False lateralization of ictal EEG onset is uncommon in temporal lobe epilepsy, but has been reported in mesial TLE with hippocampal sclerosis or vascular malformation.1-7 This phenomenon may relate to low-amplitude ictal discharges from cortical atrophy or cerebral damage, severe hippocampal sclerosis ("burned-out" hippocampus), rapid contralateral spread via hippocampal commissures, anterior commissure, or frontal limbic pathways, or the coexistence of multiple epileptogenic foci.1, 2, 8-10 This clinical vignette highlights the particular value of stereoelectroencephalography (SEEG) for anatomo-electro-clinical correlations when ictal EEG onset conflicts with imaging or semiology. We report a 21-year-old right-handed woman, with no prior medical history, who developed seizures at age nine. They initially consisted of isolated loss of awareness. At age 14, following a focal to bilateral tonic–clonic seizure, MRI revealed a left parahippocampal gyrus cavernoma, which was resected. Despite this, seizures persisted under multiple antiseizure medications. Over time, her seizures evolved to include a rising chest sensation and déjà-vu, followed by impaired awareness, oroalimentary automatisms, and right-hand dystonia, with postictal headaches and aphasia. Scalp EEG showed right anterior and middle temporal spikes, with rare left anterior temporal spikes. Two habitual seizures were recorded: the first began with a right posterior temporal discharge spreading to the entire right temporal electrodes (Figure 1A), while the second was brief and without significant EEG change. Magnetoencephalography revealed predominantly right temporal spikes with rare independent left temporal discharges. Positron emission tomography (PET) demonstrated bilateral temporo-parietal hypometabolism and focal hypometabolism at the prior resection site. Neuropsychological testing showed impaired verbal declarative memory with preserved visual memory. Given the discordance between seizure semiology, MRI, and scalp EEG ictal onset, SEEG was performed. It revealed background slowing around the left temporo-basal resection cavity, as well as in the right temporo-basal region and temporal pole. Abundant pseudo-periodic spikes arose from the left temporo-basal region, sometimes also asymptomatic rhythmic discharges, and fewer spikes were observed in the left entorhinal and parahippocampal gyri. High-amplitude spikes were also recorded in the right amygdala, hippocampus, and parahippocampal gyrus, activated during sleep and occurring at a lower rate than the left temporo-basal ones. Habitual seizures were recorded during SEEG, showing a characteristic progression (Figure 1B). They began with flattening and disappearance of interictal spikes, followed by a progressive build-up of low-voltage fast activity in the left parahippocampal gyrus, then rhythmic theta activity in both temporo-basal regions. Two distinct hemispheric patterns were observed: on the left, a sinusoidal alpha rhythm with superimposed fast activity evolved into spike–wave discharges in the temporo-basal area, propagating to the hippocampus after 15 seconds; on the right, low-voltage fast activity arose in the temporo-basal area, spreading to the amygdala and hippocampus after 20 seconds, and to the insula after 25 seconds. Seizure activity terminated earlier on the right than on the left. The patient underwent SEEG-guided radiofrequency thermocoagulation of the left temporo-basal contacts surrounding the resection cavity and has remained seizure-free for 9 months. This case highlights the key role of anatomo-electro-clinical correlations in defining the epileptogenic zone. Any discrepancies should prompt suspicion and warrant further exploration with SEEG.6, 7 In such cases, bilateral SEEG implantation with extensive sampling of mesial and basal temporal structures is paramount to distinguish delays in regional involvement at seizure onset. In our patient, omission of electrodes around the resection cavity would have led to recording only the bitemporal activity emerging after the true onset, potentially leading to the erroneous diagnosis of bitemporal epilepsy. In our patient, seizure semiology (right-hand dystonia and postictal aphasia) suggested a left temporal onset, consistent with the left-sided resection cavity but conflicting with the right-sided onset on EEG. SEEG exploration demonstrated a left temporo-basal epileptogenic zone with rapid contralateral propagation. Several factors may explain the false lateralization. The deep location and limited spatial extent of the seizure onset zone, combined with the low amplitude of the initial ictal discharge, likely precluded the detection of early ictal activity on scalp EEG. Consequently, the recorded ictal EEG primarily reflected the propagation of the discharge, which exhibited greater amplitude and spatial spread in the right temporal lobe. Similar mechanisms have been previously proposed in the literature.1, 2 The resection cavity may also have restricted ipsilateral propagation toward the anterior left temporal lobe, enhancing the visibility of the right-sided spread. We are grateful to our patient for consenting to the publication of her medical case. We thank Dr. Caroline Briere and Prof. Agnès Trebuchon for their clinical management of the patient. This work was supported as part of the national plan for rare diseases by the French Ministry of Health. The authors have no conflict of interest to disclose. The data that supports the findings of this study is available on request from the corresponding author. The data is not publicly available due to privacy or ethical restrictions. Data S1: Data S2: Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article. Which of the following mechanisms can explain false lateralization of ictal EEG onset in temporal lobe epilepsy? Which clinical or investigative finding should raise suspicion for false lateralization in a patient with temporal lobe epilepsy? Which of the following strategies helps reduce the risk of misinterpretation due to false lateralization during presurgical evaluation of temporal lobe epilepsy? Answers may be found in the supporting information
Dhoisne et al. (Tue,) studied this question.