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

Nontumoral occipitotemporal epilepsy: localizing findings and surgical outcome

We describe a syndrome of medically intractable occipitotemporal epilepsy of nontumoral developmental origin and its treatment by surgery. From our epilepsy surgery database of 1988 to 1996, we selected all patients without neoplasm who had at least two characteristics localizing to the occipital lobe (clinical symptoms, interictal focus, ictal onset, or a lesion on magnetic resonance imaging scanning) and one to the temporal lobe (interictal spikes or seizure onset). We discuss seizure characteristics, electroencephalographic (EEG), magnetic resonance imaging, positron emission tomographic, and single-photon emission computed tomographic findings, pathological findings, surgical approach, outcome from resective surgery, and implications for pathophysiology. Sixty-nine percent of our 16 patients with occipitotemporal syndrome had neuronal migration disorder, suggesting a developmental etiology of this entity. Initial signs or symptoms suggested occipital lobe seizure onset in 13 of 16 patients. On scalp EEG, interictal spikes were localized to the temporal lobe in 9 and to the occipital lobe in 1; seizure onset was poorly localized. Intracranial EEG localized seizure onset to the area of temporo-occipital junction in 77% of patients. Positron emission tomography and single-photon emission computed tomography showed occipital and temporal or widespread deficits, and neuropsychological performance was diffusely abnormal. Surgical results were best with occipital and temporal resections, but sometimes satisfactory after occipital resection even with temporal (ipsilateral) EEG findings. Temporal resection with hippocampectomy uniformly failed to control seizures. An often refractory, probably developmental epileptic syndrome with regional occipitotemporal distribution can be diagnosed by a specific constellation of findings, which has implications for treatment and pathophysiology.

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.

Seizure frequency and duration of epilepsy are not risk factors for postoperative seizure outcome in patients with hippocampal sclerosis

PURPOSE

Despite accurate localization of the seizure focus, not all patients are seizure free after temporal lobectomy. This study determined risk factors for seizure recurrence in patients with proven hippocampal sclerosis.

METHODS

The outcome from surgery was assessed in 56 consecutive patients with proven hippocampal sclerosis. The age at surgery, duration of epilepsy, history and age of febrile seizures, age of onset of epilepsy, sex ratio, laterality of seizure focus, and seizure frequency were compared between patients seizure free and those not seizure free, and those seizure and aura free and those with seizure recurrence including auras.

RESULTS

During a mean follow-up of 38 months, 48 (86%) of 56 are seizure free. The mean age at surgery (37 vs. 36 years), duration of epilepsy (26 vs. 22 years), age (1.6 vs. 1.1 years), and occurrence (58 vs. 75%) of febrile seizures, age of onset of epilepsy (11 vs. 14 years), sex ratio (50 vs. 75% female), laterality of seizure focus (42 vs. 50% left), greater than weekly seizures (40 vs. 38%), and a history of (69 vs. 75%) and frequency of (2.10 vs. 2.38 per year) secondarily generalized seizures did not differ significantly between the two groups. Similarly there was no significant difference between patients seizure and aura free and those with seizure recurrence including auras.

CONCLUSIONS

Clinical factors such as seizure frequency and duration of epilepsy are not risk factors for postoperative seizure recurrence.

Long term effects of refractory temporal lobe epilepsy on cognitive abilities: a cross sectional study

OBJECTIVE

Intractable epilepsy is related to various transient and chronic brain electric and neurochemical disturbances. There is increasing evidence that chronic epilepsy induces secondary neuronal metabolic and structural decline. However, there is no convincing evidence that the cognitive abilities of patients deteriorate with increasing duration of intractable epilepsy.

METHODS

To examine whether duration of refractory temporal lobe epilepsy (TLE) is related to generalised cognitive impairment, psychometric intelligence based on the full scale intelligence quotient (FSIQ, WAIS-R) was determined in 209 patients with unilateral TLE. For analyses of variance (ANOVA) patients were grouped into three categories: <15, 15-30, and >30 years of refractory TLE.

RESULTS

An ANOVA and a multiple regression analysis showed that duration of TLE affects FSIQ. Patients with >30 years of TLE performed worse than patients with 15 or 30 years of TLE. The factors side of seizure origin and type of lesion on MRI did not reach significance. A second ANOVA including education as factor showed that in patients with higher educational attainment, the mean FSIQ was stable for a longer duration of TLE than in less educated patients. Retesting 6 months after anterior temporal lobectomy seizure free patients (n=85 of 127) had an higher FSIQ but showed a similar duration effect before and after anterior temporal lobectomy. The variables age at epilepsy onset, education, frequency of interictal epileptiform discharges, frequency of habitual and generalised seizures, serum concentration of antiepileptic drugs, and polypharmacy were statistically controlled.

CONCLUSIONS

Psychometric intelligence of patients with a longer duration of refractory TLE were most severely impaired. Consequently, refractory TLE seems to be associated with slow but ongoing cognitive deterioration. It is assumed that epilepsy related noxious events and agents exhaust the compensatory capacity of brain functions. However, as in dementia and Alzheimer's disease, higher educational attainment as an indicator of higher brain reserve might delay the cognitive decline.

Neuroimaging evidence of progressive neuronal loss and dysfunction in temporal lobe epilepsy

Whether temporal lobe epilepsy is the result of an isolated, early injury or whether there is ongoing neuronal dysfunction or loss due to seizures is often debated. We attempt to address this issue by using magnetic resonance techniques. Proton magnetic resonance spectroscopic imaging can detect and quantify focal neuronal dysfunction or loss based on reduced signals from the neuronal marker N-acetylaspartate (NAA), and magnetic resonance imaging (MRI)-based measurements of hippocampal volumes (MRIvol) can quantify the amount of atrophy in this structure. We performed magnetic resonance spectroscopic imaging and MRIvol in 82 consecutive patients with medically intractable temporal lobe epilepsy to determine whether there was a correlation between seizure frequency, or type or duration of epilepsy, with NAA to creatine (Cr) values or hippocampal volumes. Volumes and spectroscopic resonance intensities were categorized as to whether they were measured from the temporal lobe ipsilateral or contralateral to the predominant electroencephalographic focus. Ipsilateral and contralateral NAA/Cr was negatively correlated with duration of epilepsy. Hippocampal volumes were negatively correlated with duration ipsilaterally but not contralaterally. Frequency of complex partial seizures was not correlated with any of the magnetic resonance measures. However, patients with frequent generalized tonic-clonic seizures had lower NAA/Cr bilaterally and smaller hippocampal volumes ipsilaterally than patients with none or rare generalized tonic-clonic seizures. The results suggest that although an early, fixed injury may cause asymmetric temporal lobe damage, generalized seizures may also cause progressive neuronal dysfunction or loss.

Clinical aspects and biological bases of drug-resistant epilepsies

The definition of drug-resistant epilepsy (DRE) is elusive and still controversial owing to some unresolved questions such as: how many drugs should be tried before a patient is considered intractable; to which extent side-effects may be acceptable; how many years are necessary before establishing drug resistance. In some cases, the view of epilepsy as a progressive disorder constitutes another important issue. Despite the use of new antiepileptic drugs (AEDs), intractable epilepsy represents about 20-30% of all cases, probably due to the multiple pathogenetic mechanisms underlying refractoriness. Several risk factors for pharmacoresistance are well known, even if the list of clinical features and biological factors currently accepted to be associated with difficult-to-treat epilepsy is presumably incomplete and, perhaps, disputable. For some of these factors, the biological basis may be common, mainly represented by mesial temporal sclerosis or by the presence of focal lesions. In other cases, microdysgenesis or dysplastic cortex, with abnormalities in the morphology and distribution of local-circuit (inhibitory) neurons, may be responsible for the severity of seizures. The possible influence of genes in conditioning inadequate intraparenchimal drug concentration, and the role of some cytokines determining an increase in intracellular calcium levels or an excessive growth of distrophic neurites, constitute other possible mechanisms of resistance. Several hypotheses on the mechanisms involved in the generation of DRE have been indicated: (a) ontogenic abnormalities in brain maturation; (b) epilepsy-induced alterations in network, neuronal, and glial properties in seizure-prone regions such as the hippocampus; (c) kindling phenomenon; (d) reorganization of cortical tissue in response to seizure-induced disturbances in oxygen supply. Such hypotheses need to be confirmed with suitable experimental models of intractable epilepsy that are specifically dedicated, which have until now been lacking.

Febrile convulsions and mesial temporal sclerosis

Patients with intractable temporal lobe epilepsy and mesial temporal sclerosis often have histories of severe febrile convulsions as infants. Diagnostic advances made possible by magnetic resonance imaging have shown that very prolonged febrile convulsions may produce hippocampal injury and that focal cortical dysgenesis may play a role in the etiology of febrile convulsions, mesial temporal sclerosis, and temporal lobe epilepsy.

[Epilepsy due to mesiotemporal sclerosis in children: 10 cases]

BACKGROUND

Mesio-temporal sclerosis is a frequent and probably underestimated cause of resistant temporal epilepsy in childhood.

PATIENTS AND METHODS

Ten patients originating from West and North-East France are reported in this retrospective study. They were referred for partial temporal epilepsy which had begun between the ages of 3.5 and 15 years. Mesio-temporal sclerosis was diagnosed on MRI (ten cases) and on neuropathological examination (three cases).

RESULTS

Complex partial seizures were noted in all patients, with most frequently fear, abnormal epigastric perception and oro-alimentary automatisms. Social and educational issues were altered due to frequent seizures and amnesic disturbances. An initial event, always a complex febrile seizure, was found in six patients. MRI study showed in all patients unilateral hippocampal atrophy and/or an increase in hippocampal T2 signal intensity on coronal sections. Ictal EEG showed homolateral temporal seizures six times. Hippocampo-amygdalectomy was performed in three patients with a good outcome.

CONCLUSION

Epilepsy associated with mesio-temporal sclerosis belongs to intractable epilepsy in childhood. Early recognition of its symptoms would allow early pre-operative assessment in order to minimize developmental defects due to continuing epilepsy, and adverse cognitive effects of anti-epileptics.

Dissociation of mossy fiber sprouting and electrically-induced seizure sensitivity: rapid kindling versus adaptation

It has been shown that massed stimulation (MS) of the amygdala or hippocampus does not result in seizure progression but in the 'phenomenon of adaptation', whereas alternate day rapid kindling (ADRK) produces reliable kindling (Lothman, E.W., Williamson, J.M., 1994. Brain Res. 649, 71-84). The goal of the present experiment was to determine if the two different effects are due to differences in mossy fiber sprouting and/or different seizure and postictal spike propagation patterns. Nine rats underwent MS (66-70 stimulations separated by 5-min interstimulus interval), six were exposed to ADRK (12 stimulations/day, every 30 min, with 4 stimulus days, each separated by 1 stimulus-free day), five rats served as control. All rats had electrodes implanted bilaterally in dorsal and ventral hippocampi (VH) and 14 of them had additional electrodes in the piriform cortex. Animals were stimulated in the left VH at afterdischarge threshold. There was no potentiation in seizure response 4-7 weeks after MS. In contrast, ADRK produced not only kindling but also ongoing epileptogenesis resulting 4-7 weeks later in spontaneous seizures and development of a prolonged convulsive state in response to the initially subconvulsive stimulus. Epileptiform activity during MS was mostly restricted to VH, whereas during ADRK it spread widely among studied structures including piriform cortex. Afterdischarges during MS were elicited frequently but seizures did not progress beyond stage 2-3. During ADRK, afterdischarges were evoked less frequently but seizures reached stage 4-7 by the end of the 3rd and 4th stimulus days. The fully kindled state was not reached at this time, but epileptogenic changes continued to progress. Seven weeks after the initial stimulation, both groups demonstrated mossy fiber sprouting of similar intensity in VH. We suggest, (1) frequent but predominantly local hippocampal afterdischarges induce mossy fiber sprouting, but this is not sufficient to produce significant enhancement in seizure susceptibility, and (2) the involvement of extra-hippocampal structures, possibly piriform cortex, and formation of an aberrant hippocampal-para-hippocampal circuit is required to result in a condition of progressive epileptogenesis.

Hippocampal sclerosis revisited

Studies dating back more than 150 years reported a relationship between hippocampal sclerosis and epilepsy. Retrospective studies of patients who underwent temporal lobectomy for intractable partial epilepsy found a relationship between a history of early childhood convulsions, hippocampal sclerosis, and the development of temporal lobe epilepsy. Many believe that febrile seizures lead to hippocampal damage and this in turn predisposes the patient to the development of temporal lobe epilepsy. Studies in adult rats have shown that seizures can lead to hippocampal damage and unprovoked recurrent seizures. However, many questions remain as to the relevance of early childhood seizures to hippocampal sclerosis and temporal lobe epilepsy. Human prospective epidemiologic studies have not shown a relationship between early childhood seizures and temporal lobe epilepsy. Recent MRI studies in humans suggest that a preexisting hippocampal lesion may predispose infants to experience febrile seizures, later on hippocampal sclerosis, and possibly temporal lobe epilepsy may occur. Unlike the studies in adult rats, normal immature rats with seizures have not been shown to develop hippocampal damage or unprovoked seizures in adulthood. Furthermore, animal studies reveal that preexisting brain abnormalities can predispose to hippocampal damage following seizures early in life. This paper reviews evidence for and against the view that early childhood convulsions, hippocampal sclerosis, and temporal lobe epilepsy are related, while also exploring clinical and animal studies on how seizures can lead to hippocampal damage, and how this can result in temporal lobe epilepsy. By better understanding the cause and effect relationship between early childhood seizures and hippocampal injury in normal and abnormal brains specific treatments can be developed that target the pathogenesis of epilepsy.

Synaptophysin immunohistochemistry densitometry measurement in resected human hippocampus: implication for the etiology of hippocampal sclerosis

Synaptophysin (SY) is a protein expressed at presynaptic vesicles. SY immunohistochemistry (IHC) was undertaken in surgically resected hippocampal specimens from 25 patients with intractable epilepsy. All were investigated with chronic ictal EEG videotelemetry, which showed a temporal onset in each case, and all had normal magnetic resonance imaging (MRI). The density of reaction product of SY IHC was used to generate optical density (OD) measurements as an estimate of synaptic density in CA1 and CA4 fields (ODCA1 and ODCA4), and inner third and outer two-thirds of the molecular layer of the dentate gyrus (ODIML and ODOML). There was significant correlation between ODCA1 (r=0.619, P=0.001) and ODCA4 (r=0.639, P=0.001) and onset age of epilepsy. There was no correlation between ODCA1 and duration of epilepsy. There was correlation between ODCA4 and duration (r=-0.412, P=0.041), but partial correlations showed no significant correlation between ODCA4 and duration when controlling for onset, although correlation between ODCA4 and onset when controlling for duration remained significant (r=0.536, P < 0.01). Univariate ANOVA revealed onset age to be the only predictor of ODCA1 and ODCA4. Chronological age and duration were not predictors. There was no correlation between ODIML or ODOML and either onset age or duration. ODIML and ODOML were not predicted by onset age, duration or chronological age. These findings support the hypothesis that the major cause of hippocampal sclerosis is an age specific insult rather than the result of repeated seizures.

Quantitative 1H MRS in the evaluation of mesial temporal lobe epilepsy in vivo

Hippocampal metabolite concentrations were determined by localized in vivo proton magnetic resonance spectroscopy (1H MRS) in eleven patients suffering from refractory mesial temporal lobe epilepsy (MTLE), as well as in eleven age-matched healthy volunteers, and compared with patient history, postoperative outcome and histopathology. Main results are: 1) In patients, the decrease in N-acetylaspartate (NAA) concentrations was highly significant ipsilateral, and less but still significant contralateral to the electroencephalogram-defined focus, as compared to controls. 2) The decrease in ipsilateral NAA measured preoperatively correlates with the degree of hippocampal sclerosis but 3) does not reliably predict postoperative outcome, although there is a trend toward better outcome in patients with a marked decrease of NAA. 4) Hippocampal NAA decrease (ipsi- and contralateral) is highly correlated with early onset age of epileptic seizures. 5) Among patients with similar onset age in early childhood, there is a strong association between duration of the disease and contralateral (and, though less clear-cut, ipsilateral) NAA loss. These results are concordant with the notion of a generally progressive worsening and complicating course of symptoms in poorly controlled MTLE.

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.

Proton spectroscopy in children with epilepsy and febrile convulsions

An association between complex febrile convulsions and the development of hippocampal atrophy, which is characterized by neuron loss and gliosis, has been suggested but is still controversial. In proton magnetic resonance spectroscopy (1H-MRS) a reduction in N-acetylaspartate (NAA), a neuron marker, or in its ratio to other metabolites, that is, creatine and phospocreatine (Cr) and choline-containing compounds (Cho), is considered a sensitive method for detecting neuron loss. We performed 1H-MRS of mesial temporal regions, including hippocampi, in two different groups of children with epilepsy: in children with a history of complex febrile convulsions (CFCs) (n = 7; mean age 7.1 years) and in children without any history of CFCs, referred to herein as the non-CFC group (n = 6; mean age 7.6 years). Changes in the metabolite ratios were detected in 57% of children in the CFC group and in 67% of children in the non-CFC group. In both groups, NAA/(Cho + Cr), NAA/Cho, and NAA/Cr were significantly decreased ipsilaterally to the seizure focus when compared with the control group, but no significant differences were detected between the CFC and non-CFC groups. Also on the contralateral side, NAA/(Cho + Cr) and NAA/Cr were significantly decreased in both patient groups, but the differences were not significant between the CFC and non-CFC groups. Metabolite abnormalities in the mesial temporal region were detected in children with intractable epilepsy and in children whose epilepsy is well controlled by antiepileptic medication. The noninvasive 1H-MRS can be considered an additional diagnostic method to promote early detection of mesial temporal abnormalities that, in the light of this study, seem to be underdiagnosed in children with either temporal lobe epilepsy or other seizure types.

Longitudinal quantitative hippocampal magnetic resonance imaging study of adults with newly diagnosed partial seizures: one-year follow-up results

PURPOSE

We wished to establish whether hippocampal changes occur in 1 year in adults with newly diagnosed partial seizures and, if so, to identify possible causes and mechanisms.

METHODS

Thirty-six adult patients with newly diagnosed partial seizures underwent a magnetic resonance imaging (MRI) scan of the brain including hippocampal volume and T2 relaxation time (HCT2) measurement and had a follow-up quantitative MRI scan approximately 1 year after the baseline MRI scan.

RESULTS

At baseline, 4 patients (11%) had hippocampal sclerosis (HS), 4 (11%) had abnormalities other than HS, and 28 had a normal MRI scan (78%). Twenty-three patients (64%) had recurrent seizures in the period between the two MRI scans. One of the 4 patients with HS, who had daily seizures, had significantly increased HCT2 values on follow-up, possibly reflecting progressive hippocampal damage. None of the 32 patients with MRI findings other than HS at baseline progressed to HS on follow-up. However, 2 of the 32 patients had significant hippocampal changes, probably related to resolution of inflammatory swelling or edema after seizures were controlled.

CONCLUSIONS

Subtle changes in hippocampi can occur in 1 year in adults with newly diagnosed partial seizures, which could be due to resolution of edema after seizure control or to hippocampal changes associated with frequent and daily seizures. Follow-up of the studied cohort for several years will be required to settle the question of whether progressive hippocampal damage occurs in temporal lobe epilepsy (TLE).

Recurrent spontaneous motor seizures after repeated low-dose systemic treatment with kainate: assessment of a rat model of temporal lobe epilepsy

Human temporal lobe epilepsy is associated with complex partial seizures that can produce secondarily generalized seizures and motor convulsions. In some patients with temporal lobe epilepsy, the seizures and convulsions occur following a latent period after an initial injury and may progressively increase in frequency for much of the patient's life. Available animal models of temporal lobe epilepsy are produced by acute treatments that often have high mortality rates and/or are associated with a low proportion of animals developing spontaneous chronic motor seizures. In this study, rats were given multiple low-dose intraperitoneal (i.p.) injections of kainate in order to minimize the mortality rate usually associated with single high-dose injections. We tested the hypothesis that these kainate-treated rats consistently develop a chronic epileptic state (i.e. long-term occurrence of spontaneous, generalized seizures and motor convulsions) following a latent period after the initial treatment. Kainate (5 mg/kg per h, i.p.) was administered to rats every hour for several hours so that class III-V seizures were elicited for > or = 3 h, while control rats were treated similarly with saline. This treatment protocol had a relatively low mortality rate (15%). After acute treatment, rats were observed for the occurrence of motor seizures for 6-8 h/week. Nearly all of the kainate-treated rats (97%) had two or more spontaneous motor seizures months after treatment. With this observation protocol, the average latency for the first spontaneous motor seizure was 77+/-38 (+/-S.D.) days after treatment. Although variability was observed between rats, seizure frequency initially increased with time after treatment, and nearly all of the kainate-treated rats (91%) had spontaneous motor seizures until the time of euthanasia (i.e. 5-22 months after treatment). Therefore, multiple low-dose injections of kainate, which cause recurrent motor seizures for > or = 3 h, lead to the development of a chronic epileptic state that is characterized by (i) a latent period before the onset of chronic motor seizures, and (ii) a high but variable seizure frequency that initially increases with time after the first chronic seizure. This modification of the kainate-treatment protocol is efficient and relatively simple, and the properties of the chronic epileptic state appear similar to severe human temporal lobe epilepsy. Furthermore, the observation that seizure frequency initially increased as a function of time after kainate treatment supports the hypothesis that temporal lobe epilepsy can be a progressive syndrome.

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).

Anterior temporal lobectomy, hippocampal sclerosis, and memory: recent neuropsychological findings

Anterior temporal lobectomy (ATL) is an effective and increasingly utilized treatment for nonlesional, intractable mesial temporal lobe epilepsy. However, this surgery results in domain-specific neuropsychological morbidity for a subset of patients. Within the past decade, multidisciplinary studies have revealed that left ATL patients without significant sclerosis in the resected hippocampus are most at risk for a substantial postacute decline in the ability to encode new verbal information. These patients are also at risk for a significant decrement in confrontation naming and other retrieval-based language abilities. The memory deficit is not attributable to this disruption of language. A relationship between hippocampal sclerosis (HS) status and memory performance has not been identified consistently in right ATL patients, but investigation of new visuospatial measures continues. The influence of variables other than HS on neuropsychological outcome is also discussed.

Quantitative neuropathology and quantitative magnetic resonance imaging of the hippocampus in temporal lobe epilepsy

The aims of this study were to examine the relationships of hippocampal T2 (HCT2) relaxation time and magnetic resonance (MR)-based hippocampal volume (HCV) to neuronal (ND) and glial cell densities (GD) of hippocampal neuronal cell layers, and to obtain a better clinicopathological definition of hippocampal sclerosis (HS) and end folium sclerosis (EFS). Fifty-three hippocampi with HS, 6 with EFS, and 6 control hippocampi were studied. Pathologically, the HS group had a significantly higher logarithm (log) GD/ND than the controls in all hippocampal subregions, and than the EFS group in all subregions except the granule cell layer of the dentate gyrus (GCDG). The EFS group had a significantly higher log GD/ND than the control group only in the GCDG. Clinical correlations suggested that EFS may be the consequence of temporal lobe seizures and not an epileptogenic entity. Hippocampal atrophy in HS was associated with neuronal cell depletion and concomitant gliosis in the cornu Ammonis (CA) 1, CA2, CA3, and hilus. An increased HCT2 was associated with damage in the CA1 and also the hilus and has a different neuropathological basis than HCV loss. MR-based HCV measurement and HCT2 mapping, therefore, give complementary information in the presurgical evaluation of temporal lobe epilepsy and longitudinal studies.

Reorganization of verbal memory function in early onset left temporal lobe epilepsy

The purpose of this investigation was to examine the issue of reorganization of verbal memory function following early insult to the left mesial temporal region. It was hypothesized that reorganization of memory function was most likely to occur in those patients with an early age of seizure onset who have a more limited degree of extra-hippocampal neuropathology. Fifty-four patients with epilepsy of unequivocal left temporal lobe origin were classified into four groups on the basis of the presence/absence of hippocampal sclerosis and degree of postoperative seizure relief. Measures of verbal learning and memory as well as nonmemory measures were administered both before and 6 to 8 months after anterior temporal lobectomy. Findings were consistent with the reorganization proposal. The clinical and theoretical significance of the findings are discussed.

MRI volumetry and T2 relaxometry of the amygdala in newly diagnosed and chronic temporal lobe epilepsy

Little is known about the appearance and severity of amygdaloid damage in temporal lobe epilepsy, particularly in its early stages. In the present magnetic resonance imaging study, we measured amygdaloid volumes and T2 relaxation times in 29 patients with newly diagnosed and in 54 patients with chronic temporal lobe epilepsy. The control population included 25 normal subjects. In the newly diagnosed patients, the mean amygdaloid volume did not differ from that in controls. Also, in the chronic patients the mean amygdaloid volume did not differ from that in controls or in newly diagnosed patients. However, in 19% of the chronic patients the amygdaloid volume was reduced by at least 20%. Moreover, in all of the epilepsy patients, both chronic and newly diagnosed, we found an inverse correlation between the number of epileptic seizures the patient had experienced and the amygdaloid volume on the focal side (focus on the left, r = -0.371, P < 0.01; focus on the right, r = -0.348, P < 0.05). The mean T2 relaxation time in newly diagnosed or chronic patients did not differ from each other or from control values. However, the T2 relaxation time of the left amygdala was > or = 111 msec (i.e., > or = 2 S.D. over the mean T2 time of the left amygdala in control subjects) in seven (10%) patients, one of which was newly diagnosed and six were chronic. The T2 time of the right amygdala was prolonged in eight (12%) patients, three of which were newly diagnosed and five were chronic. We did not find any clear asymmetries in amygdaloid volumes or T2 relaxation times between the ipsilateral and contralateral sides relative to seizure focus. According to the present findings, signs of amygdaloid damage were observed in approximately 20% of patients with temporal lobe epilepsy, most of which had chronic epilepsy.

Correlation of widespread preoperative magnetic resonance imaging changes with unsuccessful surgery for hippocampal sclerosis

Despite meticulous preoperative assessment, about 30% of patients with refractory partial epilepsy due to hippocampal sclerosis fail to become seizure free after appropriate temporal lobe surgery. Perioperative complications, hippocampal remnants, and bitemporal disease do not account for all failures; extrahippocampal epileptogenic tissue must persist in some patients. Such dual pathology is detected on routine visual inspection of magnetic resonance images in about 15% of patients with hippocampal sclerosis, but most such patients are excluded from surgery. We postulated that some patients have occult extrahippocampal cerebral structural abnormalities (i.e., subtle dual pathology) and that the presence of these abnormalities would be associated with a poor surgical outcome. Quantitative postprocessing of preoperative magnetic resonance images from 27 patients subsequently proved to have hippocampal sclerosis demonstrated extrahippocampal structural abnormalities in 14, 10 of whom did not become seizure free, while 11 of 13 patients without such changes did become seizure free (chi2, p < 0.005). Such structural information may supplement clinical decision making in some patients being evaluated for epilepsy surgery and help to explain the biological basis of poor outcome from such surgery.

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.

Acute and chronic effects of hypoxia on the developing hippocampus

Perinatal hypoxia is associated with both seizures arising acutely and the subsequent development of temporal lobe epilepsy (as determined retrospectively). We therefore attempted to identify acute and chronic morphological and/or electrophysiological hippocampal pathologies associated with experimentally induced hypoxia in immature rats. Pups were exposed to 15 minutes of hypoxia on 3 successive days (starting on postnatal day 8; P8), or to 60 minutes of hypoxia on P10 with either one or multiple hypoxia-induced seizures. For animals experiencing multiple seizures, flurothyl seizure threshold was significantly lower than that of controls at 60 to 80 days, but not at 10 days, after hypoxia. Acutely, there was a treatment-related increase in the number and the density of pyknotic dentate and hilar neurons, in particular in animals experiencing multiple seizures. However, 60 to 80 days after the multiple-seizure protocol, the number of dentate and hilar neurons did not differ between control and experimental animals. Electrophysiological measures of pyramidal cell properties showed no striking difference between experimental and control animals at any time point. These results indicate that early postnatal hypoxia and hypoxia-induced seizure episodes decrease seizure threshold in the adult but produce minimal acute or chronic morphological or functional changes in the hippocampus.

Possible mechanisms inducing granule cell dispersion in humans with temporal lobe epilepsy

The stratum granulosum (SG) of the fascia dentata from 17 human epileptic hippocampi was assessed in terms of width, volumetric cell density (VCD) and percentage of cell loss to study the granule cell dispersion (GCD) phenomenon described by Houser. GCD was considered when three conditions were observed, the SG was wider than 120 microns, granule cell (GC) somata did not remain in close apposition to one another the normal clear boundary between the molecular layer and the SG was not maintained. GCD involved a partial zone of the SG in six cases and the whole SG in two cases. Dynorphin mRNA in-situ hybridization was performed in two cases and allowed us to affirm that dispersed cells are actually GC. A close correlation linked GCD, GC loss and VCD decrease in diffuse CA4, laminated CA4, CA3, CA2 and CA1. The discussion is focused on the possible causes of dispersion. Some arguments did not suggest for a migration arrest during development. Nevertheless, in one case, a cluster of horizontal cells in the inner part of the molecular layer could evoke the persistence of normally transient cells during ontogenesis. A neo-migration due to permissive phenomenon induced by gliogenesis, mossy fibers sprouting in the supra-granular layer and over-expression of growth factors is suggested from experimental data. Nevertheless a straining due to the tissue shrinkage observed in severe hippocampal sclerosis (HS) could also be involved in the origin of GCD.

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.

The pathogenic and progressive features of chronic human hippocampal epilepsy

To design useful experimental models of epilepsy, it is necessary to clearly understand the known clinical-pathologic features of the disease process. Studies of mesial temporal lobe epilepsy (MTLE) patients have identified several distinctive clinical and pathophysiologic characteristics and many of these can be analyzed in experimental models. For example, patients with typical MTLE have medical histories that often contain an initial precipitating injury (IPI), are likely to have hippocampal sclerosis in the surgical specimen, and have better seizure outcomes than patients with typical idiopathic temporal seizures (i.e. cryptogenic). Hippocampal from children as young as age 1 year with IPI histories also demonstrate neuron damage similar to adults with hippocampal sclerosis. Compared to IPI patients without seizures (i.e. trauma, hypoxia, etc.), IPI cases with severe seizures showed younger ages at the IPI, shorter latent periods, and longer durations of habitual MTLE. Hippocampal damage is often bilateral, however, the epileptogenic side shows hippocampal sclerosis and the opposite side usually shows only mild neuron losses. Moreover, MTLE patients show declines in hippocampal neuron densities with very long histories of habitual seizures (15 to 20 years), however, the additional neuron loss adds to the template of hippocampal sclerosis and occurs in limited subfields (granule cells, CA1 and prosubiculum). Hippocampal axon and synaptic reorganization is another pathologic feature of MTLE, and involves granule cell mossy fibers and axons immunoreactive for neuropeptide upsilon, somatostatin, and glutamate decarboxylase (which synthesizes GABA). Finally, MTLE patients with hippocampal sclerosis show increased granule cell mRNA levels for brain derived neurotropic factor, nerve growth factor, and neurotrophin-3 that correlate with mossy fiber sprouting or with declines in Ammon's horn neuron densities. Taken together, our data support the following concepts: (1) The pathogenesis of MTLE is associated with IPI histories that probably injure the hippocampus at some time prior to habitual seizure onsets, (2) most of the damage seems to occur with the IPI, (3) there can be additional neuron loss associated with long histories, (4) another pathologic feature of MTLE is axon reorganization of surviving fascia dentata and hippocampal neurons, and (5) reorganized axon circuits probably contribute to seizure or propagation.

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.

Epilepsy surgery

Only 15% of patients with severe epilepsy with frequent partial seizures achieve any improvement in their seizure frequency by further drug treatment. As we know that epileptic seizures result in neuron loss with early development of mental deterioration, that the mortality rate of patients with epilepsy is increased and that an exact localization of the epileptogenic area which can be resected offers the possibility of curative treatment, we have a moral obligation to make this treatment available to people disabled with epilepsy. Surgery for mesial temporal sclerosis and lesional cortical partial epilepsy offers freedom from seizures in 70-80% of the patients, whereas non-lesional, cortical, partial epilepsy is more problematic, as only 30-40% of the patients will be seizure-free. Volumetric MRI, MR spectroscopy, SPECT and PET reduce the need for invasive monitoring in patients with temporal lobe epilepsy. Invasive recordings should be used when scalp-EEG, MRI, SPECT and PET cannot identify the epileptic focus; 50% of the patients who cannot be diagnosed by non-invasive recordings, can be diagnosed by invasive methods. When operated on 70% become seizure free, and a further 10% achieve a significant improvement. As age at surgery influences vocational outcome, surgical therapy should be considered in children. This will prevent their development into chronically ill patients, with all the known accompanying psychic handicaps this involves.

Tiagabine prevents seizures, neuronal damage and memory impairment in experimental status epilepticus

A novel antiepileptic drug, tiagabine ((R)-N-[4,4-di-(3-methylthien-2-yl) but-3-enyl] nipecotic acid hydrochloride), was studied in rats in order to determine its efficacy in preventing seizures, seizure-induced neuronal damage and impairment of spatial memory in the perforant pathway stimulation model of status epilepticus. In pilot experiments, administration of tiagabine (50, 100 or 200 mg/kg/day) with subcutaneously implanted Alzet osmotic pumps led to a dose-dependent increase in tiagabine concentrations in the serum and brain. Two days of tiagabine treatment at a dose range of 50-200 mg/kg/day did not change the levels of gamma-aminobutyric acid (GABA), glutamate or aspartate in cisternal cerebrospinal fluid (CSF) compared to the controls. In the pentylenetetrazol test, the maximal anticonvulsive effect of tiagabine administered via osmotic pumps was achieved already with a dose of 50 mg/kg/day. In the perforant pathway model of status epilepticus, subchronic treatment with tiagabine (Alzet pumps, 50 mg/kg/day) completely prevented the appearance of generalized clonic seizures during stimulation (P < 0.001). In the same rats, tiagabine treatment reduced the loss of pyramidal cells in the CA3c and CA1 fields of the hippocampus (P < 0.05) but not the loss of somatostatin immunoreactive neurons in the hilus. Two weeks after perforant pathway stimulation, the tiagabine-treated rats performed better in the Morris water-maze test than the vehicle-treated rats did (P < 0.001). Our results show that tiagabine treatment reduces the severity of seizures in the perforant pathway stimulation model of status epilepticus. Possibly associated with the reduction in seizure number and severity, tiagabine treatment also reduced seizure-induced damage to pyramidal cells in the hippocampus as well as the impairment of the spatial memory associated with hippocampal damage.

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.