The role of fixation disengagement and oculomotor preparation in gap saccade task is gap-duration dependent.

Abstract

The influence of internal brain state on behavioral performance is well illustrated by the gap saccade task, in which saccades might be initiated with short latency (express saccade) or with long latency (regular saccade) even though the external visual condition is identical. Accumulated evidence has demonstrated that the internal brain state is different before the initiation of an express saccade than a regular saccade. However, the reported origin of the fluctuation of internal brain state is disputed among previous studies, e.g., the fixation disengagement theory versus the oculomotor preparation theory. The present study examined these two theories by analyzing the rate and direction of fixational saccades, i.e., small amplitude saccades during fixation, because they could be modulated by the internal brain state. Since fixation disengagement is not spatially tuned, it might affect the rate but not the direction of fixational saccades. In contrast, oculomotor preparation can contain spatial information for the upcoming saccade and thus affect fixational saccade direction. We found that the different spatiotemporal characteristics of fixational saccades among tasks with different gap durations reveal diverse driving force to change the internal brain state. Under short gap duration (100 ms), fixation disengagement plays a primary role in switching internal brain states. Conversely, oculomotor preparation plays a primary role under medium (200 ms) and long (400 ms) gap durations. These results suggest that both fixation disengagement and oculomotor preparation can change the internal brain state, but their relative contributions are gap-duration dependent.NEW & NOTEWORTHY While performing the gap saccade task, the role of fixation disengagement and oculomotor preparation in modulating the internal brain state is gap-duration dependent. Fixation disengagement plays a primary role when gap duration is shorter (100 ms), whereas oculomotor preparation plays a primary role when gap duration is longer (200 ms and 400 ms).