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The effect of experimental epilepsy induced by penicillin administration during pregnancy on nestin expression in the immature rat cerebellum

A light, electron microscopic, and immunohistochemical study

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Abstract

Introduction

Recent knowledge regarding the effect of epileptic seizures in pregnant women on newborns was limited and, therefore, it was difficult to suggest the proper clinical guidelines and to take precautions against it. Studies evaluating the morphological effects of epileptic seizure during pregnancy on newborns in various experimental models are valuable. Therefore, the current study was designed to investigate the morphological changes in the cerebellum of newborn pups of rats subjected to experimental epilepsy during pregnancy.

Materials and methods

Swiss Albino rats were divided into three groups (six animals in each). In the first group (experimental group) an acute grand mal epileptic seizure was induced by 400 IU penicillin-G administration into their intrahippocampal CA3 region with a stereotaxic device during the 13th day of their pregnancy. The second group (intrahippocampal saline-injected sham group) and the third group (untreated animals) were the control groups. On the 1st neonatal day, pups were perfused with intracardiac fixative solution under anesthesia, and newborn cerebellums were dissected surgically for light and electron microscopic studies.

Results

In an immunohistochemical study using Rat-401 monoclonal antibody and peroxidase, the intermediate filament nestin was detected in the developing cerebellar tissue. Histologically, normal migration and cerebellar maturation were determined in the newborn rat cerebellum in the control and sham-operated groups. It was observed that the morphological structure of the cerebellar cortex in the experimental group was compromised in the early embryonal period. In contrast to the control and sham groups, it was found that nestin (+) cell density was increased in the experimental epilepsy group.

Conclusions

It has been concluded that epileptic convulsions during embryonic life may cause early neurogenesis and delayed maturation, which explains the harmful effects of epileptic grand mal seizures, hypoxia, and obstetric trauma to the embryo at the early stage of neuronal differentiation. However, further studies are necessary to investigate epileptic pregnant phenomena and to characterize the possible relationship between epilepsy and congenital malformations as well as mental retardation.

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Acknowledgements

The authors would like to thank Mrs. Fatma Özdemir and Mr. İsmail Zonguldak for their technical help. This work was supported by The Research Fund of Ege University.

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Correspondence to Mehmet Turgut.

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Uyanıkgil, Y., Baka, M., Yurtseven, M. et al. The effect of experimental epilepsy induced by penicillin administration during pregnancy on nestin expression in the immature rat cerebellum. Childs Nerv Syst 20, 176–182 (2004). https://doi.org/10.1007/s00381-003-0901-3

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