AI Article Synopsis
- Proprioceptive signals play a crucial role in kinesthesia, but can be overshadowed by visual input in cases of visuo-proprioceptive conflict, as shown in three experiments using a 'mirror box' setup.
- In these experiments, participants' perception of arm movements was tested by manipulating proprioceptive feedback through vibration while their reflection in a mirror provided conflicting visual information.
- Results indicated that when visual signals dominate (as in the case of a reflected static arm), kinesthetic illusions are less prevalent, highlighting the complex interplay between visual and proprioceptive inputs in shaping our perception of movement.
Article Abstract
Proprioceptive signals are of prime importance in kinesthesia. However, in conditions of visuo-proprioceptive conflicts, strong visual-evoked biases can be observed. In three experiments, we parsed the interaction between visual and proprioceptive afferents using the 'mirror box' paradigm. Participants' left arm, the image of which was reflected in a mirror, was passively moved into flexion/extension or remained static. In Experiment 1 proprioceptive afferents of the unseen static right arm were masked with diffuse arm vibration. In Experiments 2 and 3, afferent signals were enhanced by muscle vibration of biceps or triceps stretch receptors. Illusory arm movements were evaluated with subjective reports and matching adjustments. Results revealed that participants did not experience kinesthetic illusions when the mirror reflected the image of a static arm while proprioceptive afferents conveyed signals of a moving arm (Experiment 2). In this specific case, vision apparently contributed much more strongly to the final percept than proprioceptive signals. However, in most circumstances, the percept reflected integration of both afferent signals (Experiments 1-3). For instance, when both sensory channels conveyed signals of arm displacement but in the opposite direction, kinesthetic illusions occurred but were either proprioceptively (vibration illusion) or visually driven (mirror illusion), according to individual sensorial preferences (Experiments 2 and 3). These results indicate that kinesthesia is the product of cooperative integration processes in which the final percept strongly depends on the experimental conditions as well as sensorial preferences. The observed changes in the relative contribution of each input across experimental conditions likely reflect reliability-dependent weights.
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