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The density and distribution of ischemic brain injury in the rat following 2–10 min of forebrain ischemia (1984)

Smith, M. -L. ; Auer, R. N. ; Siesjö, B. K.

Springer

Acta neuropathologica 64 (1984), S. 319-332

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ISSN: 1432-0533

Keywords: Cerebral ischemia ; Selective vulnerability ; Neuronal necrosis ; Cell death ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The density and distribution of brain damage after 2–10 min of cerebral ischemia was studied in the rat. Ischemia was produced by a combination of carotid clamping and hypotension, followed by 1 week recovery. The brains were perfusion-fixed with formaldehyde, embedded in paraffin, subserially sectioned, and stained with acid fuchsin/cresyl violet. The number of necrotic neurons in the cerebral cortex, hippocampus, and caudate nucleus was assessed by direct visual counting. Somewhat unexpectedly, mild brain damage was observed in some animals already after 2 min, and more consistently after 4 min of ischemia. This damage affected CA4 and CA1 pyramids in the hippocampus, and neurons in the subiculum. Necrosis of neocortical cells began to appear after 4 min and CA3 hippocampal damage after 6 min of ischemia, while neurons in the caudoputamen were affected first after 8–10 min. Selective neuronal necrosis of the cerebral cortex worsened into infarction after higher doses of insult. Damage was worst over the superolateral convexity of the hemisphere, in the middle laminae of the cerebral cortex. The caudate nucleus showed geographically demarcated zones of selective neuronal necrosis, damage to neurons in the dorsolateral portion showing an all-or-none pattern. Other structures involved included the amygdaloid, the thalamic reticular nucleus, the septal nuclei, the pars reticularis of the substantia nigra, and the cerebellar vermis.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00690397

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2

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Mechanisms of hypoglycemic brain damage (1988)

Lindvall, O. ; Auer, R. N. ; Siesjö, B. K.

Springer

Experimental brain research 73 (1988), S. 219-223

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ISSN: 1432-1106

Keywords: Hypoglycemia ; Brain damage ; Noradrenaline ; Locus coeruleus

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Selective lesions of the noradrenergic locus coeruleus (LC) system have recently been shown to aggravate both ischemic and epileptic brain damage. This study explores the possibility that the LC system also influences hypoglycemic brain injury. Bilateral 6-hydroxydopamine lesions of the LC projection to the forebrain were found to cause no change in the degree of neuronal necrosis in the neocortex, hippocampal formation and caudateputamen following 30 min of reversible insulin-induced hypoglycemic coma. We propose that selective neuronal necrosis in ischemia and status epilepticus is due to the action of excitatory amino acids at synaptic sites, which can be partly counteracted by noradrenaline release from inhibitory LC terminals. In hypoglycemia, excitatory amino acids probably cause brain damage via a local and more diffuse toxic effect which is not significantly influenced by the activation of the LC system.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00279676

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3

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Ischemic penumbra in a model of reversible middle cerebral artery occlusion in the rat (1992)

Memezawa, H. ; Minamisawa, H. ; Smith, M. -L. ; [et al.]

Springer

Experimental brain research 89 (1992), S. 67-78

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ISSN: 1432-1106

Keywords: Cerebral ischemia ; Experimental stroke ; Recirculation ; Cerebral blood flow ; Brain damage ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary It has become increasingly clear that a stroke lesion usually consists of a densely ischemic focus and of perifocal areas with better upheld flow rates. At least in rats and cats, some of these perifocal (“penumbral”) areas subsequently become recruited in the infarction process. The mechanisms may involve an aberrant cellular calcium metabolism and enhanced production of free radicals. In general, though, the metabolic perturbation in the penumbra requires better characterization. The objective of this article was to define flow distribution in a rat model of reversible middle cerebral artery (MCA) occlusion, so as to allow delineation of the metabolic aberrations responsible for the subsequent infarction. We modified the intraluminal filament occlusion model recently developed by Koizumi et al. (1986), and described in more detail by Nagasawa and Kogure (1989), adopting it for use in both spontaneously breathing and artificially ventilated rats. Successful occlusion of the MCA (achieved in about 9/10 rats) was judged by unilateral EEG depression in ventilated rats, and neurological deficits, such as circling, in spontaneously breathing ones. CBF in the ipsilateral hemisphere was reduced to nearly constant values after 20, 60, and 120 min of occlusion, flow rates in the focus being about 10% and in the perifocal ipsilateral areas about 15–20% of control (contralateral side). When the filament was left in place (permanent occlusion) 2,3,5-triphenyl tetrazolium chloride (TTC) staining and histopathology after 24 h showed a massive infarct on the occluded side, extending from caudoputamen and overlaying cortex to the occipital striate cortex. Animals recirculated after 60 min of MCA occlusion, and allowed to survive 7 days for histopathology, showed infarction of the caudoputamen (lateral part or whole nucleus) in 5/6 animals and selective neuronal necrosis in one animal. The neocortex showed either infarcts, selective neuronal necrosis, or no damage. There was some overlap between neocortical areas which were infarcted and those which were salvaged by reperfusion. In general, though, both the CBF data and the recovery studies with a histopathological endpoint define large parts of the neocortex as perifocal (penumbral) areas which lend themselves to studies of metabolic events leading to infarction.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00229002

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Selective lesions of mesostriatal dopamine neurons ameliorate hypoglycemic damage in the caudate-putamen (1986)

Lindvall, O. ; Auer, R. N. ; Siesjö, B. K.

Springer

Experimental brain research 63 (1986), S. 382-386

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ISSN: 1432-1106

Keywords: Hypoglycemia ; Brain damage ; Striatum ; Dopamine ; Mesostriatal system

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Unilateral 6-hydroxydopamine lesion of the mesostriatal dopaminergic system was found to ameliorate neuronal necrosis in the caudate-putamen following 30 min of insulin-induced hypoglycemic coma. We propose that increased release of dopamine in the striatum during hypoglycemia or in the recovery period potentiates a deleterious neuronal hyperexcitation, probably induced by excessive release of glutamate or related compounds, thereby aggravating neuronal necrosis.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00236856

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The distribution of hypoglycemic brain damage (1984)

Auer, R. N. ; Wieloch, T. ; Olsson, Y. ; [et al.]

Springer

Acta neuropathologica 64 (1984), S. 177-191

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Cerebral damage ; Cerebrospinal fluid ; Interstitial fluid ; Neuronal necrosis

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: 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.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688108

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6

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The temporal evolution of hypoglycemic brain damage (1985)

Auer, R. N. ; Kalimo, H. ; Olsson, Y. ; [et al.]

Springer

Acta neuropathologica 67 (1985), S. 25-36

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Hippocampus ; Neuronal necrosis ; Mitochondria ; Astrocyte ; Endothelial microvilli

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Part I of this paper has documented the evolution of dark neurons into acidophilic neurons in the superficial laminae as well as the reversion of dark neurons to normal neurons in the deep laminae of the cerebral cortex in hypoglycemic brain damage. The present study describes the temporal evolution of hypoglycemic brain damage in the hippocampus. The evolution of dark neurons to acidophilic neurons was confirmed in this brain region. Four additional problems were addressed: Firstly, delayed neuronal death was looked for, and was found to occur in areas of CA1 undergoing mild damage. However, it was not preceded by a morphological free interval, had ultrastructural characteristics distinct from delayed neuronal death in ischemia, and hence should be considered a distinct phenomenon. Secondly, the gradient in the density of neuronal necrosis in the rat hippocampal pyramidal cell band was exploited to test the hypothesis that a more severe insult causes a more rapid evolution of neuronal changes. This was found to be the case, with a temporal spectrum in the timing of neuronal death: Necrosis occurred already after 2 h medially in the sobiculum, and was delayed by up to several weeks laterally in CA1. Thirdly, the almost universal sparing of CA3 pyramidal neurons after 30 min hypoglycemic isoclectricity was exploited to address the question of whether reactive changes, which could with certainty be deemed reversible, occur in CA3. Mitochondrial injury was seen in these cells, and was found to be recoverable. No reactive changes of the type previously described following ischemic insults were observed. Fourthly, the astrocytic and vascular response of the tissue was studied. A sequence of astrocytic changes representing structural and probably metabolic activation of astrocytes was seen, consisting of morphological indices of increased turnover of cellular components. Capillaries demonstrated endothelial pits, vesicles, and prominent microvilli hours to days after recovery. The results demonstrate that, in the hippocampal gyrus as in other brain regions, hypoglycemic brain damage is distinct from ischemic brain damage and likely has a different pathogenesis.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688121

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The temporal evolution of hypoglycemic brain damage (1985)

Kalimo, H. ; Auer, R. N. ; Siesjö, B. K.

Springer

Acta neuropathologica 67 (1985), S. 37-50

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Cerebral damage ; Dark neurons ; Neuronal necrosis ; Caudate ; Putamen ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The caudate nucleus and putamen belong to the selectively vulnerable brain regions which incur neuronal damage in clinical and experimental settings of both hypoglycemia and ischemia. We have previously documented the density and distribution of the hypoglycemic damage in rat caudoputamen, but the evolution of the injury, i.e., the sequence of structural changes, has not been assessed. Therefore, in the present study we analyze the light and electron microscopic alterations in the caudoputamen of rats exposed to standardized, pure insults of severe hypoglycemia with isoelectric EEG for 10–60 min, or in rats which, following insults of 30 or 60 min, were allowed to recover for periods from 5 min to 6 months. The hypoglycemic insult produced severe nerve cell injury in the dorsolateral caudoputamen. Immediately after the insult abnormal light neurons with clearing of the peripheral cytoplasm were present. These cells disappeared early in the receovery period, as they do in the cerebral cortex. Dark neurons were also present, but unlike those in the cerebral cortex they did not appear until recovery was instituted. Their number increased for a couple of hours and they became acidophilic within 4–6 h. At this stage, electron microscopy revealed severe clumping of the nuclear chromatin and cytoplasm as well as incipient fragmentation of cell membranes, all these changes indicating an irreversible injury. Within 24 h flocculent densities appeared in the mitochondria and by day 2–3 of recovery the great majority of the medium-sized neurons had undergone karyorrhexis and cytorrhexis, their remnants being subsequently removed by macrophages. After some weeks only large and a few medium-sized neurons remained amidst reactive astrocytes and numerous macrophages. The delay in the appearance of dark, lethally injured medium-sized neurons until the recovery was instituted suggests an effect that does not become apparent until the substrate supply and energy production are restored. Furthermore, it pointt out again the selectivity of the hypoglycemic nerve cell injury with respect to the type (metabolic characteristics?) and topographic location of the neurons.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688122

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