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1

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The brain in extreme respiratory acidosis (1982)

Paljärvi, L. ; Söderfeldt, B. ; Kalimo, H. ; [et al.]

Springer

Acta neuropathologica 58 (1982), S. 87-94

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ISSN: 1432-0533

Keywords: Hypercapnia ; Rat brain ; Ultrastructure ; Cerebral edema

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary It is presently debated how much cellular acidosis contributes to brain cell damage during ischemia and hypoxia. To study the influence of acidosis occurring in the absence of energy failure, extreme hypercapnia was produced in anesthetized, artificially ventilated, and well oxygenated rats by increasing the inspired CO2 concentration until arterialPCO2 reached 150 or 300 mm Hg. At these CO2 tensions intracellular pH falls from a control value of about 7.05 to about 6.85 and 6.65, respectively. After 45 min the brains were fixed in perfusion and processed for light and electron microscopy. AtPaCO2 150 mm Hg no clear neuronal abnormality was detected, but atPaCO2 300 mm Hg some neuronal changes were observed. Notably, the nuclei showed slightly coarser chromatin than normally. In a few nerve cells mild swelling of mitochondria and dispersion of polysomes as well as detachment of ribosomes from the endoplasmic reticulum appeared. In both groups, slight to moderate astrocytic edema developed. Thus, even extreme hypercapnia, with its acompanying marked tissue acidosis, alters ultrastructure in the brain only to such a moderate extent that irreversible cell damage is unlikely. We conclude, therefore, that acidosis occurring during ischemia or hypoxia is detrimental only if pH is further lowered and/or if it occurs in conjunction with cerebral energy failure.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00691646

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Influence of systemic factors on experimental epileptic brain injury (1983)

Söderfeldt, B. ; Blennow, G. ; Kalimo, H. ; [et al.]

Springer

Acta neuropathologica 60 (1983), S. 81-91

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ISSN: 1432-0533

Keywords: Brain injury ; Status epilepticus ; Hyperoxia ; Hypoxia ; Hypotension ; Vitamin E

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary A previous study from the laboratory showed that status epilepticus induced by bicuculline administration to ventilated rats produced astrocytic swelling and nerve cell changes (“type 1 and 2 injury”) particularly in layers 3 and 5 of the neocortex (Söderfeldt et al. 1981). The type 1 injured neurons were characterized by condensation of cyto-and karyoplasm and the less common type 2 cells were characterized by swelling of endoplasmic reticulum including the nuclear envelope. In the present study we explored whether changes in cerebral oxygen availability altered the extent or character of the cellular alterations. Animals with 2 h of status epilepticus were made either hyperoxic (administration of 100% O2), hypoxic (arterialpO2 50 mm Hg) or hypotensive (arterial blood pressure of either 70–75 or 50 mm Hg). Furthermore, we explored whether “oxidative” damage occurred by manipulating tissue levels of α-tocopherol, a known free radical scavenger. Non-epileptic control animals exposed to comparable degrees of hypoxia or hypotension showed no or minimal structural alterations. In the epileptic animals the results were as follows.Hyperoxia did not change the quality or extent of the structural alterations previously observed in normoxic epileptic animals. Neither administration nor deficiency ofvitamin E did modify this pattern of alterations. Inhypoxia the extent of cell damage was the same or somewhat larger than in normoxic, epileptic animals. In addition, neurons often showed cytoplasmic microvacuoles due to swelling of mitochondria. The hypoxic animals also showed swelling of astrocytic nuclei with clumped chromatin. Changes similar to those observed in hypoxic animals also appeared in moderatehypotension (mean arterial blood pressure 50 mm Hg), whereas mild hypotension (70–75 mm Hg) did not change the character of the tissue injury from that seen in hyperoxic or normoxic epileptic rats. The present results demonstrate that the neuronal cell damage that can be observed when the brain is fixed by perfusion after status epilepticus of 2 h duration is not exaggerated by hyperoxia or vitamin E deficiency nor is it ameliorated by a moderate restriction in cerebral oxygen supply or by vitamin E administration. If anything, hypoxia (or moderate hypotension) appears to increase the extent of damage and it clearly alters its ultrastructural characteristics. However, although the results fail to support the notion that epileptic cell damage is “oxidative”, definite conclusions must await information on the cell damage that remains upon arrest of the epileptic activity.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00685351

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3

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Reply to the remarks by J. B. Brierley and A. W. Brown (1981)

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

Springer

Acta neuropathologica 55 (1981), S. 323-325

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ISSN: 1432-0533

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00690997

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4

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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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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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6

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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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7

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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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8

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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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9

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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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Brain Cortical Fatty Acids and Phospholipids During and Following Complete and Severe Incomplete Ischemia (1982)

Rehncrona, S. ; Westerberg, E. ; Åkesson, B. ; [et al.]

Oxford, UK : Blackwell Publishing Ltd

Journal of neurochemistry 38 (1982), S. 0

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ISSN: 1471-4159

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Medicine

Notes: Abstract: To explore the possibility that peroxtdative degradation of brain tissue lipid constituents is an important mechanism of irreversible ischemic damage, we measured cortical fatty acids and phospholipids during reversible brain ischemia in the rat. Neither complete nor severe incomplete ischemia (5 and 30 min) caused any measurable breakdown of total or individual fatty acids or phospholipids. Except for a small (and reversible) decrease of inositol plus serine phosphoglycerides in the early postischemic period following 30 min of incomplete ischemia, there were no significant losses of fatty acids or phospholipids during recirculation. Since peroxidation, induced in brain cortical tissue in vitro, characteristically involves degradation of polyenoic fatty acids (arachidonic and docosahexaenoic acids) and of ethanolamine phosphoglycerides, the present in vivo results fail to support the hypothesis that peroxidation of membrane lipids is of primary importance for ischemic brain cell damage. Both complete and severe incomplete ischemia caused a similar increase in the tissue content of free fatty acids (FFA). Thus the FFA pool increased by about 10 times during a 30-min ischemic period, to constitute 1 - 2% of the total fatty acid pool. Since there was a relatively larger increase in polyenoic FFA (especially in arachidonic acid) than in saturated FFA, the release of FFA may be the result of activation of a phospholipase A2 unbalanced by reesterification. Increased levels of FFA persisted during the initial recirculation period, but a gradual normalization occurred and the ischemic changes were essentially reversed at 30 min after restoration of circulation. The pathophysiological implications of the changes in FFA are discussed with respect to mitochondrial dysfunction, formation of cellular edema and prostaglandin-mediated deterioration of postischemic circulation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1471-4159.1982.tb10857.x

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