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Substantia nigra damage induced by ischemia in hyperglycemic rats

A light and electron microscopic study

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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.

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Author notes

  1. K. Inamura

    Present address: Second Department of Internal Medicine, Nippon Medical School, 3-5-5 Iidabashi Chiyoda-ku, 102, Tokyo, Japan

Authors and Affiliations

  1. Laboratory for Experimental Brain Research, University Hospital, University of Lund, S-22185, Lund, Sweden

    K. Inamura & B. K. Siesjö

  2. Laboratory of Neuropathology, Institute of Pathology, University of Uppsala, S-75185, Uppsala, Sweden

    Y. Olsson

Authors
  1. K. Inamura
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  2. Y. Olsson
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  3. B. K. Siesjö
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Additional information

Supported by grants from the Swedish Medical Research Council (project 12X-03020 and project 14X-263) and from the U.S. Public Health Service via the N.I.H. (grant No. 5 RO1 NS07838)

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Inamura, K., Olsson, Y. & Siesjö, B.K. Substantia nigra damage induced by ischemia in hyperglycemic rats. Acta Neuropathol 75, 131–139 (1987). https://doi.org/10.1007/BF00687073

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