Résumé
Objective To investigate the map and pattern of blood oxygen level dependent(BOLD)signal changes correlated to interictal epileptiform discharges(IEDs)with EEG-fMRI in patients with partial epilepsy and then to explore the pathophysiological mechanisms of epileptic discharges and their effect on brain function in partial epilepsy.Methods Through the method of EEG-fMRI,2 patients with parial epilepsy were studied.The relationship between the regions of BOLD signal changes linked to IEDs and the electroelinical localization of epileptogenic zone in patients with partial epilepsy were investigated.Results The epileptogenic areas localized by electroclinical findings in the 2 patients all showed maximal activation and 2 sites of significant activation were found in 1 of the 2 patients;Weak activation were also manifested in the opposite side corresponding to lesions.Conclusions IED-linked BOLD response in patients with partial epilepsy is mainly in epileptogenic zones and weak activation can also be seen in the corresponding contralateral areas of epileptogenic zoiles.Activation areas ale well concordant with epileptogenie areas localized by electroclinical findings.
Résumé
Using simultaneous EEG-correlated functional MRI (EEG-fMRI), we studied the blood oxygenation level-dependent (BOLD) signals in a juvenile myoclonic epilepsy (JME) patient with interictal epileptiform discharges. Extensive and symmetric activation and deactivation areas were assessed in bilateral hemispheric regions respectively, and these signals decreased gradually from the parieto-occipital region to the frontal region. Activations were found in cuneus, insulae, mesial midfrontal region, midline and bilateral cerebellum and thalamus, while the deactivities were in the bilateral anterior frontal region and parietal region as well as the posterior cingulate gyri. These findings suggest that the synchronized neuronal activities represented by spike and wave complex in EEG be reflected in the activation of BLOD signals in thalamocortical regions. However, those regions of deactivation reflect the suspension of the default state of brain function resulting indirectly from this discharge. There is good correspondence between neuronal activity (EEG) and fMRI. The combination of EEG and fMRI is a powerful tool in studying brain function.