Trajectories of shifting dipole sources of visual evoked potentials across the human brain.

Visual evoked potentials in response to images of a set of horizontal and vertical lines or crosses were recorded from the brains of 18 human subjects in 34 leads. Inverse EEG analyses were used for the dynamic location of the dipole current sources of the N1, P1, and N2 waves using a two-dipole spherical model with a 1-msec step. The occipital lobes of all subjects showed significant displacement of the dipoles of evoked potential waves along predominantly arc-shaped trajectories (75.8% of cases). Trajectory durations (average about 25 msec) were characterized by insignificant interindividual variability and were independent of the type of stimulus and the phase of the evoked potential. A characteristic (occurring in 85% of cases) "jump" in the coordinates of the dipole, which constituted a rapid, sharp, and significant medial displacement, was seen between the first and second trajectories of the equivalent current dipoles (at 110-120 msec after stimulus onset). The possible significance of these data for understanding the dynamics and kinetics of processing of local image features in the human visual cortex is discussed.

[Trajectories of shifting of dipole sources of visual evoked potentials over the human brain].

Dynamic study of 3D localization of the equivalent current dipole (ECD) sources of visual evoked potentials (EP) in the human brain was performed in 18 healthy subjects using a two-dipole model. Dipole tracing was performed for relatively early EP components (N1, P1, and N2) with 1-ms step. The analysis confirmed localization of these ECDs mainly in the right occipital cortex and revealed their successive shift over this area in the anterior-medial direction and then backwards in all subjects during generation of the EP components. Typically, some successive arch-like trajectories of the shift were revealed (75.8%); their duration was relatively standard (about 25 ms) and did not depend on the stimulus shape and EP phase. Between the 1st and the 2nd trajectories (110-120 ms after the stimulus onset) a jump in ECD coordinates in the medial direction was found in 85% of cases. Possible significance of the findings for the insight into dynamic topography of the visual feature processing in the human brain is discussed.