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Bicuculline-induced epileptic brain injury (1983)

Söderfeldt, B. ; Kalimo, H. ; Olsson, Y. ; [et al.]

Springer

Acta neuropathologica 62 (1983), S. 87-95

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ISSN: 1432-0533

Keywords: Status epilepticus ; Nerve cell injury ; Bicuculline ; Rat cerebral cortex

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary It was earlier shown that bicuculline-induced status epilepticus gives rise to profound acute changes in the rat cerebral cortex, i.e. edema and neuronal alterations. In the present study, we explored to what extent interruption of the seizure activity reverses the changes observed. To that end, status epilepticus of 1 and 2 h duration was induced by bicuculline before the seizures were arrested by i.v. injection of diazepam. The brain was then fixed by vascular perfusion either 5 min (1 h of seizures) or 2 h (1 and 2 h of seizures) of recovery and cerebral cortical tissue was studied by light (LM) and electron microscopy (EM). Already 5 min following the arrest of seizure activity most of the astrocytic edema had disappeared, and the number of injured neurons was clearly reduced. After 2 h of recovery, following 1 h of status epilepticus, the edema was virtually absent, and only few injured cells were found (only about 1% of the neuronal population). When recovery was instituted after 2 h of status epilepticus, numerous dark, triangular neurons were found. In the last group an adequate blood pressure could not be obtained. Therefore, the cellular alterations observed were probably not the result of the seizure activityper se. After 5 min of recovery, EM studies showed condensed, dark-staining injured neurons, similar to those previously observed in non-recovery animals. However, an increased incidence of swollen mitochondria was observed. After 2 h of recovery a few severely injured neurons remained which showed signs of progressive injury with fragmentation of the cell body.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00684924

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Hypoglycemic brain injury (1980)

Agardh, C. -D. ; Kalimo, H. ; Olsson, Y. ; [et al.]

Springer

Acta neuropathologica 50 (1980), S. 31-41

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Nerve cell injury ; Biochemistry ; Light microscopy ; Rat cerebral cortex

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Profound hypoglycemia causing the disappearance of spontaneous EEG activity was induced by insulin in rats. For analysis of cerebral cortical concentrations of labile phosphates, glycolytic metabolites and amino acids, the brain was frozen in situ. For microscopic analysis of the corresponding cerebral cortical areas the brain was fixed by perfusion. Hypoglycemia with an isoelectric EEG for 30 and 60 min caused severe perturbation of the cerebral energy metabolites. After both 30 and 60 min of isoelectric EEG, two microscopically different types of nerve cell injury were seen. Type I injury was characterized by angulated, darkly stained neurons with perineuronal vacuolation, mainly affecting small neurons in cortical layer 3. Type II injured neurons, mainly larger ones in layers 5–6, were slightly swollen with vacuolation or clearing (depending on the histotechnique used) of the peripheral cytoplasm, but had no nuclear changes. Recovery was induced by glucose injection. Improvement in the cerebral energy state occurred during the 30 min recovery period even after 60 min of hypoglycemia. However, the persisting reduction in the size of adenine nucleotide and amino acid pools after 30 or 180 min recovery suggested that some cells remained damaged. In confirmation many type I injured neurons persisted during the recovery suggesting an irreversible injury. The disappearance of virtually all type II injuries indicated reversibility of these histopathological changes. The microscopic changes in hypoglycemia were different from those in anoxia-ischemia suggesting a dissimilar pathogenesis in these states despite the common final pathway of energy failure.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688532

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Pathogenesis of brain lesions caused by experimental epilepsy (1983)

Atillo, A. ; Söderfeldt, B. ; Kalimo, H. ; [et al.]

Springer

Acta neuropathologica 59 (1983), S. 11-24

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ISSN: 1432-0533

Keywords: Status epilepticus ; Nerve cell injury ; Brain edema ; Rat hippocampal formation

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Status epilepticus with a duration of 1 or 2 h was induced in rats by i. v. injection of the GABA receptor blocking agent, bicuculline. Immediately there-after, or following a 2 h recovery period, the brains were fixed by vascular perfusion and processed for light and electron microscopy to characterize the type and distribution of morphological changes in the hippocampal formation. In a previous study (Söderfeldt et al. 1981) astrocytic edema and wide-spread neuronal changes of two different kinds occurred in the fronto-parietal cortex of the same animals. Type 1 injured neurons were characterized by condensation of karyoplasm and cytoplasm (type 1a), which in some neurons became so intense that the nucleus could no longer be clearly discerned (type 1b). The type 2 injured neurons had slitformed cytoplasmic vacuoles chiefly caused by dilatation of the rough endoplasmic reticulum. In the hippocampus the most conspicuous alteration was astrocytic edema which was most marked around the perikarya of pyramidal neurons in CA1-CA4 and subiculum. In the dentate gyrus the edema was less pronounced and, when present, affected particularly the hilar zone of the stratum granulosum. The nerve cell changes were less pronounced than in the cerebral cortex. The vast majority of the hippocampal pyramidal neurons in CA1-CA4 showed minor configurational and tinctorial abnormalities (incipient type 1a change). Severe nerve cell alterations (type 1b) were present but very rarely affected the pyramidal neurons of CA1-CA4 and subiculum, whereas in the dentate gyrus pyramidal basket neurons of stratum granulosum and pyramidal nerve cells in stratum polymorhe showed the severe type 1b changes. As compared with the frontoparietal cortex (Söderfeldt et al. 1981) the type 2 changes were extremely rare. In the early recovery period after 1 h of status epilepticus the astrocytic edema and the incipient type 1a changes had almost entirely disappeared, whereas a few condensed and dark-staining type 1b injured neurons remained. Thus, in this model of status epilepticus the most marked response in the hippocampal formation is astrocytic edema in the layers where pyramidal perikarya are located. Incipient, mild nerve cell changes which appear to be reversible were frequent and widespread in the entire hippocampal formation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00690312

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Morphological lesions in the brain preceding the development of postischemic seizures (1988)

Smith, M. -L. ; Kalimo, H. ; Warner, D. S. ; [et al.]

Springer

Acta neuropathologica 76 (1988), S. 253-264

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ISSN: 1432-0533

Keywords: Cerebral ischemia ; Rat ; Hyperglycemia ; Postischemic seizures ; Substantia nigra

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary This study explores how hyperglycemia and enhanced tissue lactic acidosis influence the density and distribution of ischemic brain damage. Ischemia of 10-min duration was produced in glucose-infused rats by bilateral carotid clamping combined with hypotension, and the brains were perfusion-fixed with formaldehyde following recirculation of 3, 6, 12 and 18 h. After about 24 h the hyperglycemic animals developed seizures, and at that time two groups were added, one fixed prior to, and one after the onset of seizures. Similar experiments were made on normoglycemic animals with recirculation times of 1.5 to 96 h. After fixation the brains were embedded in paraffin, subserially sectioned and stained with celestine blue/acid fuchsin. In both normo- and hyperglycemic animals, neurons in the dentate hilus of the hippocampal formation and in the thalamic lateral reticular nucleus showed early and dense neuronal necrosis. In neocortex, hippocampal CA1 sector and caudoputamen, hyperglycemia shortened the delay before damage occurred and markedly enhanced the damage. Specific for the hyperglycemic animals was damage of the substantia nigra, pars reticulata (SNPR), manifest already at the earliest recovery periods studied; this finding is discussed in relationship to the role SNPR is assumed to play in preventing spread of seizure discharge.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00687772

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Substantia nigra damage induced by ischemia in hyperglycemic rats (1987)

Inamura, K. ; Olsson, Y. ; Siesjö, B. K.

Springer

Acta neuropathologica 75 (1987), S. 131-139

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ISSN: 1432-0533

Keywords: Cerebral ischemia ; Hyperglycemia ; Substantia nigra ; Electron microscopy

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Preischemic hyperglycemia induced by feeding or glucose infusion worsens the brain damage and the clinical outcome following ischemia of a given duration and density, and characteristically causes postischemic seizure activity. Light microscopy has previously showed that, in the rat, transient hyperglycemic ischemia induced by bilateral carotid occlusion in combination with arterial hypotension causes a uni- or bilateral lesion in the pars reticulata of the substantia nigra. Since this region has a central role in preventing seizure discharges the present study was carried out to determine the ultrastructural characteristics of this lesion. In rats with 10 min of transient hyperglycemic ischemia followed by recirculation for 1 to 18 h, the pars reticulata of the substantia nigra showed signs of status spongiosus, as well as extensive nerve cell alterations. These changes were observed after all recovery periods studied. The spongiotic appearance was mainly caused by swelling of dendrites and, to a lesser degree, by astrocytic swelling. The dendrites were expanded at all recovery times but the severity increased during the later periods of recirculation. These swollen dendrites contained severely expanded mitochondrias and endoplasmic reticulum. The cytoskeletal elements showed disordered lining of microtubules. Two major types of nerve cell alterations were present: a “pale” and a “dark” variety. The pale type was the most frequent cell alteration. It occurred in all experimental groups and at all time points. Redistribution of the nuclear chromatin and of cytoplasmic organelles as well as swelling of the same type as in the dendrites were the essential changes. The dark neurons were much fewer in number and occupied a peripheral position in the pars reticulata. Astrocytic foot processes appeared to be dilated around the dark neurons. Swelling of astrocyte processes was most pronounced in the 1 h recovery animals. Both types of neurons showed severe mitochondrial alterations of the type observed in dendrites. Occasionally, mitochondrial alterations were found in astrocytic processes as well. Blood vessel alterations were lacking. Previous studies have shown that in this model of ischemia the substantia nigra has a relatively well-preserved blood perfusion. In view of this the extensive histopathological lesions are surprising. We speculate that the lesions primarily involve excitotoxic damage to dendrites, with pronounced lactic acidosis playing a contributory role in causing axonal and glial pathology as well.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00687073

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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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Hypoglycemic brain injury (1980)

Kalimo, H. ; Agardh, C. -D. ; Olsson, Y. ; [et al.]

Springer

Acta neuropathologica 50 (1980), S. 43-52

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Nerve cell injury ; Electron microscopy ; Rat cerebral cortex

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Severe hypoglycemia was induced in rats by insulin. The brain was fixed in situ by perfusion after the spontaneous EEG had disappeared for 30 or 60 min or after recovery had been induced for 30 or 180 min by glucose injection. Samples from the cerebral cortex from the area corresponding to the previous metabolic studies were processed for electron microscopy. The light-microscopic finding of two different types of nerve cell injury, reported in a preceding communication (Agardh et al. 1980), was also verified at the ultrastructural level. The type I injury was characterized by cellular shrinkage, condensation of the cell sap and nuclei, and perineuronal astrocytic swelling. No swelling of mitochondria occurred. The slightly swollen type II injured neurons showed contraction of mitochondria, disintegration of ribosomes, loss of RER, and appearance of membrane whorls, while their nuclear chromatin remained evenly distributed. No transition from one type to the other was observed. Neither type of nerve cell injury in hypoglycemia was like that commonly seen in anoxic-ischemic insults indicating a different pathogenesis in these states despite the common final pathway of energy failure. The loss of endoplasmic membranes and disintegration of ribosomes suggests that these structures might be sacrificed for energy production in the absence of normal substrates. During recovery, though, the number of type I injured neurons decreased while some of the remaining ones appeared even more severely affected, suggesting irreversible damage. Type II injured neurons were no longer seen indicating reversibility of these changes.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688533

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8

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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. 13-24

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ISSN: 1432-0533

Keywords: Hypoglycemia ; Cerebral cortex ; Nerve cell injury ; Dark neurons ; Acidophilic neurons ; Mitochondria ; Golgi apparatus ; Cell necrosis ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 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 karyoplasma 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 mitochondrial 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.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00688120

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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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