Marla Kleinholz

Hyperglycemic versus Normoglycemic Stroke: Topography of Brain Metabolites, Intracellular pH, and Infarct Size

Hyperglycemia aggravates brain pathologic outcome following middle cerebral artery (MCA) occlusion in cats. We presently determined if hyperglycemia during occlusion leads to high lactic acid accumulations in the ischemic MCA territory. We measured brain metabolite concentrations in 14 MCA territory sites at 0.5 and 4 h following occlusion in hyper- (20 mM) and normoglycemic (5 mM) cats and correlated these results with previous brain pathologic findings. Hyper- versus normoglycemia during MCA occlusion resulted in significantly higher lactate concentrations in the ischemic territory and more numerous loci with lactates >17 μmol/g. At 0.5 h of occlusion, ATP levels were lower in normoglycemic cats, while at 4 h, ATP was similarly reduced (40%) in both glycemia groups. At 4 h, PCr was more reduced in hyperglycemics secondary to a greater brain tissue acidosis. Carbohydrate substrates at 0.5 h were more markedly depleted in normoglycemics, likely limiting lactate accumulation (34.3% versus only 5.0% of sites in hyperglycemics with glucose <0.5 μmol/g). Although lactate was markedly elevated at both 0.5 and 4 h in hyperglycemic ischemic territories, clip release at 4 versus 0.5 h yields a significantly poorer brain pathologic outcome. Correspondingly, intracellular pH, calculated from the creatine kinase equilibrium, was more markedly depressed at 4 than at 0.5 h of occlusion, demonstrating a time-dependent dissociation between tissue lactate and hydrogen ion accumulations. The present findings show that following MCA occlusion (a) hyperglycemia increases the magnitude and topographic extent of marked tissue lactic acidosis, (b) infarct size following 0.5 h of clip release correlates more closely with tissue acidosis than with lactate concentrations, (c) ischemic tissue ATP concentrations correlate poorly with infarct size, (d) normoglycemia limits lactate accumulation during focal ischemia because tissue glucose is depleted, and (e) early during ischemia, tissue buffering or antiport mechanisms may prevent marked increases in intracellular hydrogen ion activity.

Fatal strokes in hyperglycemic cats.

Hyperglycemia is associated with three- to fourfold larger infarcts than normoglycemia following permanent middle cerebral artery occlusion in cats. We investigated the effects of glycemia on brain outcome when middle cerebral artery blood flow was restored (clip release) after 4 hours of occlusion. Seven of 13 hyperglycemic (22 mM) and one of 12 normoglycemic (6 mM) anesthetized cats developed total middle cerebral artery territory infarcts and hemispheric edema and died of brainstem compression. The remaining six and 11 cats recovered fully and later showed no or only small infarcts. Compared with permanent occlusion, restoration of blood flow after 4 hours reduced infarct volume in all normoglycemic and hyperglycemic cats that survived, but caused a much higher proportion (54% vs. 17%) of hyperglycemic and, for the first time, one normoglycemic cat, to die of infarct extension, hemorrhagic infarct conversion, and total territory edema. Thus, clip release after 4 hours caused some cats to show reduced and others to show augmented tissue damage. Rendering cats hyperglycemic substantially worsened their outcome after reperfusion by increasing their death rate from total territory edema sevenfold. Our results demonstrate that risk/benefit analyses for recanalization efforts in humans should take serum glucose concentrations into account.

Normoglycemia (not hypoglycemia) optimizes outcome from middle cerebral artery occlusion.

We examined the effects of serum glucose concentration during middle cerebral artery (MCA) occlusion in the cat on death rates in animals that died from hemispheric edema and on infarct size in animals that survived. We occluded the MCA permanently in some groups and released the clip after 8 h in others. By injecting or infusing glucose solutions, saline, or insulin, we maintained six animal groups steadily either hyper-, normo-, or slightly hypoglycemic before and for 6 or 8 h after permanent or 8-h temporary MCA occlusion. Studies with these groups revealed a distinct optimal outcome with normoglycemic animals. In three additional groups, we altered the glycemia after permanent occlusion from hyper- to normo- or hypoglycemia and from normo- to hyperglycemia. Two of the three hypoglycemic groups (8-h reversible and permanent hyper- to hypoglycemic occlusions) yielded the worst outcomes in this study, with >10× larger median infarcts than the best outcome group (normoglycemic permanent occlusion). Hyperglycemia also was detrimental and increased infarct size and mortality after permanent occlusion. Restoring the cerebral blood flow after 8 h of occlusion increased the death rate from hemispheric edema compared with a maintained occlusion. Following permanent MCA occlusion, converting from normo- to hyperglycemia or vice versa yielded outcomes intermediate between a sustained normo- or hyperglycemia. A regression analysis of the normo- and hyperglycemic groups and the two groups with glycemia altered after permanent occlusion showed a significant linear correlation between glycemia level at and 1 h after MCA occlusion and median infarct size.

Delayed decreases in specific brain mitochondrial electron transfer complex activities and cytochrome concentrations following anoxia/ischemia

Hyperglycemic, but not normoglycemic cats exposed to anoxia develop neurologic signs following reoxygenation including fasciculations, focal and tonic-clonic seizures and coma after a symptom-free period. These symptomatic hyperglycemic cats may develop brain edema and will show diffuse neuronal injury or brain infarction depending on length of survival. Brain mitochondria isolated from symptomatic but not asymptomatic cats have decreased ADP- and uncoupler-stimulated oxygen consumption rates. Since impaired respiration could result from altered electron transport chain function, we measured cytochrome c, b, and aa3 concentrations and the activities of the five electron transfer complexes in isolated brain mitochondria. In symptomatic cats marked alterations were present in particular in complex IV, cytochrome oxidase, with a 57% reduction in activity and a 45% reduction in prosthetic group (cytochrome aa3) concentrations. Less marked reductions in other segments of the chain included 27% and 41% decreases, respectively, in cytochrome c concentrations and in electron transfer complex II, succinate:ubiquinone oxidoreductase activity. Cytochrome b concentrations and complex I, II and V activities were unchanged. Small but significant decreases in cytochrome aa3 concentrations (18%) and cytochrome oxidase activity (20%) were also present in mitochondria from postanoxic hyperglycemic cats prior to appearance of neurologic signs. These results indicate that delayed decreases in the activities of specific electron transfer complexes are correlated with impaired mitochondrial respiration and neurologic deterioration in postanoxic hyperglycemic cats. However, it is presently unclear if these postanoxic brain mitochondrial alterations are primary or secondary events in the development of brain injury.

Delayed Onset of Neurologic Deterioration following Anoxia/Ischemia Coincides with Appearance of Impaired Brain Mitochondrial Respiration and Decreased Cytochrome Oxidase Activity

We previously demonstrated markedly inhibited brain mitochondrial respiration only in cats that (a) were hyperglycemic at anoxia and (b) had neurologic signs, i.e., fasciculations in tongue or facial muscles or focal seizures following reoxygenation. However, since the relationship between time of onset of mitochondrial dysfunction and neurologic signs was unclear, in the present study we killed postanoxic cats immediately when signs first appeared. Cerebrocortical homogenates and isolated brain mitochondria only from symptomatic cats showed markedly inhibited substrate-, ADP-, and uncoupler-stimulated respiration rates. Cytochrome oxidase activity and cytochrome aa3 concentrations were also markedly reduced in these mitochondria. Since brain mitochondrial function was impaired when neurologic signs first appeared, mitochondrial alterations are an important early organellar change correlated with development of neurologic deterioration following anoxia.

Delayed Neurologic Deterioration Following Anoxia: Brain Mitochondrial and Metabolic Correlates

Abstract: Hyper‐ but not normoglycemic cats exposed to 8 min of anoxia show neurologic signs (fasciculations, myoclonic jerks, seizures) that develop after a symptom‐free period. We examined brain mitochondrial function and metabolite concentrations at 0, 1, 3, and 5 h following exposure to anoxia, to correlate biochemical findings with the presence (“symptomatic”) or absence (“presymptomatic”) of neurologic signs. Brain mitochondria isolated postexposure only from symptomatic cats showed markedly decreased (‐50%), state 3 (ADP‐stimulated), and uncoupler‐stimulated respiration rates with NAD‐ and FAD‐linked substrates. Respiratory control and ADP/oxygen (ADP/O) ratios remained unchanged, indicating, respectively, that coupling and efficiency of ATP synthesis were preserved. Thus, inhibition of electron transport chain function, not phosphorylative activity, may be rate limiting for respiration. During anoxia, hyperglycemic cats showed higher brain lactate levels (26 versus 20 μmol/g), but similar ATP and phosphocreatine concentrations, compared with normoglycemic cats. After exposure, in all animals lactate and phosphocreatine were restored to control levels, whereas ATP remained at 85%. Cats that became symptomatic demonstrated four‐ to sixfold increases in lactate and 50% reductions in phosphocreatine. At 3 and 5 h postexposure, symptomatic animals showed significant reductions in ATP concentrations. We conclude that although initially asymptomatic, hyperglycemic cats exposed to anoxia undergo a neurologic deterioration over several hours following reoxygenation that is correlated with inhibition of mitochondrial respiration, increases in tissue lactate, and decreases in energy state.

Determiners of Fatal Reperfusion Brain Oedema

Brain oedema is an important aspect of infarction from cerebrovascular occlusion. In a cat stroke model where the middle cerebral artery (MCA) was reversibly or permanently occluded, we analyzed the incidence of fatal hemispheral oedema in 35 normo- (6 mM) and 35 hyperglycaemic (20 mM for 6 hours) animals, with (N = 45) and without (N = 25) restoration of blood flow with clip release at 4 and 8 hrs of occlusion. Fatal hemispheral oedema occurred in 23% of cats (16/70) while hyperglycaemia, for one, and restoration of blood flow, for another, each quadrupled its occurrence. Further, evidence of remote oedema in the form of posterior cingulate cortical pressure atrophy from transtentorial herniation was found in animals that were allowed to survive for 2 weeks and that exhibited infarcts that affected 12 to 95% of the MCA territory. Thus, hemispheral oedema in association with MCA occlusion developed sufficiently markedly as to cause transtentorial herniation in 47% of all cats (33/70). We carried out biochemical analyses in 14 hyper- and 10 normoglycaemic cats after 4 hrs of MCA occlusion for ATP, phosphocreatine (PCr), lactate, glucose and glycogen. The biochemical findings then were correlated with the occurrence of reperfusion oedema following clip release after 4 hrs of occlusion point-by-point in the brains. Linear regression analyses of the brain metabolic and pathologic data revealed highly significant (p less than 0.001) correlations of acute oedema with brain tissue ATP and PCr reductions less than 1.5 microM/g, with lactic acid accumulation greater than 20 microM/g and with the extents of reduction in brain tissue glucose concentrations in the ischaemic territories.(ABSTRACT TRUNCATED AT 250 WORDS)