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Edema formation and cellular alterations following spinal cord injury in the rat and their modification with p-chlorophenylalanine

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Summary

The possibility that serotonin can modify the early pathological sequences occurring in spinal cord trauma was investigated in a rat model. To that end we took advantage of the possibility of influencing serotonin pharmacologically by treating animals with a serotonin synthesis inhibitor, p-chlorophenylalanine (p-CPA) before the production of the injury and compared the results with injured, untreated controls. A unilateral incision was made into the dorsal horn of the lower thoracic cord (about 2.5 mm deep, 4.5 mm long) and the trauma. The injured region from untreated animals showed macroscopically at that time a pronounced swelling and the water content had increased by 3.5% as compared to intact controls. The segments rostral and caudal to the lesion also exhibited a profound increase in water content. Light microscopy revealed a significant expansion of the spinal cord as compared to controls. The swelling was most pronounced in the gray matter on the injured side. Electron microscopy showed distorted neurons, swollen astrocytes and extracellular edema in the gray matter in and around the primary lesion. There was also a sponginess in the surrounding white matter with disruption of myelin, collapsed axons and widened periaxonal spaces. Pretreatment of the rats with p-CPA significantly reduced the swelling of the injured spinal cord and there was no visible expansion. The ipsilateral edema in the central gray matter was considerable less pronounced as compared to that in untreated animals. The increase in water content was less than 1% in these animals. The neuronal and glial cell changes were also markedly reduced in the drugtreated rats. The disruption of myelin and the vacuolation of the gray matter were much less severe. Our results show that p-CPA can markedly modify the edema and the cellular changes occurring in the traumatic spinal injury and indicate that serotonin is somehow involved in the production of the early, and thus important, pathological events.

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Authors and Affiliations

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

    H. S. Sharma & Y. Olsson

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  1. H. S. Sharma
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  2. Y. Olsson
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Additional information

Supported by grants from the Swedish Medical Research Council, project 12X-03020, 1987 Års Stiftelse för Strokeforskning, Trygg Hansa, the Multiple Sclerosis Society of Sweden, Wallenius Line and Söderbergs stiftelser

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Sharma, H.S., Olsson, Y. Edema formation and cellular alterations following spinal cord injury in the rat and their modification with p-chlorophenylalanine. Acta Neuropathol 79, 604–610 (1990). https://doi.org/10.1007/BF00294237

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  • DOI: https://doi.org/10.1007/BF00294237

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