This study determined differences of fascia dentata (FD) peptide and inhibitory neuroanatomy between patients with epileptogenic hippocampal sclerosis (HS), those with extrahippocampal seizure pathologies, and autopsy comparisons. Surgically treated temporal lobe epilepsy patients were clinically classified into two pathogenic categories: (1) HS with focal mesial temporal neuroimaging and histories of initial precipitating injuries to the brain (n = 18) and (2) non-HS patients with extrahippocampal mass lesions or idiopathic seizures (i.e., without lesions or HS; mass lesion/idiopathic; n = 9). The hippocampal sections were studied for (1) granule cell, hilar, CA4, and CA3 neuron densities; (2) hilar densities and the percentage of neurons immunoreactive (IR) for neuropeptide Y (NPY), somatostatin (SS), and glutamate decarboxylase (GAD); (3) densities of GAD neurons in the lower granule cell and infragranular zone (basket-like cells); (4) the semiquantitative pattern of IR peptides/GAD FD molecular layer axon sprouting; (5) IR gray values (GV) of the FD molecular layers; and (6) the thickness of the supragranular molecular layer. Results showed the following. (1) Compared to autopsies, both HS and mass lesion/idiopathic patients showed less granule cell and CA3 neuron densities, but there were no statistical differences between the latter two pathogenic categories. (2) By contrast, compared to autopsies and mass lesion/idiopathic cases, HS patients showed less hilar and CA4 neuron densities, and there were no differences between autopsies and mass lesion/idiopathic. (3) Compared to autopsies, the NPY and SS hilar neuron densities in HS patients, but not mass lesion/idiopathic cases, were less. (4) Compared to autopsies, the hilar GAD neuron densities for HS and mass lesion/idiopathic patients were not less. (5) In HS patients the averaged percentages of hilar SS neurons were less than autopsies, and no other differences of IR hilar percentages were found. (6) The densities of GAD basket-like neurons and the thickness of the supragranular molecular layer were not different between any combination of pathogenic categories and autopsies. (7) By semiquantitative visual assessments, peptides/GAD axon sprouting into the FD was greater in HS compared to mass lesion/idiopathic or autopsies. (8) Compared to mass lesion/idiopathic cases, in HS NPY outer molecular layer GVs were lower, SS GVs were not different, and GAD inner molecular layer GVs were higher. (9) Analyses comparing the two pathogenic categories and neuron densities with peptides/GAD axon sprouting found six comparisons that correlated sprouting with hilar and CA4 neuron losses, and four comparisons showing greater sprouting in HS compared to mass lesion/idiopathic.
Hippocampal GABA and glutamate transporter IR differ in TLE patients compared with autopsies. These data support the hypothesis that excitatory and inhibitory neurotransmission and seizure susceptibility could be altered by neuronal and glial transporters in TLE patients.
The present study was designed to determine whether inhibitory neurons in human epileptic hippocampus are reduced in number, which could reduce inhibition on principal cells and thereby be a basis for seizure susceptibility. We studied the distribution of GABA neurons and puncta by using glutamate decarboxylase (GAD) immunocytochemistry (ICC) together with Nissl stains. Using quantitative comparisons of GAD-immunoreactive (GAD-IR) neurons and puncta in human epileptic hippocampus and in the normal monkey hippocampus, we found that GAD-IR neurons and puncta are relatively unaffected by the hippocampal sclerosis typical of hippocampal epilepsy where 50-90% of principal (non-GAD-IR) cells are lost. GAD-IR neurons and puncta were not significantly decreased compared with normal monkey. In 6 patients, prior in vivo electrophysiology demonstrated that the anterior hippocampus generated all seizures. The anterior and posterior hippocampus were processed simultaneously, and the counts of hippocampal GAD-IR neurons were numerically greater in anterior than in the posterior hippocampus, where no seizures were initiated. These results indicate that GABA neurons are intact in sclerotic and epileptogenic hippocampus. Computerized image analysis of puncta densities in fascia dentata, Ammon's horn, and subicular complex in epileptic hippocampi (n = 7) were not different from puncta densities in the same regions in normal monkey (n = 2). Hence, despite the significant loss of principal cells (50-90% loss) GABA terminals (GAD-IR puncta) were normal, which suggests GABA hyperinnervation of the remnant pyramidal cells and/or dendrites in human epileptic hippocampus. The apparent increase in puncta ranged from 2 (fascia dentata) to 3.3 (CA1) times normal puncta densities. These findings would suggest increased inhibition and less excitability; however, those regions were epileptogenic. We suggest that GABA terminal sprouting or hyperinnervation of the few remnant projection cells may serve to synchronize their membrane potentials so that subsequent excitatory inputs will trigger a larger population of neurons for seizure onset in the hippocampus and propagation out to undamaged regions of subiculum and neocortex.
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