Neonatal death in mice lacking cardiotrophin-like cytokine is associated with multifocal neuronal hypoplasia

Mice with null mutations of ciliary neurotrophic factor (Cntf) receptor alpha (Cntf-Ralpha), or cytokine-like factor 1 (Clf), one component of Cntf-II (a heterodimeric Cntf-Ralpha ligand), die as neonates from motor neuron loss affecting the facial nucleus and ventral horn of the lumbar spinal cord. Exposure to cardiotrophin-like cytokine (Clc), the other putative Cntf-II element, supports motor neuron survival in vitro and in ovo. Confirmation that Clc ablation induces an equivalent phenotype to Clf deletion would support a role for Clc in the functional Cntf-II complex. In this study, Clc knockout mice had decreased facial motility, did not suckle, died within 24 hours, and had 32% and 29% fewer motor neurons in the facial nucleus and lumbar ventral horn, respectively; thus, Clc is essential for motor neuron survival during development. The concordance of the Clc knockout phenotype with those of mice lacking Cntf-Ralpha or Clf bolsters the hypothesis that Clc participates in Cntf-II.

CD4+CD45RBHi T cell transfer induced colitis in mice is accompanied by osteopenia which is treatable with recombinant human osteoprotegerin

BACKGROUND AND AIMS

Transfer of CD4+CD45RBHi T cells into semi syngeneic immunodeficient mice represents a model of inflammatory bowel disease (IBD). As patients with IBD often suffer from osteopenia, we studied if this T cell transfer in mice results in osteopenia in addition to colitis, and if treatment with osteoprotegerin (OPG) has effects on the bone mineral density of T cell transferred mice. We also investigated whether osteopenia was due to malabsorption as a result of a dysregulated digestive tract or as a consequence of the inflammatory process.

METHODS

CD4+CD45RBHi or CD4+CD45RBLo T cells (4 x 10(5)) were sorted from CB6F1 and transferred into C.B.17 scid/scid mice. Recipient mice were treated with human IgG1 Fc (control) or Fc-OPG three times per week in a prophylactic regimen as well as a therapeutic regimen (after 10% body weight loss) and were evaluated for osteopenia and colitis.

RESULTS

Mice that received CD4+CD45RBHi T cells developed osteopenia (as indicated by decreased bone density accompanied by decreased osteoblasts and increased osteoclasts) and colitis (as indicated by histological changes in the large intestine). Mice that received CD4+CD45RBLo T cells developed neither osteopenia nor colitis. All animals consumed, on average, the same amount of food and water over the course of the study. Prophylactic treatment with Fc-OPG increased bone density in mice that received either CD4+CD45RBHi or CD4+CD45RBLo T cells but had no effects on the gastrointestinal tract. Fc-OPG treatment of osteopenic mice with established IBD caused the normalisation of bone density. Osteopenia in CD4+CD45RBHi T cell recipients was accompanied by hypoparathyroidism that was partially normalised by treatment with Fc-OPG. CD4+CD45RBHi T cell recipients also had a bone marrow inflammatory cell infiltrate expressing tumour necrosis factor alpha which was unaffected by treatment with Fc-OPG.

CONCLUSIONS

CD4+CD45RBHi T cell transfer results in osteopenia in addition to colitis. Evidence suggests that this osteopenia was induced by inflammatory cell infiltration and not by malabsorption of calcium. Recombinant human osteoprotegerin effectively treated the osteopenia. OPG may be a useful therapeutic option for treating osteopenia in patients with IBD.

Hippocampal N-methyl-D-aspartate receptor subunit mRNA levels in temporal lobe epilepsy patients

Changes in the subunit stoichiometry of the N-methyl-D-aspartate (NMDA) receptor (NMDAR) alters its channel properties, and may enhance or reduce neuronal excitability in temporal lobe epilepsy patients. This study determined whether hippocampal NMDA receptor subunit mRNA levels were increased or decreased in temporal lobe epilepsy patients compared with nonseizure autopsy cases. Hippocampal sclerosis (HS; n = 16), non-HS (n = 10), and autopsy hippocampi (n = 9) were studied for NMDAR1 (NR1) and NR2A-D mRNA levels by using semiquantitative in situ hybridization techniques, along with neuron densities. Compared with autopsy hippocampi, non-HS and HS patients showed increased NR2A and NR2B hybridization densities per dentate granule cell. Furthermore, non-HS hippocampi showed increased NR1 and NR2B mRNA levels per CA2/3 pyramidal neuron compared with autopsy cases. HS patients, by contrast, showed decreased NR2A hybridization densities per CA2/3 pyramidal neuron compared with non-HS and autopsy cases. These findings indicate that chronic temporal lobe seizures are associated with differential changes in hippocampal NR1 and NR2A-D hybridization densities that vary by subfield and clinical-pathological category. In temporal lobe epilepsy patients, these findings support the hypothesis that in dentate granule cells NMDA receptors are increased, and excitatory postsynaptic potentials should be strongly NMDA mediated compared with nonseizure autopsies. HS patients, by comparison, showed decreased pyramidal neuron NR2A mRNA levels, and this suggests that NMDA-mediated pyramidal neuron responses should be reduced in HS patients compared with non-HS cases.

Hippocampal GABA and glutamate transporter immunoreactivity in patients with temporal lobe epilepsy

OBJECTIVE

Sodium-coupled transporters remove extracellular neurotransmitters and alterations in their function could enhance or suppress synaptic transmission and seizures. This study determined hippocampal gamma-aminobutyric acid (GABA) and glutamate transporter immunoreactivity (IR) in temporal lobe epilepsy (TLE) patients.

METHODS

Hippocampal sclerosis (HS) patients (n = 25) and non-HS cases (mass lesion and cryptogenic; n = 20) were compared with nonseizure autopsies (n = 8). Hippocampal sections were studied for neuron densities along with IR for glutamate decarboxylase (GAD; presynaptic GABA terminals), GABA transporter-1 (GAT-1; presynaptic GABA transporter), GAT-3 (astrocytic GABA transporter), excitatory amino acid transporter 3 (EAAT3; postsynaptic glutamate transporter), and EAAT2-1 (glial glutamate transporters).

RESULTS

Compared with autopsies, non-HS cases with similar neuron counts showed: 1) increased GAD IR gray values (GV) in the fascia dentata outer molecular layer (OML), hilus, and stratum radiatum; 2) increased GAT-1 OML GVs; 3) increased astrocytic GAT-3 GVs in the hilus and Ammon's horn; and 4) no IR differences for EAAT3-1. HS patients with decreased neuron densities demonstrated: 1) increased OML and inner molecular layer GAD puncta; 2) decreased GAT-1 puncta relative to GAD in the stratum granulosum and pyramidale; 3) increased GAT-1 OML GVs; 4) decreased GAT-3 GVs; 5) increased EAAT3 IR on remaining granule cells and pyramids; 6) decreased glial EAAT2 GVs in the hilus and CA1 stratum radiatum associated with neuron loss; and 7) increased glial EAAT1 GVs in CA2/3 stratum radiatum.

CONCLUSIONS

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.

Hippocampal AMPA and NMDA mRNA levels correlate with aberrant fascia dentata mossy fiber sprouting in the pilocarpine model of spontaneous limbic epilepsy

There is considerable controversy whether aberrant fascia dentata (FD) mossy fiber sprouting is an epiphenomena related to neuronal loss or a pathologic abnormality responsible for spontaneous limbic seizures. If mossy fiber sprouting contributes to seizures, then reorganized axon circuits should alter postsynaptic glutamate receptor properties. In the pilocarpine-status rat model, this study determined if changes in alpha amino-3-hydroxy-5-methyl-4-isoxazole-propionate (AMPA) and n-methyl-D-aspartic acid (NMDA) receptor subunit mRNA levels correlated with mossy fiber sprouting. Sprague-Dawley rats were injected with pilocarpine (320 mg/kg; i.p.) and maintained in status epilepticus for 6 to 8 hours (pilocarpine-status). Rats were killed during the: (1) latent phase after neuronal loss but before spontaneous limbic seizures (day 11 poststatus; n = 7); (2) early seizure phase after their first seizures (day 25; n = 7); and (3) chronic seizure phase after many seizures (day 85; n = 9). Hippocampi were studied for neuron counts, inner molecular layer (IML) neo-Timm's staining, and GluR1-3 and NMDAR1-2b mRNA levels. Compared with controls, pilocarpine-status rats in the: (1) latent phase showed increased FD GluR3, NMDAR1, and NMDAR2b; greater CA4 and CA1 NMDAR1; and decreased subiculum GluR1 hybridization densities; (2) early seizure phase showed increased FD GluR3, increased CA1 NMDAR1, and decreased subiculum NMDAR2b densities; and (3) chronic seizure phase showed increased FD GluR2; increased FD and CA4 GluR3; decreased CA1 GluR2; and decreased subiculum GluR1, GluR2, NMDAR1, and NMDAR2b levels. In multivariate analyses, greater IML neo-Timm's staining: (1) positively correlated with FD GluR3 and NMDAR1 and (2) negatively correlated with CA1 and subiculum GluR1 and GluR2 mRNA levels. These results indicate that: (1) hippocampal AMPA and NMDA receptor subunit mRNA levels changed as rats progressed from the latent to chronic seizure phase and (2) certain subunit alterations correlated with mossy fiber sprouting. Our findings support the hypothesis that aberrant axon circuitry alters postsynaptic hippocampal glutamate receptor subunit stoichiometry; this may contribute to limbic epileptogenesis.

Altered hippocampal kainate-receptor mRNA levels in temporal lobe epilepsy patients

This study determined whether hippocampal kainate (KA) receptor mRNA levels were increased or decreased in temporal lobe epilepsy patients compared with nonseizure autopsies. Hippocampal sclerosis (HS; n = 17), nonsclerosis (non-HS; n = 11), and autopsy hippocampi (n = 9) were studied for KA1-2 and GluR5-7 mRNA levels using semiquantitative in situ hybridization techniques, along with neuron densities. Compared with autopsy hippocampi, HS and non-HS cases showed decreased GluR5 and GluR6 hybridization densities per CA2 and/or CA3 pyramid. Furthermore, HS patients demonstrated increased KA2 and GluR5 hybridization densities per granule cell compared with autopsy hippocampi. These findings indicate that chronic temporal lobe seizures were associated with differential changes in hippocampal KA1-2 and GluR5-7 hybridization densities that vary by subfield and pathology group. In temporal lobe epilepsy patients, these results support the hypothesis that pyramidal cell GluR5 and GluR6 mRNA levels are decreased as a consequence of seizures, and in HS patients granule cell KA2 and GluR5 mRNA levels are increased in association with aberrant fascia dentata mossy fiber sprouting and/or hippocampal neuronal loss.

Hippocampal AMPA and NMDA mRNA levels and subunit immunoreactivity in human temporal lobe epilepsy patients and a rodent model of chronic mesial limbic epilepsy

This study compared temporal lobe epilepsy patients, along with kindled animals and self sustained limbic status epilepticus (SSLSE) rats for parallels in hippocampal AMPA and NMDA receptor subunit expression. Hippocampal sclerosis patients (HS), non-HS cases, and autopsies were studied for: hippocampal AMPA GluR1-3 and NMDAR1&2b mRNA levels using in situ hybridization: GluR1, GluR2/3, NMDAR1, and NMDAR2(a&b) immunoreactivity (IR); and neuron densities. Similarly, spontaneously seizing rats after SSLSE, kindled rats, and control animals were studied for: fascia dentata neuron densities: GluR1 and NMDAR2(a&b) IR; and neo-Timm's staining. In HS and non-HS cases, the mRNA hybridization densities per granule cell, as well as molecular layer IR, showed increased GluR1 (relative to GluR2/3) and increased NMDAR2b (relative to NMDAR1) compared to autopsies. Likewise, the molecular layer of SSLSE rats with spontaneous seizures demonstrated more neo-Timm's staining, and higher levels of GluR1 and NMDAR2(a&b) IR compared to kindled animals and controls. These results indicate that hippocampal AMPA and NMDA receptor subunit mRNAs and their proteins are differentially increased in association with spontaneous, but not kindled, seizures. Furthermore, there appears to be parallels in fascia dentata AMPA and NMDA receptor subunit expression between HS (and non-HS) epileptic patients and SSLSE rats. This finding supports the hypothesis that spontaneous seizures in humans and SSLSE rats involve differential alterations in hippocampal ionotrophic glutamate receptor subunits. Moreover, non-HS hippocampi were more like HS cases than hippocampi from kindled animals with respect to glutamate receptors; therefore, hippocampi from kindled rats do not accurately model human non-HS cases, despite some similarities in neuron densities and mossy fiber axon sprouting.

Increased hippocampal AMPA and NMDA receptor subunit immunoreactivity in temporal lobe epilepsy patients

This study determined if hippocampal AMPA and NMDA subunit immunoreactivity (IR) in temporal lobe epilepsy patients was increased compared with nonseizure autopsies. Hippocampi from hippocampal sclerosis patients (HS; n = 26) and nonsclerosis cases (non-HS: n = 12) were compared with autopsies (n = 6) and studied for GluR1, GluR2/3, NMDAR1, and NMDAR2 IR gray values (GV) along with fascia dentata and Ammon's horn neuron densities. Compared with autopsies, non-HS cases with similar neuron densities and HS patients with decreased neuron densities showed: (a) Increased GluR1 GVs in the fascia dentata molecular layer: (b) increased NMDAR1 GVs in the CA3-1 stratum radiatum and greater IR within pyramids; and (c) increased GluR2/3 and NMDAR2 GVs throughout all hippocampal subfields. Furthermore, HS patients showed that relative to the outer molecular layer: (a) GluR1 GV differences were decreased in the CA4/hilar region and CA1 stratum radiatum compared with autopsies; and (b) NMDAR2 GV differences were increased in the inner molecular layer compared with non-HS cases. In temporal lobe seizure patients, these results indicate that AMPA and NMDA receptor subunit IR was increased in HS and non-HS hippocampi compared with nonseizure autopsies. In humans, these findings support the hypothesis that glutamate receptor subunits are increased in association with chronic temporal lobe seizures, which may enhance excitatory neurotransmission and seizure susceptibility.

Anoxia during kainate status epilepticus shortens behavioral convulsions but generates hippocampal neuron loss and supragranular mossy fiber sprouting

In rats, this study determined the impact of systemic hypoxia during late kainate-induced status epilepticus on hippocampal neuron loss and mossy fiber sprouting. Non-fasted Sprague Dawley rats were prepared as follows: Naive controls (n=5); rats placed 2 min in a hypoxia chamber (hypoxia only; n=6); rats that seized for more than 6 h from kainic acid (KA-status; 12 mg/kg; i.p.; n=7); and another KA-status group placed into the hypoxia chamber 75 min after the convulsions started (KA-status/hypoxia; n=16). All rats, except for half of the KA-status/hypoxia animals, were perfused 2 weeks later (short-term). The other 8 KA-status/hypoxia rats were perfused after 2 months (long-term). Hippocampal sections were studied for neuron densities and aberrant mossy fiber sprouting at three ventral to dorsal levels. Fascia dentata (FD) mossy fiber sprouting was quantified as an increase in the inner minus outer molecular layer (IML-OML) gray value (GV) difference. Behaviorally, KA-status/hypoxia rats had a shorter duration of convulsive status epilepticus than KA-status animals without anoxia. Hippocampal sections showed that compared to controls: (1) hypoxia-only rats showed no differences in ventral neuron densities and neo-Timm's stained IML-OML GVs; (2) KA-status rats had decreased CA3 densities and a non-significant increase in ventral IML-OML GV differences; and (3) KA-status/hypoxia short-term animals showed decreased hilar, CA3 and CA1 densities and increased ventral IML-OML GV differences. Compared to KA-status/hypoxia short-term rats, long-term animals showed no differences in ventral hippocampal neuron densities, but middle and dorsal sections demonstrated increased IML-OML GV differences and animals were observed to have spontaneous limbic epilepsy. These results indicate that rats exposed to kainate-induced status epilepticus for over 1 h and then a hypoxic insult had a shorter duration of convulsive status, decreased hippocampal neuron densities and greater FD mossy fiber sprouting than controls and the amount of neuronal damage and sprouting was slightly more than animals subjected to 6 h of kainate-induced status. This supports the hypothesis that a physiologic insult during status can shorten the convulsive episode, but still produce hippocampal pathology with a number of clinical and pathologic similarities to human mesial temporal lobe epilepsy (MTLE).

Human hippocampal AMPA and NMDA mRNA levels in temporal lobe epilepsy patients

This study was designed to determine whether hippocampal neuronal AMPA (alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid) and NMDA (N-methyl-D-aspartate) mRNA levels were differentially increased in temporal lobe epilepsy patients compared with those measured in control tissue from non-seizure autopsies. Hippocampi from hippocampal sclerosis patients (n = 28) and temporal mass lesion cases (n = 12) were compared with those from the autopsies (n = 4), and studied for AMPA GluR1-3 and NMDAR1-2 mRNAs using semi-quantitative in situ hybridization, along with fascia dentata and Ammon's horn neuron densities. Compared with the autopsies, and without correction for neuron counts, the mass lesion cases with neuron densities similar to autopsies showed: (i) significantly increased NMDAR2 hybridization densities for fascia dentata granule cells; (ii) increased AMPA GluR3 mRNA densities for Ammon's horn pyramids; and (iii) similar or numerically increased mRNAs for all other subunits and hippocampal subfields. Compared with the autopsies, hippocampal sclerosis cases with decreased neuron densities showed: (i) significantly decreased AMPA GluR1-2 and NMDAR1-2 hybridization densities for Ammon's horn pyramids and (ii) similar or numerically decreased mRNAs for all other subunits and subfields. However, correcting for changes in neuron densities showed that hippocampal sclerosis patients had increased AMPA and NMDA mRNA levels per neuron compared with autopsies, and in the CA2 resistant sector GluR2 mRNA levels were numerically greater than autopsies and mass lesion cases. Furthermore, relative to autopsies both sclerosis and mass lesion hippocampi showed that, in the stratum granulosum, the greatest mRNA increases were in AMPA GluR1 and NMDAR2 compared with the other mRNAs. In chronic temporal lobe seizure patients these results indicate that mass lesion and sclerosis cases show differential increases in hippocampal AMPA and NMDA mRNA levels per neuron compared with autopsies, especially for AMPA GluR1 and NMDAR2 in fascia dentata granule cells. These findings support the hypothesis that temporal lobe seizures are associated with increased ionotropic glutamate receptor mRNA levels and alterations in receptor subunit composition that probably contribute to neuronal hyperexcitability, synchronization and seizure generation.

In contrast to kindled seizures, the frequency of spontaneous epilepsy in the limbic status model correlates with greater aberrant fascia dentata excitatory and inhibitory axon sprouting, and increased staining for N-methyl-D-aspartate, AMPA and GABA(A) receptors

This study determined whether there were differences in hippocampal neuron loss and synaptic plasticity by comparing rats with spontaneous epilepsy after limbic status epilepticus and animals with a similar frequency of kindled seizures. At the University of Virginia, Sprague-Dawley rats were implanted with bilateral ventral hippocampal electrodes and treated as follows; no stimulation (electrode controls; n=5): hippocampal stimulation without status (stimulation controls; n=5); and limbic status from continuous hippocampal stimulation (n=12). The limbic status group were electrographically monitored for a minimum of four weeks. Four rats had no recorded chronic seizures (status controls), and all three control groups showed no differences in hippocampal pathology and were therefore incorporated into a single group (controls). Eight limbic status animals eventually developed chronic epilepsy (spontaneous seizures) and an additional eight rats were kindled to a similar number and frequency of stage 5 seizures (kindled) as the spontaneous seizures group. At the University of California (UCLA) the hippocampi were processed for: (i) Niss1 stain for densitometric neuron counts; (ii) neo-Timm's histochemistry for mossy fiber sprouting; and (iii) immunocytochemical staining for glutamate decarboxylase, N-methyl-D-aspartate receptor subunit 2, AMPA receptor subunit 1 and the GABA(A) receptor. In the fascia dentata inner and outer molecular layers the neo-Timm's stain and immunoreactivity was quantified as gray values using computer image analysis techniques. Statistically significant results (P<0.05) showed the following. Compared to controls and kindled animals, rats with spontaneous seizures had: (i) lower neuron counts for the fascia dentata hilus, CA3 and CA1 stratum pyramidale; (ii) greater supragranular inner molecular layer mossy fiber staining; and (iii) greater glutamate decarboxylase immunoreactivity in both molecular layers. Greater supragranular excitatory mossy fiber and GABAergic axon sprouting correlated with: (i) increases in N-methyl-D-aspartate receptor subunit 2 inner molecular layer staining; (ii) more AMPA receptor subunit 1 immunoreactivity in both molecular layers; and (iii) greater outer than inner molecular layer GABA(A) immunoreactivity. Furthermore, in contrast to kindled animals, rats with spontaneous seizures showed that increasing seizure frequency per week and the total number of natural seizures positively correlated with greater Timm's and GABAergic axon sprouting, and with increases in N-methyl-D-aspartate receptor subunit 2 and AMPA receptor subunit 1 receptor staining. In this rat limbic status model these findings indicate that chronic seizures are associated with hippocampal neuron loss, reactive axon sprouting and increases in excitatory receptor plasticity that differ from rats with an equal frequency of kindled seizures and controls. The hippocampal pathological findings in the limbic status model are similar to those in humans with hippocampal sclerosis and mesial temporal lobe epilepsy, and support the hypothesis that synaptic reorganization of both excitatory and inhibitory systems in the fascia dentata is an important pathophysiological mechanism that probably contributes to or generates chronic limbic seizures.

Human fascia dentata anatomy and hippocampal neuron densities differ depending on the epileptic syndrome and age at first seizure

This study determined fascia dentata anatomy and hippocampal neuron densities in patients with different epileptic syndromes. Based on presurgical data, patients were classified into: (a) pediatric patients (n=19); (b) temporal mass lesion cases (n=14); and (c) hippocampal sclerosis patients (n=31). Surgically removed hippocampi and autopsies (n=34) were studied for: (a) hippocampal neuron densities; (b) stratum granulosum (SG) widths and lengths; and (c) hilar areas. The number of granule cells and hilar neurons per tissue section were estimated from the neuron densities and fascia dentata area measurements. Results showed that compared with autopsies (p<0.05): (a) pediatric patients had similar SG and hilar areas; granule cell density was lower (but not hilar neuron density); and the estimated number of granule cells was lower (but not the number of hilar neurons); (b) the widths of SG and hilar areas were greater in mass lesion cases; the density of granule cells and hilar neurons was lower; and the total estimated numbers of granule cells and hilar neurons were similar to those of the autopsies; and (c) hippocampal sclerosis patients had wider, yet shorter SG; hilar areas were smaller; granule cell and hilar densities were lower; and the total estimated numbers of granule cells and hilar neurons were lower than those of the autopsy cases. The duration of the seizures did not correlate with lower fascia dentata neuron densities or estimates of total granule cell and hilar neurons. Furthermore, greater SG widths correlated with lower hilar and CA4 neuron densities, but not with age at first seizure or duration of epilepsy. These results indicate that the size of the fascia dentata SG and hilus along with hippocampal neuron densities differ between surgical patients with different epileptic syndromes, and a wider SG was associated with a lower density of end folium neurons. These findings support the hypothesis that hippocampal sclerosis and granule cell dispersion are not the consequence of repetitive seizures beginning at an early developmental age, but seem to differ depending on the type of epileptic syndrome.

Granule cell mRNA levels for BDNF, NGF, and NT-3 correlate with neuron losses or supragranular mossy fiber sprouting in the chronically damaged and epileptic human hippocampus

This study determined in temporal lobe epilepsy patients if there were correlations among hippocampal granule cell expression of neurotrophin mRNAs, aberrant supragranular mossy fiber sprouting, and neuron losses. Consecutive surgically resected hippocampi (n = 9) and comparison tissue from autopsies (n = 3) were studied for: 1. Granule cell mRNA levels using in situ hybridization for brain-derived neurotrophic factor (BDNF), nerve growth factor (NGF), and neurotrophin-3 (NT-3); 2. neo-Timm supragranular mossy fiber sprouting; and 3. Ammon's horn neuron densities. Clinically, patients were classified into those with hippocampal sclerosis (HS; n = 7) and non-HS cases (i.e., mass lesions and autopsies; n = 5). Results showed that compared to non-HS cases, HS patients showed increased granule cell mRNA levels for BDNF, NGF, and NT-3 (p = 0.035, p = 0.04, p = 0.045 respectively; one-tail directional test). Moreover, granule cell BDNF mRNA levels correlated inversely with Ammon's horn neuron densities (p = 0.02) and correlated positively with greater supragranular mossy fiber sprouting (p = 0.02). NGF mRNA levels correlated inversely with Ammon's horn neuron densities (p = 0.02), and NT-3 mRNA levels correlated inversely with age at surgery (p = 0.04) and correlated positively with greater mossy fiber sprouting (p = 0.026). These results indicate in the chronically damaged human hippocampus that granule cells express neurotrophin mRNAs, and mRNA levels correlate with either hippocampal neuron losses or aberrant supragranular mossy fiber sprouting. These data support the hypothesis that in the epileptic human hippocampus, there may be pathophysiologic associations among mossy fiber synaptic plasticity, hippocampal neuron damage, and granule cell mRNA neurotrophin levels.

Glutamate AMPA receptors in the fascia dentata of human and kainate rat hippocampal epilepsy

The present study examined the relationship between the patterns and densities of glutamate AMPA receptor sub-units GluR1 and GluR2/3 in the molecular layer of the fascia dentata and aberrant mossy fiber neoinnervation in human and kainate rat hippocampal epilepsy. Because AMPA sub-units modulate the fast glutamate synaptic transmission, we hypothesized that the AMPA receptor densities would be related to the glutamate-secreting mossy fibers, which could then contribute to seizure generation. In human hippocampal epilepsy, we found that the immunocytochemical labeling of GluR1 and GluR2/3 dendrites was positively related to the densities and spatial locations of the densest, aberrant neo-Timm stained supragranular mossy fibers. We used quantitative densitometry for the mossy fibers. However, the relatively faint and punctate immunocytochemical staining of the receptors did not allow true quantitative densitometry of the dendritic trees because in human epilepsy granule cell densities were decreased on average 50% of normal. Nevertheless, visual observations did confirm spatial relations between dense fascia dentata inner molecular layer mossy fibers and dense AMPA receptor staining. In the outer molecular layer, the mossy fibers were present only in the lower portion, were not densely-stained, and the AMPA receptors were only faintly-labeled. Nevertheless, outer molecular layer AMPA receptor densities were usually present more distally than were the mossy fibers. Experiments were done using intrahippocampal kainate epileptic rats to test the time courses for the changes in mossy fibers and AMPA receptors. The upregulation of inner and outer molecular layer AMPA receptors occurred maximally within 5 days post-kainate injection, prior to any mossy fiber supragranular ingrowth. One hundred and eighty days after ipsilateral kainate the AMPA receptors were increased bilaterally in the inner and outer molecular layers despite the fact that the contralateral aberrant supragranular mossy fibers were minor in comparison to the dense ipsilateral mossy fiber hyperinnervation. These results suggest that in hippocampal epilepsy AMPA receptor numbers increase throughout the length of the molecular layer dendrites; however the AMPA receptor densities are greater in rough relation to the greatest aberrant mossy fiber presynaptic inputs. Interestingly, the receptor upregulation precedes the mossy fiber ingrowth and may play a role in initiating axonal sprouting or in maintaining the aberrant mossy fiber synapses.

Neuron loss, mossy fiber sprouting, and interictal spikes after intrahippocampal kainate in developing rats

This study determined neuron losses, mossy fiber sprouting, and interictal spike frequencies in adult rats following intrahippocampal kainic acid (KA) injections during postnatal (PN) development. KA (0.4 micrograms/0.2 microliters; n = 64) was injected into one hippocampus and saline into the contralateral side between PN 7 to 30 days. Animals were sacrificed 28 to 256 days later, along with age-matched naive animals (controls; n = 20). Hippocampi were studied for: (1) Fascia dentata granule cell, hilar, and CA3c neuron counts; (2) neo-Timm's stained supragranular mossy fiber sprouting; and (3) hippocampal and intracerebral interictal spike densities (n = 13). Mossy fiber sprouting was quantified as the gray value differences between the inner and outer molecular layer. Statistically significant results (p < 0.05) showed the following: (1) Compared to controls, CA3c and hilar neuron counts were reduced in KA-hippocampi with injections at PN 7-10 and PN 12-14 respectively and counts decreased with older PN injections. Granule cell densities on the KA-side and saline injected hippocampi were not reduced compared to controls. (2) In adult rats, supragranular mossy fiber sprouting was observed in 2 of 7 PN 7 injected animals. Compared to controls, increased gray value differences, indicating mossy fiber sprouting, were found on the KA-side beginning with injuries at PN 12-14 and increasing with older PN injections. On the saline-side only PN 30 animals showed minimal sprouting. (3) Mossy fiber sprouting progressively increased on the KA-side with longer survivals in rats injured after PN 15. Sprouting correlated positively with later PN injections and longer post-injection survival intervals, and not with reduced hilar or CA3c neuron counts. (4) On the KA-side, mossy fiber gray value differences correlated positively with in vivo intrahippocampal interictal spike densities. These results indicate that during postnatal rat development intrahippocampal kainate excitotoxicity can occur as early as PN 7 and increases with older ages at injection. This rat model reproduces many of the pathologic, behavioral, and electrophysiologic features of human mesial temporal lobe epilepsy, and supports the hypothesis that hippocampal sclerosis can be the consequence of focal injury during early postnatal development that progressively evolves into a pathologic and epileptic focus.

Childhood generalized and mesial temporal epilepsies demonstrate different amounts and patterns of hippocampal neuron loss and mossy fibre synaptic reorganization

In this study, we determined whether childhood seizures were associated with hippocampal neuron loss and mossy fibre synaptic reorganization and if hippocampal sclerosis evolved from longer seizure histories. Children undergoing surgical treatment for catastrophic epilepsy were grouped into the following pathology categories: (i) those with generalized seizures and extra-hippocampal congenital pathologies (i.e. prenatal cortical dysplasia; n = 17); (ii) cases of generalized seizures and extra-hippocampal acquired lesions. (i.e. postnatal ischaemic injuries and encephalitis; n = 7); (iii) children with complex partial hippocampal epilepsy (n = 4). Further, to determine whether the epileptogenic location influenced hippocampal pathology, the seizure focus was classified as (i) hippocampal, (ii) temporal (n = 13) or (iii) extra-temporal (n = 11). Surgical and autopsy (n = 23) hippocampi were studied for (i) fascia-dentata (FD) and Ammon's horn (AH) neuron densities; (ii) thickness; height or length of the FD molecular layer, stratum granulosum (SG) and stratum pyramidale; and (iii) grey value (GV) densities of supragranular neo-Timm's staining. Statistically significant results (P < 0.05) showed the following. (i) Autopsy hippocampal neuron densities for the hilus (H), AH and prosubiculum (Pro) decreased logarithmically at the same time as the thickness of the stratum pyramidale and Pro increased. By contrast, autopsy granule cell densities and thickness did not significantly change with age; however, the SG lengthened-expanding around the enlarging H. Further, the supragranular molecular layer height increased logarithmically, and took longer than the increase in stratum pyramidale thickness. (ii) Compared with age-matched autopsies, young children with a history of hippocampal seizures showed decreased granule cell, hilar and regio superior neuron densities similar to adults with hippocampal sclerosis (average loss 70%). By contrast, children with extra-hippocampal congenital or acquired pathologies showed only decreased granule cell densities, along with a thinner and shorter SG. Compared with extra-temporal locations, those with temporal lobe lesions showed decreased hilar and AH neuron densities, but averaged 20-30% less than autopsies and not in the pattern typical of hippocampal sclerosis. (iii) The neo-Timm's GV densities, when compared with autopsies, showed supragranular mossy fibre sprouting in children with congenital pathologies and temporal lobe lesions; however, the greatest GVs were in children with hippocampal seizures. (iv) Of the children with extra-hippocampal congenital or acquired pathologies there were no statistical correlations between longer duration of seizures with changes in neuron densities, hippocampal heights, or mossy fibre sprouting. These results indicate the following. (i) In the human there is anatomical evidence for postnatal maturation of the hippocampus and our results are consistent with the notion that AH pyramids are a stable population; however, there are probably increases in granule cell numbers. Further, compared with the AH, dendritic maturation of the FD granule cells appears to take longer. (ii) Extra-hippocampal childhood seizures whether from prenatal or postnatal aetiologies are associated with moderate FD and minimal AH neuron losses and signs of aberrant mossy fibre sprouting. (iii) By contrast, young children with the syndrome of mesial temporal epilepsy show patterns of neuron loss and mossy fibre sprouting, typical of hippocampal sclerosis. (iv) Repeated extra-hippocampal childhood seizures are not associated with progressive evolution of hippocampal damage or mossy fibre sprouting. These findings support the hypothesis that childhood seizures can damage or alter the postnatally developing granule cells of the human hippocampus, and that early neuron loss and aberrant axon circuits may contribute to chronic hippocampal seizures. However, repeated childhood generalized seiz

Aberrant hippocampal mossy fiber sprouting correlates with greater NMDAR2 receptor staining

This study determined in temporal lobe epilepsy patients and rats injected with intrahippocampal kainate (KA) whether fascia dentata molecular layer mossy fiber sprouting was associated with increases in NMDAR2 immunoreactivity (IR). Patients with hippocampal sclerosis (n = 11) were compared with those with temporal mass lesions (n = 7) and material obtained at autopsies (n = 4); and unilateral KA-injected rat hippocampi (n = 7) were compared with the contralateral saline-injected side and non-lesioned animals (n = 7; control). Hippocampi were studied for neo-Timm's stained mossy fiber sprouting and NMDAR2 IR. The staining was quantified as gray values (GV) using computer image analysis. Hippocampal sclerosis patients and KA-injected rats showed the greatest inner molecular layer (IML) mossy fiber sprouting and NMDAR2 staining. Compared with autopsies and patients with mass lesions, hippocampal sclerosis patients had greater IML neo-Timm's (p = 0.0018) and NMDAR2 staining (p = 0.0063). Similarly, compared with controls and saline-injected rats, KA-injected hippocampi showed greater IML mossy fiber sprouting and NMDAR2 IR (p = 0.0001). Furthermore, IML mossy fiber sprouting positively correlated with greater IML NMDAR2 staining in both human and experimental rat groups (p < 0.0099). These results support the hypothesis that in severely damaged hippocampi abnormal mossy fiber sprouting and concordant increases in IML NMDAR2 receptor staining may contribute or partially explain granule cell hyperexcitability and the pathophysiology of hippocampal epilepsy.

The pathophysiologic relationships between lesion pathology, intracranial ictal EEG onsets, and hippocampal neuron losses in temporal lobe epilepsy

In temporal lobe epilepsy (TLE) lesion patients the pathology, location of intracranial ictal EEG onsets, and hippocampal neuron losses were compared. Patients (n = 63) were classified into: (1) Tumors (n = 26, e.g. astrocytomas, gangliogliomas); (2) vascular (n = 9, e.g. cavernous and venous angiomas); (3) developmental (n = 17, e.g. cortical dysplasia, heterotopias); or (4) atrophic (n = 11, e.g. cortical or white matter encephalomalacia). Other variables were; (1) the location of the temporal lesion in the mesial to lateral, and anterior to posterior plane, (2) a clinical history of an initial precipitating injury (IPI) prior to the onset of TLE (e.g. prolonged first seizure, head trauma), (3) hippocampal neuron densities, (4) focal or regional location by intracranial depth EEG of ictal onsets, and (5) seizure outcomes. Results showed that severe hippocampal neuron losses were associated with two statistically significant findings. First, patients with mesial lesions in or adjacent to the body of the hippocampus had greater neuron losses compared to mesial lesions anterior or posterior to the hippocampus (P = 0.04). Second, lesion patients with an IPI history had greater Ammon's horn (AH) neuron losses compared to those without IPI histories (P = 0.0005), and the profile of loss was similar to hippocampal sclerosis (HS). Granule cell losses correlated in a complex manner in that; 1) by regression analysis densities decreased with longer intervals of TLE (P = 0.006), (2) tumor patients with IPIs had less granule cell loss compared to those without IPIs intervals of TLE (P = 0.006), (2) tumor patients with IPIs had less granule cell loss compared to those without IPIs (P = 0.05), and (3) developmental patients with IPIs had greater granule cell loss than patients without IPIs (P = 0.009). Mesial-temporal depth EEG electrodes were the first areas of ictal activity in 15 of 16 patients (94%), and greater hippocampal neuron losses were not associated with focal mesial-temporal EEG onsets. Seizure outcomes were worse in tumor patients compared to HS patients (P = 0.01), and patients with post-resection seizures had incomplete resections of their lesions and/or hippocampi. These results indicate that in TLE lesion patients the amount and pattern of hippocampal neuron loss depends on the location of the lesion, the pathologic classification, and a history of an IPI. Further, despite variable neuron losses, in temporal lesion patients the hippocampus was nearly always involved in the genesis or propagation of the chronic seizures.

Reactive synaptogenesis and neuron densities for neuropeptide Y, somatostatin, and glutamate decarboxylase immunoreactivity in the epileptogenic human fascia dentata

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.(ABSTRACT TRUNCATED AT 400 WORDS)

The clinical-pathogenic mechanisms of hippocampal neuron loss and surgical outcomes in temporal lobe epilepsy

A retrospective study was carried out to determine whether a prior cerebral injury or medical illness was associated with hippocampal sclerosis in intractable, surgically treated temporal lobe epilepsy (TLE), or whether there was evidence for progressive hippocampal neuron damage from repeated seizures. Temporal lobe epilepsy patients (n = 162) from one epilepsy centre were retrospectively and blindly catalogued into groups based on the presence or absence of an initial precipitating injury (IPI) and whether, when an IPI was present, it had involved seizures (independent variables). Patients were catalogued into four groups: (i) non-seizure IPIs (Group A; n = 54); (ii) IPIs with a prolonged seizure (Group B; n = 66); (iii) IPIs with repetitive non-prolonged seizures (Group C; n = 20); (iv) or no IPIs and idiopathic TLE (Group D; n = 22). The dependent variables were: the differences in the time course of clinical seizures, and quantified hippocampal neuron counts and seizure outcomes. Statistically significant (ANOVA at least P < 0.05) results showed the following. (i) Patients with IPIs (Groups A, B and C) had hippocampal sclerosis, while those with idiopathic TLE (Group D) showed fewer neuron losses and worse post-resection seizure relief. (ii) Patients with non-seizure IPIs (Group A) were on average older at injury; had a longer latent period; showed less neuron losses in Ammon's horn, CA1 and prosubiculum than seizure associated IPIs (Groups B and/or C). (iii) Initial precipitating injury patients with repetitive non-prolonged seizures (Group C) showed the shortest latent period, earliest age of TLE onset, and less CA2 damage than the other IPI groups. Other findings that were statistically significant by analysis of covariance along with the IPI category included the following. (i) CA1 (P = 0.0097) and prosubiculum (P = 0.0089) neuron losses were greater in patients when their TLE was longer than 22 years. (ii) IPIs after age 4 years were associated with latent periods shorter than 10 years compared with variable and longer latent periods of IPIs before age 4 years (P = 0.0015). These results indicate that in surgically treated TLE, hippocampal sclerosis and good seizure outcomes are associated with IPIs. Most of the hippocampal damage found at surgery and the clinical time course of the habitual TLE are influenced by the pathogenic IPI mechanism. However, some secondary neuron losses were associated with longer TLE seizure histories.(ABSTRACT TRUNCATED AT 400 WORDS)

Kainic acid induced hippocampal seizures in rats: comparisons of acute and chronic seizures using intrahippocampal versus systemic injections

Hyppocampal epilepsy is a recently defined syndrome occurring in 65% of all temporal lobe epilepsies as defined by: 1) electrographic (EEG) onset in the hippocampus (HC) prior to EEG seizures elsewhere, 2) post-resection hippocampal sclerosis and mossy fiber synaptic reorganizations and 3) relief of typical complex partial seizures after surgical resection of the hyppocampus. We used intrahippocampal kainic acid injections V2 in rats at different developmental ages (postnatal 7 through adult) to develop long term spontaneous HC EEG spikes, EEG seizures, and behavioral seizures. Split-screen video/EEG monitoring demonstrated that this intrahippocampal kainic acid model produced progressive development of: 1) ipsilateral interictal spikes, 2) later polyspike complexes, 3) bilaterally-asynchronous EEG spiking, 4) unilateral HC EEG seizure onsets with occasional secondarily generalized spread to apposite HC and motor cortex to elicit complex partial seizures, and 5) in all seizing rats there was mossy fiber synaptic reorganization, even when injected at age 7 days. These results indicate that the intrahippocampal kainic acid injection model is similar to human hippocampal epilepsy.

Quantified patterns of mossy fiber sprouting and neuron densities in hippocampal and lesional seizures

Quantified hippocampal mossy fiber synaptic reorganization and neuron losses were measured to determine the pathological features associated with epileptogenic fascia dentata. Twenty-five patients with temporal lobe epilepsy (TLE) were classified as having either mesial temporal sclerosis (MTS; 16 patients), with seizure genesis in the hippocampus, or temporal mass lesions (nine patients), with seizures that were probably extrahippocampal. Neo-Timm's histochemistry identified mossy fiber sprouting, and aberrant fascia dentata puncta densities were objectively measured by light microscopic analysis on an image-analysis computer. neuron densities determined cell losses and the two seizure groups were compared to control specimens obtained from autopsies. Results showed significantly greater fascia dentata mossy fiber puncta densities and neuron losses in TLE patients compared to autopsy specimens (p < 0.026). Furthermore, there were significant differences between the two seizure groups: 1) mossy fiber puncta densities in the inner molecular layer were significantly greater in MTS compared to lesions (p < 0.02), and 2) mossy fiber puncta densities were greater in the inner molecular layer than in the stratum granulosum in 14 of 16 MTS patients (88%) compared to four of nine patients with lesions (44%, p < 0.01). Neuron densities were significantly different comparing MTS, lesion and control groups for stratum granulosum (p = 0.0001) and Ammon's horn (p = 0.0001), with each group significantly different (p < 0.05) compared to another. All patients were either seizure-free or significantly improved 1 year or more after en bloc temporal lobectomy. There were no significant correlations between fascia dentata mossy fiber puncta densities and counts of hilar neurons, CA4 pyramids, granule cells, or years of seizures. This indicates that inner molecular layer mossy fiber puncta densities and neuron losses are greater in patients with MTS than in those with lesions, and mossy fiber sprouting probably contributes to the pathophysiology of hippocampal seizures. Furthermore, these data show that some patients with extrahippocampal lesions have mossy fiber sprouting similar to MTS patients, suggesting that hippocampi in lesion patients may be capable of epileptogenesis from synaptic reorganization.

Unilateral hippocampal mossy fiber sprouting and bilateral asymmetric neuron loss with episodic postictal psychosis

Rarely are both sides of the hippocampus available for pathological study in a patient with intractable temporal lobe epilepsy (TLE). The authors report a patient with TLE investigated with bilateral depth electrodes who had an episode of postictal psychosis. The patient died 4 weeks after temporal lobectomy of unknown reasons, despite complete postmortem examination and clinical evidence of postsurgery seizure control. Pathological examination of surgical and autopsy hippocampal specimens found bilateral asymmetric neuron losses. However, only the resected epileptogenic hippocampus showed the profile of neuron loss typical of mesial temporal sclerosis (MTS) and abnormal mossy fiber synaptic reorganization. Quantitative depth electroencephalographic (EEG) analysis of the postictal psychotic event showed that it was not associated with a cluster of seizures, increased postictal depth EEG spike activity, or insufficient antiepileptic medication. These results support the hypothesis that ipsilateral hippocampal epileptogenesis is associated with MTS and mossy fiber sprouting. The results also suggest that the etiology of postictal psychosis in this patient was initiated by an ictal event and the behavior apparently depended on seizure propagation outside the hippocampus. The relevance of these two findings to the literature is discussed.

Influence of the type of initial precipitating injury and at what age it occurs on course and outcome in patients with temporal lobe seizures

The type of initial precipitating injury and the age at which it occurred in 20 patients with nonlesional temporal lobe epilepsy (TLE) were related to clinical features, presurgical neuroimaging, quantified hippocampal pathologies, and seizure outcomes. Clinical data, neuroimaging records, and seizure outcomes were abstracted from medical records and confirmed with patient and family contacts. Hippocampal neuron losses and mossy fiber reactive synaptogenesis were quantified independently. Results showed that the type of initial precipitating injury and the patient's age at which it occurred were related to the clinicopathological features of TLE. An initial precipitating injury occurred in 18 patients (90%), all of whom had mesial temporal sclerosis (MTS). Patients with a prolonged initial seizure or a nonseizure initial precipitating injury before age 5 years were significantly more likely to have unilateral hippocampal atrophy (p < 0.05) shown on magnetic resonance (MR) imaging, and had significantly greater inner molecular layer mossy fiber puncta densities (p < 0.001) than patients with nonprolonged childhood initial precipitating injuries and/or seizures after age 5 years. Furthermore, nonseizure injuries in patients before age 5 years had significantly longer latent periods (p < 0.05), and the patients did not respond to surgical treatment as well as other MTS patients. Those with an initial precipitating injury after age 5 years had MTS but showed significantly less inner molecular layer mossy fiber sprouting (p < 0.05) than patients whose injuries appeared before age 5 years. Patients without an initial precipitating injury (idiopathic TLE) had significantly fewer neuron losses (p < 0.05) and inner molecular layer mossy fiber puncta densities (p < 0.05) and had worse outcomes following en bloc temporal lobectomy compared to patients with MTS who had experienced initial precipitating injuries. Patients with unilateral hippocampal abnormalities on MR imaging did not show significant differences in neuron losses or aberrant mossy fiber puncta densities compared to patients without asymmetry. These results support the hypothesis that the type of initial precipitating injury and the age at which the injury occurred initiates and influences the pathophysiological process that eventually develops into MTS. These data support the notion that the pathophysiology of hippocampal damage and mossy fiber sprouting after an initial precipitating injury may be a progressive process.

Traumatic compared to non-traumatic clinical-pathologic associations in temporal lobe epilepsy

This study determined differences in clinical-pathologic characteristics of intractable temporal lobe epilepsy (TLE) patients whose mechanism of cerebral injury and chronic seizures involved a prior history of cerebral trauma compared to those with non-traumatic initial injuries. TLE patients (n = 120) from a single epilepsy center were retrospectively and blindly catalogued into pathogenic groups (independent variables) based on if there was a significant Birth injury (n = 11) or Cerebral trauma (n = 26). These two 'trauma' categories were compared to TLE patients with non-seizure non-trauma histories (Non-Sz/Non-Trauma; n = 17), or a first Prolonged seizure (n = 66). The four groups were compared for differences in the time course of their clinical injuries and seizures, quantified hippocampal neuron counts, other temporal neocortical pathologies, and seizure outcomes (dependent variables). Between group statistically significant (at least P < 0.05) results showed: (1) In Birth injury, 33% had Ammon's Horn (AH) neuron loss under 50%, 54% had other temporal neocortical pathologies, they showed the most CA4 neuron loss, and the worse seizure outcomes. (2) Cerebral trauma were older when injured, 29% had AH loss under 50%, 50% showed other pathologies, and they had the best seizure outcomes. (3) Non-Sz/Non-Trauma showed the least AH and CA4 neuron losses, only 12% had other temporal pathologies, and they had seizure outcomes that were intermediate. (4) Prolonged seizure showed the youngest age of habitual TLE onsets, the greatest AH, CA1, and prosubiculum neuron loss, only 11% had other temporal pathologies, and their seizure outcomes were excellent. These results indicate that in intractable surgically treated TLE, a history of cerebral trauma or birth injury as the pathogenic mechanism of their seizures show different clinical-pathologic features and seizure outcomes compared to non-trauma patients. This supports the notion that in TLE there are different pathogenic mechanisms associated with different types of initial injuries and that patients will have different responses to surgical therapy.

Children with severe epilepsy: evidence of hippocampal neuron losses and aberrant mossy fiber sprouting during postnatal granule cell migration and differentiation

Surgically resected hippocampi from children with extrahippocampal seizures and structurally non-atrophic brains were examined to determine the relationship of neuron losses and aberrant mossy fiber (MF) sprouting to the postnatal migration and differentiation of the fascia dentata (FD) granule cells (GC). Percent neuron loss compared to age-matched autopsy controls was determined by quantitative cell densities, and aberrant MF sprouting by neo-Timm histochemistry. Postnatal immature GC migration and differentiation was demonstrated by the transient but GC-specific expression of the immature form of neural cell adhesion molecule (NCAM-H). Results showed that the hippocampi from children with seizures appeared microanatomically intact without focal areas of damage. However, significant neuron losses were found by neuron counts in the fascia dentata (P < 0.01), CA4 (P < 0.01), and CA2 (P < 0.05). Aberrant supragranular inner molecular layer MF sprouting was found in hippocampi of children with seizures, and the MFs showed smaller puncta in specimens resected under 2 years of age (n = 3) compared to the larger puncta in older children (n = 5). Hippocampi from children under 2 years of age also demonstrated NCAM-H positive primitive cells in the infragranular and stratum granulosum of the fascia dentata consistent with the postnatal migration and differentiation of GCs, the parent neurons of the MFs. These results indicate that seizures in the immature but structurally intact human hippocampus are associated with decreased neuron densities and aberrant MF sprouting very early in postnatal development. The data also show that aberrant MF sprouting is found during postnatal migration, differentiation and axogenesis of GCs.(ABSTRACT TRUNCATED AT 250 WORDS)

Circuit mechanisms of seizures in the pilocarpine model of chronic epilepsy: cell loss and mossy fiber sprouting

We used the pilocarpine model of chronic spontaneous recurrent seizures to evaluate the time course of supragranular dentate sprouting and to assess the relation between several changes that occur in epileptic tissue with different behavioral manifestations of this experimental model of temporal lobe epilepsy. Pilocarpine-induced status epilepticus (SE) invariably led to cell loss in the hilus of the dentate gyrus (DG) and to spontaneous recurrent seizures. Cell loss was often also noted in the DG and in hippocampal subfields CA1 and CA3. The seizures began to appear at a mean of 15 days after SE induction (silent period), recurred at variable frequencies for each animal, and lasted for as long as the animals were allowed to survive (325 days). The granule cell layer of the DG was dispersed in epileptic animals, and neo-Timm stains showed supra- and intragranular mossy fiber sprouting. Supragranular mossy fiber sprouting and dentate granule cell dispersion began to appear early after SE (as early as 4 and 9 days, respectively) and reached a plateau by 100 days. Animals with a greater degree of cell loss in hippocampal field CA3 showed later onset of chronic epilepsy (r = 0.83, p < 0.0005), suggesting that CA3 represents one of the routes for seizure spread. These results demonstrate that the pilocarpine model of chronic seizures replicates several of the features of human temporal lobe epilepsy (hippocampal cell loss, supra- and intragranular mossy fiber sprouting, dentate granule cell dispersion, spontaneous recurrent seizures) and that it may be a useful model for studying this human condition. The results also suggest that even though a certain amount of cell loss in specific areas may be essential for chronic seizures to occur, excessive cell loss may hinder epileptogenesis.

Hippocampal EEG excitability and chronic spontaneous seizures are associated with aberrant synaptic reorganization in the rat intrahippocampal kainate model

Previously, Mathern et al. (1992) demonstrated progressive mossy fiber (MF) sprouting in the intrahippocampal rat kainate seizure model. This study looked at the time course of EEG hyperexcitability and spontaneous seizure activity in the same in vivo model to determine if seizures were associated with MF sprouting. Results showed that animals progressed through 4 distinct EEG and behavioral phases and that in the chronic phase (greater than 90 days post kainate) MF sprouting was strongly associated with hippocampal epileptogenesis. Progressive MF sprouting into the inner molecular layer (IML) of the fascia dentata paralleled the EEG and behavioral appearance of independent hippocampal interictal epileptiform transients and chronic seizures. Hippocampi from chronic animals that demonstrated unilateral MF IML sprouting were observed to have interictal epileptiform transients and spontaneous seizures that lateralized to the hippocampus with synaptically reorganized MFs. Chronic animals with bilateral MF sprouting were observed to have bilateral independent EEG and behavioral hyperexcitability. Control animals and kainate treated animals that lacked hippocampal cell loss and MF sprouting did not show signs of chronic hippocampal EEG hyperexcitability or chronic seizures. These data support the idea that MF sprouting contributes to chronic hippocampal seizures by feedback excitation which leads to the excitability and synchronization required for a damaged hippocampus to become an epileptic focus.

Synaptic reorganization by mossy fibers in human epileptic fascia dentata

This study was designed to identify whether synaptic reorganizations occur in epileptic human hippocampus which might contribute to feedback excitation. In epileptic hippocampi, (n = 21) reactive synaptogenesis of mossy fibers into the inner molecular layer of the granule cell dendrites was demonstrated at the light microscopic and electron microscopic levels. There was no inner molecular layer staining for mossy fibers in autopsy controls (n = 4) or in controls with neocortex epilepsy having no hippocampal sclerosis (n = 2). Comparing epileptics to controls, there were statistically significant correlations between Timm stain density and hilar cell loss. Since hilar neurons are the origin of ipsilateral projections to the inner molecular layer, this suggests that hilar deafferentation of this dendritic zone precedes mossy fiber reafferentation. Quantitative Timm-stained electron microscopy revealed large, zinc-labelled vesicles in terminals with asymmetric synapses on dendrites in the inner molecular and granule cell layers. Terminals in the middle and outer molecular layers did not contain zinc, were smaller and had smaller vesicles. These histochemical and ultrastructural data suggest that in damaged human epileptic hippocampus, mossy fiber reactive synaptogenesis may result in monosynaptic recurrent excitation of granule cells that could contribute to focal seizure onsets.

Glutamate decarboxylase-immunoreactive neurons are preserved in human epileptic hippocampus

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.

Recovery of decreased glutamate decarboxylase immunoreactivity after rat hippocampal kindling

The present study was designed to test the hypothesis that chronic gamma-aminobutyric acid (GABA) disinhibition of granule cells could explain permanent kindled epileptogenicity. Quantitative and statistical comparisons of glutamate decarboxylase immunoreactivity (GAD-IR), the synthesizing enzyme for GABA, were made of GAD-IR cells and puncta in stratum granulosum of the fascia dentata. The use of GAD immunocytochemistry in kindled and control tissue was used to allow direct anatomic confirmation that we were measuring changes in GAD-IR which would represent GABA synthesis for release by the recurrent inhibitory system of the fascia dentata. Immediately after the last kindled seizure, optically detected GAD-IR puncta densities were significantly reduced in stratum granulosum. At 3 or 7 days after the last kindled seizure, GAD-IR was normal in puncta, indicating that the transient GAD-IR loss was probably a metabolic response to the recent seizure represented by over-use of GAD needed for synthesis of GABA after a prolonged kindled seizure. When the prolonged kindled seizures were discontinued GAD-IR recovered in the puncta. This transient effect did not occur in other areas such as Ammon's horn (CA3) or substantia nigra. The extent of the GAD-IR loss showed no correlation with the severity of the final behavioral seizure (R = 0.23), or the final afterdischarge (AD) duration in entorhinal cortex (R = 0.17) or motor cortex (R = 0.53). A massed stimulation control group given 19 shorter-duration ADs every 10 min (non-kindling) did not reduce GAD-IR. These findings support the hypothetical model that prolonged kindled seizures release excessive GABA which depletes GAD in axon terminals for 1 day after the seizure. However, such a transient suppression of GAD-IR provides no evidence that disinhibition contributes to the kindling process, because kindling proceeds normally with inter-seizure intervals as long as 1 week. The finding of full recovery of GAD-IR within 1 week does not support the model of loss of GABA inhibition to explain the permanency of kindled epileptogenesis.

Distribution of glutamate-decarboxylase-immunoreactive neurons and synapses in the rat and monkey hippocampus: light and electron microscopy

We have studied the distribution of gamma-aminobutyric acid (GABA) neurons, axons, and synapses in the rat and monkey hippocampal formation by using glutamate decarboxylase (GAD) immunocytochemistry together with Nissl stains, electron microscopy, and double-labeled retrograde transport of horseradish peroxidase. The numbers of GAD-containing (putative GABA) neurons and their percentages compared to all Nissl-stained neurons were calculated throughout all the various fields and strata of the mammalian hippocampus. Although their numbers are greatest in the polymorph region of the fascia dentata (FD) and in the principal cell layers stratum pyramidale (SP) and stratum granulosum (SG), GAD immunoreactive (GAD-IR) cells are numerous in other strata that contain mostly dendrites and scattered cells. These GAD-IR (putative GABA) neurons in dendritic regions may be involved in feedforward dendritic inhibition or may directly inhibit nearby neurons. We used a postmortem delay technique, which resulted in apparent diffusion of GAD into dendrites and axons and allowed better visualization of the extensive dendritic domain of GAD-IR neurons. Computerized image analysis of GAD-IR puncta indicated that putative GABA terminals were numerous on apical and basilar dendrites of all pyramidal cells but unexpectedly highest in the monkey presubiculum. In the rat, GAD-IR neurons projected axons ipsilaterally from every region to the fascia dentata and CA1; however, commissural GAD-IR axons to the fascia dentata arose from GAD-IR neurons in only the contralateral fascia dentata and subiculum. Electron microscopy of GAD-stained hippocampus identified GAD-IR neurons with non-GAD-IR (possibly excitatory) synapses and GAD-IR terminals on somata and dendrites, 80% being the symmetric type and 20% the asymmetric type. In contrast, non-GAD-IR terminals were asymmetric 80% of the time.