Hg. The adequacy of the servo-control system was evaluated in greater detail at requested perfusion pressures of 7 and 12 mm Hg in 14 male Sprague-Dawley rats (300-450 g). Experimentally obtained cerebral perfusion pressures of 6.84 (SD = 0.25, n = 7) and 11.72 (SD = 0.89, n = 7) mm Hg, respectively, demonstrate the efficacy of the system. CBFs were concurrently measured at four separate bilaterally symmetric anatomic sites (cortex, hippocampus, thalamus, and substantia nigra). Significant intra- and interhemispheric differences were found to exist, with regional flows monitored ipsilaterally to the carotid balloon exceeding those of the opposite hemisphere. In summary, this acute model of cerebral ischemia permits control of perfusion pressure over the entire critical partial ischemic range.     

Cerebral blood flow during dihydralazine-induced hypotension in hypertensive rats

The cerebrovascular effects of graded, controlled dihydralazine-induced hypotension were studied in rats with renal hypertension (RHR) and spontaneous hypertension (SHR). Repeated measurements of cerebral blood flow (CBF) were made using the intraarterial 133Xenon injection technique in anaesthetised normocapnic animals. Dihydralazine was administered in single increasing i.v. doses (0.1 to 2 mg/kg), and CBF measured after each dose when a stable blood pressure had been reached. From a resting level of 145 +/- 7 mm Hg in RHR and 138 +/- 11 mm Hg in SHR, mean arterial pressure (MAP) fell stepwise to a minimum of around 50 mm Hg. CBF was preserved during dihydralazine induced hypotension, and remained at the resting level of 79 +/- 13 ml/100 g . min in RHR and 88 +/- 16 ml/100 g . min in SHR. Following 2 hours hypotension at the lowest pressure reached, the rats were sacrificed by perfusion fixation and the brains processed for light microscopy. Evidence of regional ischaemic brain damage was found in 4 of 11 animals: in 2 cases the damage appeared to be accentuated in the arterial boundary zones. Although the lower limit of CBF autoregulation in these rats is around 100 mm Hg during haemorrhagic hypotension, dihydralazine brought MAP to around 50 mm Hg without any concomitant fall in CBF. This was interpreted as being due to direct dilatation of cerebral resistance vessels. The combination of low pressure and direct dilatation may have resulted in uneven perfusion, thus accounting for the regional ischaemic lesions.     

Effects of fasting and insulin-induced hypoglycemia on brain cell membrane function and energy metabolism during hypoxia–ischemia in newborn piglets

This study was done to determine the effects of 12 h fasting-induced mild hypoglycemia (blood glucose 60 mg/dl) and insulin-induced moderate hypoglycemia (blood glucose 35 mg/dl) on brain cell membrane function and energy metabolism during hypoxia–ischemia in newborn piglets. Sixty-three ventilated piglets were divided into six groups; normoglycemic control (NC, n=8), fasting-induced mildly hypoglycemic control (FC, n=10), insulin-induced moderately hypoglycemic control (IC, n=10), normoglycemic/hypoxic–ischemic (NH, n=11), fasting-induced mildly hypoglycemic/hypoxic–ischemic (FH, n=12) and insulin-induced moderately hypoglycemic/hypoxic–ischemic (IH, n=12) group. Cerebral hypoxia–ischemia was induced by occlusion of bilateral common carotid arteries and simultaneous breathing with 8% oxygen for 30 min. The brain lactate level was elevated in NH group and this change was attenuated in FH and IH groups. The extent of cerebral lactic acidosis during hypoxic–ischemic insult showed significant positive correlation with blood glucose level (r=0.55, p<0.001). Cerebral Na⁺, K⁺-ATPase activity and concentrations of high-energy phosphate compounds were reduced in NH group and these changes were not ameliorated in FH or IH group. Cortical levels of conjugated dienes, measured as an index of lipid peroxidation of brain cell membrane, were significantly elevated in NH, FH and IH groups compared with NC, FC and IC groups and these increases were more profound in FH and IH with respect to NH. Blood glucose concentration showed significant inverse correlation with levels of conjugated dienes (r=−0.35, p<0.05). These findings suggest that, unlike in adults, mild or moderate hypoglycemia, regardless of methods of induction such as fasting or insulin-induced, during cerebral hypoxia–ischemia is not beneficial and may even be harmful in neonates.     

The temporal evolution of hypoglycemic brain damage

In the course of a study on the pathogenesis of neuronal necrosis in severe hypoglycemia, the morphological characteristics reflecting reversible and irreversible neuronal lesions were examined as a function of time following normalization of blood glucose. To that end, closely spaced time intervals were studied in the rat cerebral cortex before, during, and up to 1 year after standardized pure hypoglycemic insults of 30 and 60 min of cerebral isoelectricity. Both the superficial and deep layers of the cerebral cortex showed dark and light neurons during and several hours after the insult. By electron microscopy (EM) the dark neurons were characterized by marked condensation of both karyoplasm and cytoplasm, with discernible, tightly packed cytoplasmic organelles. The light neurons displayed clustering of normal organelles around the nucleus with clearing of the peripheral cytoplasm. Some cells, both dark neurons and neurons of normal electron density, contained swollen mitochondria with fractured cristae. Light neurons disappeared from the cerebral cortex by 4 h of recovery. Some dark neurons in the superficial cortex and almost all in the deep cortex evolved through transitional forms into normal neurons by 6 h recovery. Another portion of the dark neurons in the superficial cortex became acidophilic between 4 and 12 h, and by EM they demonstrated karyorrhexis with stippled electron-dense chromatin. The plasma membrane was disrupted, the cytoplasm was composed of amorphous granular debris, and the mitochondria contained flocculent densities. These definitive indices of irreversible neuronal damage were seen as early as 4-8 h recovery. Subsequently, the acidophilic neurons were removed from the tissue, and gliosis ensued. Thus, even markedly hyperchromatic "dark" neurons are compatible with survival of the cell, as are neurons with conspicuous mitochondrial swelling. Definite nerve cell death is verified as the appearance of acidophilic neurons at which stage extensive damage to mitochondria is already seen in the form of flocculent densities, and cell membranes are ruptured. Our previous results have shown that hypoglycemic neocortical damage affects the superficial laminae, chiefly layer 2. The present results demonstrate that, following the primary insult, this damage evolves relatively rapidly within the first 4-12 h. We have obtained no evidence that additional necrotic neurons are recruited after longer recovery periods.     

Brain damage in a new hemorrhagic shock model in the rat using long-term recovery

A new shock model in the rat using hemorrhagic hypotension for production of brain damage is described. Hemorrhagic shock was induced by lowering arterial blood pressure with bleeding. The MABP was maintained at approximately 25 mm Hg, accompanied by isoelectric EEG, and then shed blood was retransfused. At 1 week of recovery, morphological and 45Ca autoradiographic changes were examined. No brain damage was observed in rats after 1 min of isoelectric EEG. Mild neuronal damage in the hippocampal CA1 subfield was seen in some animals after 2 min of isoelectric EEG. Severe and consistent neuronal loss in the hippocampal CA1 subfield was recognized after 3 min of isoelectric EEG. Additional damage was also seen in the dentate hilus and the thalamus in some animals. This model can be used to study the pathophysiology of postshock brain damage and to assess new therapies following shock.     

A study of experimental cyanide encephalopathy in the acute phase —Physiological and neuropathological correlation

Summary A study was performed to elucidate the significance of various physiological factors contributing to the pathogenesis of experimental cyanide encephalopathy, such as the systemic arterial blood pressure, venous pressure, common carotid blood flow and local blood flow of the cerebral grey and white matters, and blood gas including pH. The histology and topography of the brain damage was also analysed. Twenty-one cats were divided into four groups. The animals in groups 1, 2 and 3 were subjected to continuous infusion of 0.2% sodium cyanide solution and to the ensuing hypotension below 100 mm Hg by administering a ganglion-blocking drug and by respiratory arrest. Severe damage developed in the deep cerebral white matter, corpus callosum, pallidum and substantia nigra, but the damage of the cerebral cortex and hippocampus was not remarkable. The animals in group 4 that were subjected to cyanide infusion without significant hypotension (above 100 mm Hg), but to the same degree of acidosis as that of the the other groups, had similar morphological changes, but to a lesser degree. On the basis of our physiological and morphological findings, we speculated that the pathophysiological factors of tissue hypoxia and subsequent hypotension operated in cyanide leucoencephalopathy. The topographic selectivity seemed to be related to the characteristic cerebral vascular system, and the severity of the white matter lesions was related to the intensity of both hypoxia and hypotension during cyanide infusion, but not to the extent of acidosis, total dose of cyanide or duration of its infusion per se.Supported by Grants-in-Aid for Scientific Research from the Ministry of Education, Science and Culture of Japan (No. 58770280)     

Platelet-activating factor antagonists reduce excitotoxic damage in cultured neurons from embryonic chick telencephalon and protect the rat hippocampus and neocortex from ischemic injury in vivo

The neuroprotective effects of the platelet-activating factor (PAF) antagonists BN 52020 and BN 52021 were determined in a temperature-controlled model of transient forebrain ischemia in the rat (occlusion of both common carotid arteries combined with lowering of the mean arterial blood pressure to 40 mm Hg for 10 min). After 7 days of recirculation, the ischemic neuronal damage was evaluated histologically within the hippocampus and neocortex. Combined pre- and post-treatment with the PAF antagonists (2 × 25 mg/kg, s.c.) significantly reduced the resulting neuronal damage of the CA1 and CA3 hippocampal subfields and of the occipital and parietal cerebral cortex. The two PAF antagonists were also tested for their neuroprotective activity in primary neuronal cultures isoalted from embryonic chick telencephalon. Since an excessive activation of excitatory amino acid receptors is discussed to be of importance for the ischemic brain damage, the cultured neurons were exposed to the excitatory amino acid L-glutamate (1 mM) for a period of 60 min. Twenty hours after the excitotoxic insult, BN 52020- and BN 52021- treated cultured (1–100 μM) showed both a better preserved morphology, as well as a dose-dependent increase in cell viability and protein content compared to the control cultures. Our results demonstrate that the PAF antagonists BN 52020 and BN-52021 have the capacity to protect brain tissue against ischemic neuronal damge independent of hypothermic effects and are also capable of reducing excitotoxic damage of telencephalic neurons from chick embryos cultured in the absence of glial or endothelial cells. We thus propose that PAF plays an important role in the pathophysiology of ischemic/excitotoxic neuronal injury via a direct action on neurons. © 1993 Wiley-Liss, Inc.     

Hypoglycemic encephalopathy with extensive lesions in the cerebral white matter

Here we report an autopsy case of hypoglycemic encephalopathy with prolonged coma. Laboratory data obtained when the patient lapsed into a coma showed that she had a low level of serum glucose (27 mg/dL). Although the level of glucose returned to within the normal range rapidly after glucose infusion, the patient remained in a coma for 22 months. It was presumed that the state of hypoglycemia persisted for about 4 h. There was no evidence of hypotension or hypoxia. Magnetic resonance imaging was performed 3 h after glucose administration; diffusion‐weighted images revealed hyperintensity in the cerebral white matter and in the boundary zone between the middle and posterior cerebral arteries. Post‐mortem examination revealed superficial laminar necrosis throughout the cerebral cortex. Neuronal necrosis was also found in the hippocampus and dentate gyrus, although the CA3 region appeared normal. In addition to these lesions, which are consistent with hypoglycemia‐induced brain damage, the cerebral white matter exhibited severe loss of myelin and axons with reactive astrocytosis and macrophage infiltration. Old infarcts were also present in the bilateral occipital lobes. Since the cerebral blood flow is reported to be decreased during severe hypoglycemia, the present findings suggest that white matter lesions and boundary‐zone infarctions may develop primarily in uncomplicated hypoglycemia.