A differential brain response to the subject's own name persists during sleep

METHODS

Auditory evoked potentials (AEPs) to the subject's own name and to seven other first names were recorded in ten normal adults during wakefulness, in both passive listening and active detection conditions, and during sleep stage II (SII) and paradoxical sleep (PS). All stimuli were disyllabic, equiprobable and presented in random order.

RESULTS

During wakefulness, a parietal positive 'P3' component, peaking at about 500 ms, probably equivalent to the endogenous P300 wave, was enhanced in response to the subject's own name, even in the passive condition. During SII, K-complexes (KCs) were evoked by all first names and were formed by two biphasic consecutive waveforms. While the amplitude of the late complex (N3/P4) was identical for both types of stimuli, the early portion of the KC (N2/P3), and notably the positive wave 'SII-P3' at about 600 ms, was selectively enhanced after the subject's own name. This supports the hypothesis that at least two distinct neuronal systems are activated in parallel in response to auditory stimuli during SII, one reflecting the detection of stimulus' salience and the other the processing of its intrinsic relevance. During PS, the AEP morphology was comparable to that observed in wakefulness. Notably, a posterior 'PS-P3' wave appeared exclusively in response to own names at about 550 ms, and was considered as an equivalent of the waking P300.

CONCLUSIONS

These results suggest that the sleeping brain, during SII and PS, elicits a differential cognitive response to the presentation of the subject's own name, comparable to that occurring during wakefulness, and therefore that the sleeping brain is able to detect and categorize some particular aspects of stimulus significance.

Timing and spatial distribution of somatosensory responses recorded in the upper bank of the sylvian fissure (SII area) in humans

We studied responses of the parieto-frontal opercular cortex to electric stimuli, as recorded by intra-cortical electrodes during stereotactic EEG presurgical assessment of patients with drug-resistant temporal lobe epilepsy. After electrical stimulation of the median nerve at the wrist, we consistently recorded a negative-positive biphasic response peaking at 60 ms (N60) and 90 ms (P90) post-stimulus in the upper bank of the sylvian fissure contralateral to stimulation. Talairach stereotactic coordinates of the electrode contacts recording these responses covered the pre- and post-rolandic part of the upper bank of the sylvian fissure (25<x<55 mm; -27<y<+13 mm; 0<z<21 mm), corresponding to the accepted localization of SII area in man. The sources of these responses were deeply situated in the cortex of the upper bank of the sylvian fissure at approximately 40 mm from the midline sagittal plane, so that some of them could be located in the insular cortex. Moreover this study suggests the existence of dipolar SII sources radial to the scalp surface, which are overlooked in magnetic recordings. Somatosensory evoked potentials (SEPs) recorded in SII are delayed by approximately 40 ms as compared with SEPs generated in the primary somatosensory cortex. This long delay between SI and SII responses is not fully explained though it is coherent with the timing of activation issued from MEG source modeling data.

Transient and falsely lateralizing flumazenil-PET asymmetries in temporal lobe epilepsy

We have observed a falsely lateralizing mesial temporal [11C]-flumazenil binding asymmetry in three patients who had temporal lobe epilepsy (TLE) with normal hippocampal volumes. This abnormality was not detected 3 months later in two of the patients who underwent a second PET study. We conclude that transient and falsely lateralizing changes of flumazenil binding might occur in patients with TLE and no hippocampal sclerosis.

Electrical stimulation of motor cortex for pain control: a combined PET-scan and electrophysiological study

Although electrical stimulation of the precentral gyrus (MCS) is emerging as a promising technique for pain control, its mechanisms of action remain obscure, and its application largely empirical. Using positron emission tomography (PET) we studied regional changes in cerebral flood flow (rCBF) in 10 patients undergoing motor cortex stimulation for pain control, seven of whom also underwent somatosensory evoked potentials and nociceptive spinal reflex recordings. The most significant MCS-related increase in rCBF concerned the ventral-lateral thalamus, probably reflecting cortico-thalamic connections from motor areas. CBF increases were also observed in medial thalamus, anterior cingulate/orbitofrontal cortex, anterior insula and upper brainstem; conversely, no significant CBF changes appeared in motor areas beneath the stimulating electrode. Somatosensory evoked potentials from SI remained stable during MCS, and no rCBF changes were observed in somatosensory cortex during the procedure. Our results suggest that descending axons, rather than apical dendrites, are primarily activated by MCS, and highlight the thalamus as the key structure mediating functional MCS effects. A model of MCS action is proposed, whereby activation of thalamic nuclei directly connected with motor and premotor cortices would entail a cascade of synaptic events in pain-related structures receiving afferents from these nuclei, including the medial thalamus, anterior cingulate and upper brainstem. MCS could influence the affective-emotional component of chronic pain by way of cingulate/orbitofrontal activation, and lead to descending inhibition of pain impulses by activation of the brainstem, also suggested by attenuation of spinal flexion reflexes. In contrast, the hypothesis of somatosensory cortex activation by MCS could not be confirmed by our results.

[Operculo-insular responses to nociceptive skin stimulation in humans. A review of the literature]

CO2 laser stimulation selectively activates the endings of small myelinated A delta fibers, involved with non-myelinated C fibers in the processing of nociceptive information. Thus, potentials evoked by CO2 laser stimulation reflect the activation of cortical areas receiving inputs from the spinothalamic tract. In this article we review data on the early pain-related CO2 laser evoked potentials recorded on the scalp, or by intracortical electrodes, during presurgical assessment of patients with drug-resistant epilepsy. A combination of surface and depth recordings allows the description of early cortical pain responses in terms of latency, polarity and scalp topography. Such a technique also allows the localization of the anatomical generators of these early responses using dipolar source modeling of scalp-recorded evoked potentials, or intracortical recordings, in stereotactical conditions. The earliest response recorded on the scalp to CO2 laser stimulation was an N1-P1 dipolar potential field at a latency of 140-200 ms. The N1 and P1 maximal voltages are recorded in the temporal region contralateral to stimulation and mid-frontal region, respectively. Intracerebral electrodes record an activation of a dipolar cortical source in the same latency range located in the upper bank of the sylvian fissure, corresponding to the second somatosensory (SII) area ipsi- and contralateral to the stimulation and insular cortex. The SII-insular responses ipsilateral to stimulation are likely to be triggered via transcallosal fibers coming from the opposite SII area. The operculo-insular cortex contralateral to stimulation, activated through direct thalamocortical projections, is likely to represent the first step in the cortical processing of peripheral A delta fiber pain inputs.

An H(2) (15)O-PET study of cerebral blood flow changes during focal epileptic discharges induced by intracerebral electrical stimulation

Partial epileptic seizures are known to cause a focal increase in cerebral blood flow (CBF). However, quantified studies of ictal CBF changes under intracranial EEG control are still needed to assess the relationships in time and space between CBF changes and electrical discharges. Ten patients undergoing an intracerebral stereotaxic EEG (stereo-EEG) investigation for epilepsy surgery were prospectively studied for local perfusion changes. These were measured by H(2)(15)O-PET during 12 subclinical or mild symptomatic focal epileptic discharges induced by intracerebral electrical stimulation of the hippocampus (eight), amygdala (two), temporal pole (one) and fusiform gyrus (one). This study aimed to assess whether a significant focal blood flow change reflected the geographical extent of the underlying coincident epileptic discharge, as measured by this method at seizure onset. No significant CBF change was observed on test-retest at rest or during ineffective electrical stimulations outside the epileptogenic area. Compared with the resting condition, a significant focal perfusion increase of 16-55% occurred during eight discharges, there was no CBF change in three and a significant CBF decrease in one. Ictal CBF increases were mostly associated with low-voltage fast activity, but their magnitude had no obvious link with the duration of the discharge (range 8-106 s). Regional analysis of ictal PET was performed in 10 anatomical areas during each of the 12 discharges. Of all the 120 regions, 59 were not explored by intracerebral electrodes and 14 (24%) of these demonstrated ictal CBF changes. In 43 of the 61 regions explored by stereo-EEG (70.5%), PET and depth EEG findings converged, showing either a CBF change in a discharging area or no CBF change in a region unaffected by the discharge. Areas of increased CBF indicated an underlying epileptic discharge in almost 100% of the cases. Conversely, of the 18 regions showing discrepancies between intracerebral recordings and PET data, 17 were discharging regions showing no ictal CBF changes. Thus, a focal CBF increase, when detected at the seizure onset concomitantly with the initial low-voltage fast activity, was a reliable marker of an underlying epileptic discharge. It emphasizes the importance of injecting blood-flow tracers as soon as possible after detection of the discharge in routine clinical studies, even at a subclinical stage of the seizure. However, the extent of significant ictal CBF changes can be more restricted than that of the electrical discharge, thus limiting the reliability of ictal CBF images for outlining the contours of a tailored cortectomy.

[Clinical neurophysiology and functional neuroimaging at the Société Française de Neurologie (1948-1998)]

The historical role of the French Neurology in the development of anatomo-clinical method is likely to explain why the first communications on electrophysiology were presented in Paris with some delay, as compared with other european societies where the neurophysiological tradition had been more lively. Though clinical neurophysiology, by essence, addresses the pathophysiology of neurological disorders, it has sometimes missed this target at its very beginning, when it aimed at providing data supposed to have some aetiological specificity, causing distrust among neurologists used to accept aetiological diagnosis only when based on post-mortem anatomical evidence. Thanks to the discovery of computerized tomography this time has been over for 25 years, and no one would question anymore the role of clinical neurophysiology and neuroimaging in Neurology, the former giving access to the timing of sensori-motor and cognitive pocesses and the latter to the localization of brain functions. This article reviews the neurophysiological literature published in the Revue Neurologique from 1948 to 1998.

Haemodynamic brain responses to acute pain in humans: sensory and attentional networks

Turning attention towards or away from a painful heat stimulus is known to modify both the subjective intensity of pain and the cortical evoked potentials to noxious stimuli. Using PET, we investigated in 12 volunteers whether pain-related regional cerebral blood flow (rCBF) changes were also modulated by attention. High (mean 46.6 degrees C) or low (mean 39 degrees C) intensity thermal stimuli were applied to the hand under three attentional conditions: (i) attention directed towards the stimuli, (ii) attention diverted from the stimuli, and (iii) no task. Only the insular/second somatosensory cortices were found to respond whatever the attentional context and might, therefore, subserve the sensory-discriminative dimension of pain (intensity coding). In parallel, other rCBF changes previously described as 'pain-related' appeared to depend essentially on the attentional context. Attention to the thermal stimulus involved a large network which was primarily right-sided, including prefrontal, posterior parietal, anterior cingulate cortices and thalamus. Anterior cingulate activity was not found to pertain to the intensity coding network but rather to the attentional neural activity triggered by pain. The attentional network disclosed in this study could be further subdivided into a non-specific arousal component, involving thalamic and upper brainstem regions, and a selective attention and orientating component including prefrontal, posterior parietal and cingulate cortices. A further effect observed in response to high intensity stimuli was a rCBF decrease within the somatosensory cortex ipsilateral to stimulation, which was considered to reflect contrast enhancing and/or anticipation processes. Attentional processes could possibly explain part of the variability observed in previous PET reports and should therefore be considered in further studies on pain in both normal subjects and patients with chronic pain.

Different contribution of joint and cutaneous inputs to early scalp somatosensory evoked potentials

To elucidate whether the frontal components of scalp somatosensory evoked potentials (SEPs) depend on the type of peripheral input, we compared scalp SEPs in response to electrical stimuli applied to: (i) the proximal phalanx of the thumb, involving both deep and cutaneous afferents; and (ii) the distal phalanx of the thumb, involving cutaneous afferents, but excluding joint inputs coming from the interphalangeal articulation. We applied the same dipolar model that we built to explain the scalp SEP distribution to median nerve stimulation in previous investigations. Cortical SEPs after proximal stimulation were generated by three dipolar sources, one of which was likely to account for the frontal scalp N30. When we analyzed SEPs for distal (purely cutaneous) stimulation, the frontal and central recordings showed a clear reduction in amplitude of the negative responses having a latency of about 30 ms. Moreover, when applying the dipole model derived from analysis of responses to proximal stimulation to SEPs to distal stimulation, the source corresponding to the N30 distribution showed no activity, suggesting a strong relationship between joint and tendinous inputs and the activity of the N30 generator.

[Modification of ictal cerebral blood flow studied by positron emission tomography (PET) and stereoelectroencephalography (SEEG)]

Converging evidence suggests that partial epileptic seizures can cause a circumscribed increase of CBF. However, quantified studies of ictal perfusion changes verified by intracranial EEG are still needed to better evaluate the relationships between CBF changes and the underlying electrical activity. We studied, in 10 patients undergoing a SEEG for epilepsy surgery, the local perfusion changes measured by [15O]-H2O PET during focal epileptic discharges induced by intracerebral electrical stimulation. CBF measurements under SEEG control were performed at rest and during stimulations eliciting, or not, subclinical or mild symptomatic epileptic discharges. PET and magnetic resonance imaging slices parallel to the AC-PC plane were matched for anatomical identification of cortical regions. Individual normalized CBF difference images between rest and stimulation (with or without induced discharge) were analysed by a hierchical description and multiscale detection method. Only CBF changes at p < 0.01 were considered significant. No significant CBF change was observed on test-retest at rest or during ineffective stimulations. Among the 12 elicited discharges, of which 11 involved mainly the temporal lobe, 8 were associated with a focal CBF increase (16-55 p. 100), there was no CBF change in 3, and a significant CBF decrease was observed in 1 (64 p. 100). These latter 4 discharges were restricted to mesio-temporal lobe structures. PET data were analysed in the same 10 anatomical areas during each of the 12 discharges. In 70.5 p. 100 of the 61 regions explored by SEEG, PET and depth EEG findings were consistent, showing either a CBF change in a discharging area, or no CBF change in a region unaffected by the discharge. Areas of increased CBF indicated an underlying epileptic discharge in almost 100 p. 100 of the cases. Discrepancies between SEEG and PET concerned almost always discharging regions showing no ictal CBF changes. A focal CBF increase detected at the seizure onset is a reliable marker of an underlying epileptic discharge. However, the extent of the CBF changes can be more restricted than that of the electrical discharge, and ictal discharges restricted to the mesial temporal cortex can be overlooked by CBF studies.

Hyperalgesia with reduced laser evoked potentials in neuropathic pain

Nociceptive evoked potentials to laser stimuli (LEPs) are able to detect lesions of pain and temperature pathways at peripheral, spinal and supraspinal levels. It is commonly accepted that LEP attenuation correlates with the loss of pain and temperature sensations, while pathological heat-pain hypersensitivity has been associated with increased LEP amplitude. Here we present two patients in whom increased pain sensation (hyperalgesia) to laser stimuli was, on the contrary, associated to delayed, desynchronized and attenuated LEPs. Both patients experienced increased unpleasantness and affective reactions to laser, associated to poor ability to localize the stimulus. In both cases the results may be explained by an overactivation of the 'medial pain system', in one patient due to deafferentation of cortical sensory areas by a capsular lesion, and in the other to imbalance between A-delta and C fiber excitation due to peripheral nerve injury. Our results suggest that LEPs, as currently recorded, reflect the activity of a 'lateral' pain system subserved by rapidly conducting fibers. They may therefore, assess the sensory and cognitive dimensions of pain, but may not index adequately the affective-emotional aspects of pain sensation conveyed by the 'medial' pain system. The dissociation between pain sensation and cortical EPs deserve to be added to the current semiology of LEPs, as the presence of abnormal pain to laser on the background of reduced LEPs substantiates the neuropathic nature of the pain.

Simplified projection of EEG dipole sources onto human brain anatomy

This study was aimed at determining an easy way to project dipole modelling results onto brain anatomy. This simplified projection is based on the estimation of the mean location of the centre of the dipole sphere according to internal brain landmarks. The mean values for the centre location were calculated from ten epileptic patients. To define the axes of the dipole model frame on the patient's magnetic resonance image (MRI), markers were pasted at some electrode positions during the acquisition. An estimation was then made of the mean position of the model centre from the bicommissural line (anterior commissure-posterior commissure [AC-PC]), and a simple transformation to pass from the model cartesian coordinates to the anatomical correlates either in the subject MRI or in the Talairach atlas. These data were then tested in four additional subjects in whom no markers had been placed during the MRI acquisition. On average, the horizontal plane of the sphere model was pitched up 1.9 degrees +/- 1.8 only with respect to the AC-PC horizontal plane, which allowed the projection of dipoles directly onto the Talairach atlas, without pitch. The mean sphere centre was located 7.4 +/- 4.2 mm above the bicommissural line, and 8.2 +/- 1 mm in front of the posterior commissure. In the four additional subjects, projections on MRI and atlas indicated the same anatomical regions and showed high congruence with the physiology or the pathology. This simplified way we report herein has proved to give reliable results. We believe that this method will be useful as a first approximation to project dipole coordinated onto MRI data; moreover, when MRI is unavailable, our results show that dipole modelling results can be superimposed onto atlas slices provided that they are represented according to the AC-PC plane.

Functional anatomy of perceptual and semantic processing for odors

The functional anatomy of perceptual and semantic processings for odors was studied using positron emission tomography (PET). The first experiment was a pretest in which 71 normal subjects were asked to rate 185 odorants in terms of intensity, familiarity, hedonicity, and comestibility and to name the odorants. This pretest was necessary to select the most appropriate stimuli for the different cognitive tasks of the second experiment. The second one was a PET experiment in which 15 normal subjects were scanned using the water bolus method to measure regional cerebral blood flow (rCBF) during the performance in three conditions. In the first (perceptual) condition, subjects were asked to judge whether an odor was familiar or not. In the second (semantic) condition, subjects had to decide whether an odor corresponded to a comestible item or not. In the third (detection) condition, subjects had to judge whether the perceived stimulus was made of an odor or was just air. It was hypothetized that the three tasks were hierarchically organized from a superficial detection level to a deep semantic level. Odorants were presented with an air-flow olfactometer, which allowed the stimulations to be synchronized with breathing. Subtraction of activation images obtained between familiarity and control judgments revealed that familiarity judgments were mainly associated with the activity of the right orbito-frontal area, the subcallosal gyrus, the left inferior frontal gyrus, the left superior frontal gyrus, and the anterior cingulate (Brodmann's areas 11, 25, 47, 9, and 32, respectively). The comestibility minus familiarity comparison showed that comestibility judgments selectively activated the primary visual areas. In contrast, a decrease in rCBF was observed in these same visual areas for familiarity judgments and in the orbito-frontal area for comestibility judgments. These results suggest that orbito-frontal and visual regions interact in odor processing in a complementary way, depending on the task requirements.

Intracortical recordings of early pain-related CO2-laser evoked potentials in the human second somatosensory (SII) area

We studied responses of the parieto-frontal opercular cortex to CO2-laser stimulation of A delta fiber endings, as recorded by intra-cortical electrodes during stereotactic-EEG (SEEG) presurgical assessment of patients with drug-resistant temporal lobe epilepsy. After CO2-laser stimulation of the skin at the dorsum of the hand, we consistently recorded in the upper bank of the sylvian fissure contralateral to stimulation, a negative response at a latency of 135 +/- 18 ms (N140), followed by a positivity peaking around 171 +/- 22 ms (P170). The stereotactic coordinates in the Talairach's atlas of the electrode contacts recording these early responses covered the pre- and post-rolandic part of the upper bank of the sylvian fissure (-27 < y < +12 mm; 31 < x < 57 mm; 4 < z < 23 mm), corresponding to the accepted localization of the SII area in man, possibly including the upper part of the insular cortex. The spatial distribution of these early contralateral responses in the SII-insular cortex fits wit that of the modeled sources of scalp CO2-laser evoked potentials (LEPs) and with PET data from pain activation studies. Moreover, this study showed the likely existence of dipolar sources radial to the scalp surface in SII, which are overlooked in magnetic recordings. Early responses also occurred in the SII area ipsilateral to stimulation peaking 15 ms later than in contralateral SII, suggesting a callosal transmission of nociceptive inputs between the two SII areas. Other pain responsive areas such as the anterior cingulate gyrus, the amygdala and the orbitofrontal cortex did not show early LEPs in the 200 ms post-stimulus. These findings suggest that activation of SII area contralateral to stimulation, possibly through direct thalamocortical projections, represents the first step in the cortical processing of peripheral A delta fiber pain inputs.

Course of valvular strands in patients with stroke: cooperative study with transesophageal echocardiography

BACKGROUND

Native valve strands might be related to the acute stage of thrombosis or might suggest a long-term valvular change. We aimed to estimate changes in the strands in patients with stroke through a serial transesophageal echocardiographic (TEE) study.

METHODS AND RESULTS

A study was conducted among patients who were referred for TEE for stroke or cardiac pathology. Patients had TEE examinations with a 5-MHz multiplane TEE probe. Echocardiography was repeated 3 months later in patients with stroke. TEE was performed in 180 patients admitted to cardiology units and in 160 patients referred to neurology units. Among 34 patients with valvular strands, 30 were referred to neurology for stroke, whereas 4 patients were admitted to cardiology (18.8% versus 2.2%, difference 16.5%, 95% confidence interval 10% to 22.9%, P =.001). Strands were located on the mitral valve in 16 patients, the aortic valve in 6 patients, and both left heart valves in 8 patients. Among the 38 valves with strands, 17 (44. 7%) were morphologically normal, 4 (10.5%) were thickened, 7 (18.4%) were redundant, and 10 (26.3%) had both abnormalities. TEE showed other abnormalities in 16 (53.3%) patients, whereas 14 patients had only strands. Twenty-six (86.6%) patients had a second TEE study 3 months later. Strands were not found in 4 (15.4%) patients (95% confidence interval 4.3% to 34.9%).

CONCLUSIONS

Valvular thickening or redundancy may predispose valves to strand formation. Native valve strands usually persist and thus reflect a chronic valvular change.

Clinical utility of flumazenil-PET versus [18F]fluorodeoxyglucose-PET and MRI in refractory partial epilepsy. A prospective study in 100 patients

We assessed the clinical utility of [11C]flumazenil-PET (FMZ-PET) prospectively in 100 epileptic patients undergoing a pre-surgical evaluation, and defined the specific contribution of this neuro-imaging technique with respect to those of MRI and [18F]fluorodeoxyglucose-PET (FDG-PET). All patients benefited from a long term video-EEG monitoring, whereas an intracranial EEG investigation was performed in 40 cases. Most of our patients (73%) demonstrated a FMZ-PET abnormality; this hit rate was significantly higher in temporal lobe epilepsy (94%) than in other types of epilepsy (50%) (P < 0.001). Most FMZ-PET findings coexisted with a MRI abnormality (81%), including hippocampal atrophy (35%) and focal hypometabolism on FDG-PET (89%). The area of decreased FMZ binding was often smaller than that of glucose hypometabolism (48%) or larger than that of the MRI abnormality (28%). FMZ-PET did not prove superior to FDG-PET in assessing the extent of the ictal onset zone, as defined by intracranial EEG recordings. However, it provided useful data which were complementary to those of MRI and FDG-PET in three situations: (i) in temporal lobe epilepsy associated with MRI signs of hippocampal sclerosis, FMZ-PET abnormalities delineated the site of seizure onset precisely, whenever they were coextensive with FDG-PET abnormalities; (ii) in bi-temporal epilepsy, FMZ-PET helped to confirm the bilateral origin of seizures by showing a specific pattern of decreased FMZ binding in both temporal lobes in 33% of cases; (iii) in patients with a unilateral cryptogenic frontal lobe epilepsy, FMZ-PET provided further evidence of the side and site of seizure onset in 55% of cases. Thus, FMZ-PET deserves to be included in the pre-surgical evaluation of these specific categories of epileptic patients, representing approximately half of the population considered for epilepsy surgery.

[Recurrent Mollaret's meningitis of herpetic origin]

BACKGROUND

Benign recurrent meningitis, or Mollaret's meningitis, is an uncommon disease whose viral origin was long unidentified. Since 1991, about twenty cases have been reported in patients with herpes infection.

CASE REPORT

A female patient had experienced repeated episodes of spontaneous meningitis since 1983. The episodes resolved spontaneously and no etiology had been identified. A spinal tap was performed when the patient was again hospitalized a new episode of meningitis and PCR amplification of the herpes simplex virus type 2 (HSV 2) was positive. The patient was given long term acyclovir per os. A new spinal tap after resolution of the meningitis episode was PCR HSV2 negative.

DISCUSSION

HSV2 infection is one of the known causes of Mollaret's meningitis. Long-term antiviral therapy appears to prevent recurrence as was observed in our patient.

A stereoelectroencephalographic (SEEG) study of light-induced mesiotemporal epileptic seizures

PURPOSE

This study explored the mechanism of light-induced complex partial seizures by using ictal intracerebral recordings in a patient with refractory epilepsy of the right temporal lobe.

METHODS

Presurgical evaluation of this patient was realized by means of video-EEG recordings, WADA test, magnetic resonance imaging (MRI), F18-deoxyglucose and C11-flumazenil positron emission tomography (PET) interictal neuroimaging data, and stereoelectroencephalographic (SEEG) ictal recordings.

RESULTS

SEEG investigations demonstrated the right mesiotemporal origin of all the patient's seizures. This result was confirmed by a successful right temporal lobectomy. Moreover, SEEG recordings revealed a frequent interictal spiking activity in the right occipital visual cortex that was undetectable on scalp recordings. However, the occipital cortex was not involved at the onset of mesiotemporal ictal discharges and was not hyperresponsive to focal electrical stimulation.

CONCLUSIONS

This study shows that, in spite of interictal occipital spiking, the photosensitivity of mesiotemporal seizures can be observed in both the absence of occipital cortex involvement during ictal discharges and demonstrable hyperexcitability of the occipital cortex to light or direct electrical stimulation.

[Functional imaging in idiopathic generalized epilepsy]

Positron emission tomography has offered the possibility to investigate the pathophysiology of idiopathic generalized epilepsies. Absence epilepsies demonstrate normal cerebral glucose metabolism and benzodiazepine receptor density. Conversely, juvenile myoclonic epilepsies are associated with frontal hypometabolism, which aggravates during a working memory task. Typical 3 Hz spike and wave discharges lead to a diffuse hypermetabolism. The latter resembles that observed during GAERS rats absences, and clearly differs from the hypometabolism encountered in partial epilepsies associated with generalized spike and wave discharges. Overall, functional imaging data provide further evidence of syndromic specificities in idiopathic generalized epilepsies.