Jean Isnard

Clinical manifestations of insular lobe seizures: a stereo-electroencephalographic study.

Summary:  Purpose: In this study, we report the clinical features of insular lobe seizures based on data from video and stereo‐electroencephalographic (SEEG) ictal recordings and direct electric insular stimulation of the insular cortex performed in patients referred for presurgical evaluation of temporal lobe epilepsy (TLE).

The role of the insular cortex in temporal lobe epilepsy

The role of the insular cortex in the genesis of temporal lobe epileptic (TLE) seizures has been investigated in 21 patients with drug‐refractory TLE using chronic depth stereotactic recordings of the insular cortex activity and video recordings of ictal symptoms during 81 spontaneous electroclinical seizures. All of the recorded seizures were found to invade the insula, most often after a relay in the ipsilateral hippocampus (19/21 patients). However, 2 patients had seizures that originated in the insular cortex itself. Ictal symptoms associated with the insular discharges were similar to those usually attributed to mesial temporal lobe seizures, so that scalp video‐electroencephalographic monitoring does not permit making any difference between ictal symptoms of temporo‐mesial and insular discharges. A favorable outcome was obtained after a temporal cortectomy sparing the insular cortex in 15 of 17 operated patients. Seizures propagating to the insular cortex were found to be fully controlled by surgery, whereas those originating in the insular cortex persisted after temporal cortectomy. The fact that seizures originating in the insular cortex are not influenced by temporal lobectomy is likely to explain some of the failures of this surgical procedure in TLE. Ann Neurol 2000;48:614–623

Functional Mapping of the Insular Cortex: Clinical Implication in Temporal Lobe Epilepsy

Summary: Purpose: We report the results of 75 intracortical electrical stimulations of the insular cortex performed in 14 patients during stereo‐electroencephalography (SEEG) investigation of drug‐resistant partial epilepsy. The insular cortex was investigated on electroclinical arguments suggesting the possibility of a perisylvian spread or a rapid multilobar diffusion of the discharges during video EEG.

An attention modulated response to disgust in human ventral anterior insula

The human brain is expert in analyzing rapidly and precisely facial features, especially emotional expressions representing a powerful communication vector. The involvement of insula in disgust recognition has been reported in behavioral and functional imaging studies. However, we do not know whether specific insular fields are involved in disgust processing nor what the processing time course is. Using depth electrodes implanted during presurgical evaluation of patients with drug‐refractory temporal lobe epilepsy, we recorded intracerebral event‐related potentials to human facial emotional expressions, that is, fear, disgust, happiness, surprise, and neutral expression. We studied evoked responses in 13 patients with insular contacts to specify the insular fields involved in disgust processing and assess the timing of their activation. We showed that specific potentials to disgust beginning 300 milliseconds after stimulus onset and lasting 200 milliseconds were evoked in the ventral anterior insula in four patients. The occurrence and latency of event‐related potentials to disgust in the ventral anterior insula were affected by selective attention. The analysis of spatial and temporal characteristics of insular responses to disgust facial expression lead us to underline the crucial role of ventral anterior insula in the categorization of facial emotional expressions, particularly the disgust. Ann Neurol 2003

Neurophysiological Monitoring for Epilepsy Surgery: The Talairach SEEG Method

Object of the Study: In some candidates for epilepsy surgery in whom the decision to operate is difficult to make, invasive presurgical investigations, namely depth electrode recordings, may be needed. The SEEG (StereoElectroEncephaloGraphy) method consists of stereotactic orthogonal implantation of depth electrodes (5 to 15, 11 on average). The object of this study is to clarify the indications for SEEG, to expose its complications, and to display its usefulness in terms of surgical strategy and results. Patients and Methods: 100 patients, suffering from drug-resistant epilepsy and selected as candidates for surgical resection, underwent SEEG between 1996 and 2000. A total of 1,118 electrodes were implanted. For each single case, the sites of implantation of the electrodes were chosen in order to determine either the side of the onset of seizures, or the uni- or multilobar feature of them, or a possible operculo-insular propagation from a temporal onset, and also, using direct electrode stimulation, the proximity of speech or motor area. Results: Complications occurred in 5 patients (2 superficial infections, 2 breakages of electrodes, and 1 intracerebral hematoma responsible for death). SEEG was helpful in most (84%) of the 100 patients to confirm or annul surgical indication, and to adjust the extent of the resection. In some cases (14%), SEEG allowed to propose a resection that might have been disputable based solely on noninvasive investigation data. For frontal epilepsy, SEEG was crucial in all cases to delineate the extent of resection. Conclusion: SEEG proved to be a relatively safe and a very useful method in ‘difficult’ candidates for epilepsy surgery. In addition, in some cases the implanted electrodes can be used to perform therapeutic RF thermocoagulation of epileptic foci or networks.

Somatotopic organization of pain responses to direct electrical stimulation of the human insular cortex

ABSTRACT The question whether pain encoding in the human insula shows some somatotopic organization is still pending. We studied 142 patients undergoing depth stereotactic EEG (SEEG) exploration of the insular cortex for pre‐surgical evaluation of epilepsy. 472 insular electrical stimulations were delivered, of which only 49 (10.5%) elicited a painful sensation in 38 patients (27%). Most sites where low intensity electric stimulation produced pain, without after‐discharge or concomitant visually detectable change in EEG activity outside the insula, were located in the posterior two thirds of the insula. Pain was located in a body area restricted to face, upper limb or lower limb for 27 stimulations (55%) and affected more than one of these regions for all others. The insular cortex being oriented parallel to the medial sagittal plane we found no significant difference between body segment representations in the medio‐lateral axis. Conversely a somatotopic organization of sites where stimulation produced pain was observed along the rostro‐caudal and vertical axis of the insula, showing a face representation rostral to those of upper and lower limbs, with an upper limb representation located above that of the lower limb. These data suggest that, in spite of large and often bilateral receptive fields, pain representation shows some degree of somatotopic organization in the human insula.

Does the insula tell our brain that we are in pain

&NA; Current knowledge on pain‐related cerebral networks has relied so far on stimulus‐induced brain responses, but not on the analysis of brain activity during spontaneous pain attacks. In this case report, correlation between intracerebral field potentials and online sensations during spontaneously painful epileptic seizures suggests a crucial role of the insula in the development of subjective pain. Attacks originated from a very limited dysplasia located in the posterior third of the right insula and propagated to other areas of the pain matrix, including the parietal operculum and the midcingulate gyrus. Concomitant painful symptoms started on the left hand or the left foot and extended in a few seconds to the whole left side of the body, sparing the head. Continuous during the first seconds of the attack, the painful feeling evolved to throbbing and remained so until it progressively vanished, together with the spike discharge. Stimulation of the insula, but not of other pain matrix regions, induced pain identical to that of seizures. After thermocoagulation of the insular epileptic focus, a short, transient exacerbation of seizures with same painful features but different location was observed before a long‐lasting and complete remission of the attacks. Although these preliminary data need to be confirmed, they strongly suggest that if the full pain experience involves the pain matrix network, the posterior insula seems to play a leading role in the triggering of this network and the resulting emergence of subjective pain experience. Evidence from intracerebral EEG recordings of epileptic painful seizures reveals that the posterior insula seems to play a leading role in the triggering of the so called pain matrix cortical network and the resulting emergence of subjective pain experience.

Basic mechanisms of central rhythms reactivity to preparation and execution of a voluntary movement: a stereoelectroencephalographic study.

OBJECTIVE To localize the sources of mu, beta and gamma rhythms and to explore the functional significance of their reactivity. METHODS We used the method of quantification of event-related desynchronization (ERD) and synchronization (ERS) to analyze the reactivity of intracerebral rhythms recorded in stereoelectroencephalography within the sensorimotor areas during the preparation and the execution of a simple self-paced hand movement. We recorded 3 epileptic subjects who were explored before a surgical treatment. RESULTS An ERD of mu and beta rhythms has been recorded before the movement onset in the precentral gyrus, spreading then to the postcentral gyrus and to the frontal medial cortex. The frontal lateral cortex was inconstantly involved during the movement. The movement offset was followed by an important and focused beta ERS which was found within the pre- and post-central gyrus and the frontal medial cortex. Within the beta band, we observed several narrower bands with different reactivities and locations. Focused gamma reactivity was also found in the precentral and postcentral gyri. CONCLUSIONS The reactivities of mu and beta rhythms are different but their locations overlap. Mu ERD is a diffuse phenomenon that reflects the activation of all the sensorimotor areas during a simple movement. Beta band is likely to be composed of different rhythms with different functional significance. The primary motor area seems to contain two distinct areas with different reactivity to the movement preparation and execution.

SEEG‐guided RF Thermocoagulation of Epileptic Foci: Feasibility, Safety, and Preliminary Results

Summary:  Purpose: Depth electrodes recordings may be required in some cases of epilepsy surgery to delineate the best region for cortical resection. We usually implant depth electrodes according to Talairachs stereoelectroencephalography (SEEG) method. By using these permanently implanted depth electrodes, we are able to perform radiofrequency (RF)‐thermolesions of the epileptic foci. We report the technical data required to perform such multiple cortical thermolesions, as well as preliminary results in terms of seizure outcome in a group of 20 patients.

Involvement of Medial Pulvinar Thalamic Nucleus in Human Temporal Lobe Seizures

Summary:  Purpose: Several animal studies suggest that the thalamus might be involved in the maintenance and propagation of epileptic seizures. However, electrophysiologic evidence for this implication in human partial epileptic seizures is still lacking. Considering the rich and reciprocal connectivity of the medial pulvinar (PuM) with the temporal lobe, we evaluated a potential participation of this thalamic nucleus in temporal lobe epilepsy (TLE).