Sensory gating in epilepsy - effects of the lateralization of hippocampal sclerosis.

OBJECTIVE: The role of the hippocampus in sensory gating is unresolved as yet. The current study was conducted in order to examine the effects of hippocampal lesions on the function of auditory sensory gating. METHODS: Epilepsy patients with unilateral and bilateral hippocampal sclerosis (HS) were investigated. Auditory-evoked potentials (AEPs) were recorded by multichannel scalp EEG in a double-click experiment. Gating was defined as the response decrease of the AEP components from 1st to 2nd click. RESULTS: Diagnosis (left vs. right vs. bilateral HS) did not affect the amplitudes or gating of the P50, N100 or P200 components. However, diagnosis had an impact on the topography of the N100 component after its peak maximum: In right HS patients, the N100 was left-lateralized, while it was nearly symmetrically distributed in patients with left HS and right lateralized in patients with bilateral HS. Besides the N100, the topography of the P200 component was affected by diagnosis. CONCLUSIONS: Findings suggest that auditory activity, as reflected in the N100 and P200 components, is modulated by the hippocampus, but not sensory gating in its classical definition. SIGNIFICANCE: Deficits in P50 gating in schizophrenia are unlikely to be explained by hippocampal deficits.

Intracranially recorded memory-related potentials reveal higher posterior than anterior hippocampal involvement in verbal encoding and retrieval.

The human hippocampus is essential for both encoding and recollection, but it remains controversial whether there is a functionally different involvement of anterior versus posterior parts of the hippocampus in these memory processes. In the present study, we examined encoding and retrieval processes via intrahippocampal recordings in 27 patients with unilateral temporal lobe epilepsy. Multicontact depth electrodes were implanted along the longitudinal axis of the hippocampus as part of the presurgical evaluation. In a continuous word recognition test, subjects had to indicate whether words were new or already presented. Recognized old words, as compared to new words, resulted in a larger P600 component, as well as in a larger late negative component (LNC, 600-900 msec). In addition, subsequently remembered words elicited a larger positivity (400 to 900 msec) than later forgotten words. We found differences concerning the distribution along the hippocampus for the LNC old-new effect, reflecting successful retrieval, as well as for the subsequent memory effect, reflecting successful encoding. Both effects were larger the further posterior an electrode was located in the hippocampus. Findings are suggestive for a predominant posterior hippocampal involvement in both verbal encoding and retrieval.

Human neocortical and hippocampal near-DC shifts are interconnected.

Hippocampal DC shifts have been observed under various physiological and pathological conditions. Here, we studied the interconnection of slow shifts (0.01 Hz high-pass) in surface EEG and hippocampal shifts as emerging in an event-related EEG biofeedback paradigm. Hippocampal EEG activity was monitored by depth electrodes implanted in four epilepsy patients for presurgical evaluation. Trials were sorted according to the near-DC shifts occurring at the surface position Cz, which was the feedback electrode, into positive, indistinct (i.e., small or biphasic) and negative shifts. We found significant hippocampal near-DC shifts being positively or negatively correlated to the shifts in surface EEG in all four patients. The amplitudes of the hippocampal near-DC shifts were several times larger than the surface shifts. The polarity of the shifts appears to depend on the location of the electrode contacts with respect to the hippocampal subfields. The finding that neocortical and hippocampal near-DC shifts are interconnected may open new perspectives for the prediction and control of mediotemporal lobe seizures.