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Abstract
Going into space is a disorienting experience. Many studies have looked at sensory functioning in space but the multisensory basis of orientation has not been systematically investigated. Here, we assess how prolonged exposure to microgravity affects the relative weighting of visual, gravity, and idiotropic cues to perceived orientation. We separated visual, body, and gravity (when present) cues to perceived orientation before, during, and after long-term exposure to microgravity during the missions of seven astronauts on the International Space Station (mean duration 168 days) and measuring perceived vertical using the subjective visual vertical and the perceptual upright. The relative influence of each cue and the variance of their judgments were measured. Fourteen ground-based control participants performed comparable measurements over a similar period. The variance of astronauts’ subjective visual vertical judgments in the absence of visual cues was significantly larger immediately upon return to earth than before flight. Astronauts’ perceptual upright demonstrated a reduced reliance on visual cues upon arrival on orbit that re-appeared long after returning to earth. For earth-bound controls, the contributions of body, gravity, and vision remained constant throughout the year-long testing period. This is the first multisensory study of orientation behavior in space and the first demonstration of long-term perceptual changes that persist after returning to earth. Astronauts showed a plasticity in the weighting of perceptual cues to orientation that could form the basis for future countermeasures.
Highlights
Humans have evolved in the gravitational field of the earth that provides a constant direction to which spatial perceptions and movements can be referenced
63 to 75%) and a corresponding decrease in visual weighting across BDC sessions. 100% of astronauts showed a reduction in the ratio of the vision to body weightings (v:b) for the perceptual upright (PU) measurements from BDC1 to FLTE and from BDC1 to BDC3 (Fig. 4c)
The ratios calculated from the weights in this manner are npj Microgravity (2017) 3. For both ground-based and astronaut participants, the SVV and PU responses remained consistent across data collection sessions even though astronaut observers were subjected to microgravity for an average of 168 days (Figs 1 and 2)
Summary
Humans have evolved in the gravitational field of the earth that provides a constant direction to which spatial perceptions and movements can be referenced. Body and vision cues all contribute to the estimation of vertical and are weighted in proportion to their reliability.[3] The relative weighting varies between participants and between tasks, presumably reflecting individual factors such as the stability of the eyes, the reliability of the internal representation of the body, and the efficiency of the vestibulo-somatosensory system. How is this multisensory system affected when gravity is removed? How is this multisensory system affected when gravity is removed? Do visual cues remain as effective in determining the perception of “up” during and after long-term exposure to microgravity?
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