Abstract
Across a wide variety of research environments, the recording of microsaccades and other fixational eye movements has provided insight and solutions into practical problems. Here we review the literature on fixational eye movements—especially microsaccades—in applied and ecologically-valid scenarios. Recent technical advances allow noninvasive fixational eye movement recordings in real-world contexts, while observers perform a variety of tasks. Thus, fixational eye movement measures have been obtained in a host of real-world scenarios, such as in connection with driver fatigue, vestibular sensory deprivation in astronauts, and elite athletic training, among others. Here we present the state of the art in the practical applications of fixational eye movement research, examine its potential future uses, and discuss the benefits of including microsaccade measures in existing eye movement detection technologies. Current evidence supports the inclusion of fixational eye movement measures in real-world contexts, as part of the development of new or improved oculomotor assessment tools. The real-world applications of fixational eye movement measurements will only grow larger and wider as affordable high-speed and high-spatial resolution eye trackers become increasingly prevalent.
Highlights
Most studies of fixational eye movements— FEMs, the small movements we make while we attempt to fixate our gaze on a target—have been conducted in laboratory settings
Due to the difficulty of measuring tremor, even inside the lab, and the resulting scarcity of studies including tremor measurements, this review focuses primarily on microsaccades, and secondarily on drift
An early study by Winterson and Collewijn (1976), aimed at determining whether microsaccades might be useful in any real-world tasks, measured the eye movements of participants while they aimed and fired an air rifle, or threaded a sewing needle
Summary
Most studies of fixational eye movements— FEMs, the small movements we make while we attempt to fixate our gaze on a target—have been conducted in laboratory settings. The studies above indicate that prolonged exposure to low gravity conditions causes gaze instability, with measurable alterations in drift, nystagmus, SWJs, (micro)saccades, and smooth pursuit movements, both during free viewing and in tasks that require the controlled allocation of gaze. An early study by Winterson and Collewijn (1976), aimed at determining whether microsaccades might be useful in any real-world tasks, measured the eye movements of participants while they aimed and fired an air rifle, or threaded a sewing needle. It is unclear if such speeded latencies might extend to microsaccadic eye movements produced during aiming This same study assessed the fixational stability of expert and novice shooters, in terms of their gaze deviation from the fixation point. Neuroimaging studies have started to use high-resolution eye tracking to remove trials with microsaccades from analysis (Plöchl, Ossandón, & König, 2012)
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