Delayed kindling epileptogenesis and increased neurogenesis in adult rats housed in an enriched environment.

Environmental risk factors such as stressful experiences have long been recognized to affect seizure susceptibility, but little attention has been paid to the potential effects of improving housing conditions. In this study, we investigated the influence of an enriched environment on epileptogenesis. Epileptic susceptibility was assessed in animals housed in an enriched environment either before and during (group I) or only during (group II) a kindling procedure and in animals placed in isolated conditions (group III). The kindling paradigm provides a reliable assessment of the capacity to develop seizures following repeated daily low-frequency electrical stimulations. As both enriched environment and seizures are known to interfere with hippocampal neurogenesis, the number of newly generated dentate cells was assessed before and after the kindling procedure to investigate in more detail the relationship between epileptogenesis and neurogenesis. We found that susceptibility to developing epilepsy differed in animals housed in complex enriched environments and in those housed in isolated conditions. Kindling epileptogenesis occurred significantly later in animals housed in enriched conditions throughout the procedure (group I) than in animals from groups II and III. We also demonstrated that cells generated during kindling survived for at least 42 days and that these cells were more numerous on both sides of the brain following environmental enrichment than in rats housed in isolated conditions. As similar values were obtained regardless of the duration of the period of enrichment, these cellular changes may not play a major role in delaying kindling development. We suggest that the increase response in neurogenesis following seizures may be an adaptative rather an epileptogenic response.

A model of 'epileptic tolerance' for investigating neuroprotection, epileptic susceptibility and gene expression-related plastic changes.

Previous insult, for example, sustained epileptic seizures, confers a substantial temporary protection against the cellular damage induced by subsequent epileptic challenge. Here we describe a useful model of this so-called 'epileptic tolerance'. Expression of a status epilepticus was triggered by infusing the excitotoxic agent, kainate, into the right hippocampus of adult rats. An appropriate dose of kainate was used to cause brain damage in the homolateral, but not contralateral, hippocampus. At various times following this preconditioning insult, kainate was then re-administered into the lateral ventricle and neuroprotection was observed in the contralateral side between 1 and 15 days later. This model can be used to investigate the mechanisms of this endogenous neuroprotection. It is also particularly suitable for studying the epileptic susceptibility, as reflected by the modifications of the after-discharge threshold, as well as any changes in gene expression induced associated with the preconditioning episode.