Involuntary, fixational eye movements play a bigger role in vision than researchers previously thought.
Our eyes are never at rest. Instead, they remain in motion, even between our voluntary gaze shifts, through fixational eye movements鈥攕mall, continuous movements of the eye that we are not aware of making.
Scientists have long sought to understand how we humans can perceive the world as stable as our eyes are constantly moving. Past research has suggested that, in the intervals between voluntary gaze shifts, the human visual system builds a picture of a stable world by relying solely on sensory inputs from fixational eye movements. According to new research by a team at the , however, there may be another contributing factor.
In a published in Nature Communications, the researchers鈥攊ncluding , a professor in the 聽and at the University鈥檚 , and first author Zhetuo Zhao, a PhD student in Rucci鈥檚 lab鈥攔eport that the visual system not only receives sensory inputs from fixational eye movements but also possesses knowledge of the motor behavior involved in those movements.
鈥淭he human brain has a very precise knowledge of how the eyes move, even if humans are not aware of moving them, and they use this knowledge to infer spatial relations and perceive the world not as blurry but as stable,鈥 Rucci says.
The results of the research reveal that spatial representations鈥攖hat is, the locations of objects in relation to other objects鈥攁re based on a combination of sensory and motor activity from both voluntary and involuntary eye movements, which is contrary to the prevailing understanding, Rucci explains.
鈥淚t was already clear that the visual system uses sensory and motor knowledge from large voluntary movements, either gaze shifts we perform to look at different parts of a scene, or tracking movements for following moving objects,鈥 he says. 鈥淏ut scientists didn鈥檛 think smaller, involuntary movements like fixational eye movements could be used to convey information through motor signals.鈥
Instead, the research shows the visual system continually monitors motor activity, even when people believe they are maintaining a steady gaze. The research also shows that vision has computational strategies similar to other senses, such as touch and smell, where motor behavior profoundly affects incoming sensory signals.
The results have important implications in future studies of visual perception and will help in better understanding visual impairments that involve abnormal eye movements.
鈥淥ur study unveils that involuntary eye movements, which are widely discarded as motor noise, make major contributions to spatial representations of the world,鈥 Zhao says. 鈥淎s we show, studying spatial representations without considering motor activity鈥攁s is often done in current neuroscience鈥攊s severely limiting.鈥
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