Influence of Gravity on the Size-mass Illusion

Summary

Parabolic flight is the only ground-based condition in which free-fall (0G) can be created long enough for safely testing changes in human perception and behavior. In addition to the 0G period, parabolic flight generates equal duration periods of 1.8G, which present another unique opportunity to test the same responses to hypergravity and back to 1G.

It is well known that performance decrements occur in astronauts during and after gravity level transitions. Illusions are commonly felt in orbit as well disorientation and perceptual limitations, mainly due to both psycho-physiological changes and adaptation and lack of familiar points of reference in the space environment. Studies performed during previous space missions showed several changes occurring in different gravity conditions, pointing out, for example, that colors and shadows were misleading, the depth and distance perception were weakened, and the linear perspective was lost. Visual perception is of primary importance for spatial orientation and object recognition because the static vestibular (otolithic) and proprioceptive signals are absent when free-floating. Consequently, astronauts become increasingly dependent on vision to perceive motion and orientation. All these factors play an important role in the adaptation of humans to spaceflight that needs to be analyzed to understand the underlying mechanisms that regulate human psycho-physiological adaptive process to changing gravity. Human psycho-physiological health has to be safeguarded and possibly improved when long-term human space missions are programmed in the near future.

The primary objective of this experiment is to investigate if the SWI illusion is present in altered gravity environments. Since weight cannot be estimated in 0G, investigators have developed a procedure during which the subject is asked to estimate the objects' mass by shaking them rather than lifting them. Our results in 1G indicate that a size-mass illusion (SMI) is also present in 1G. Our hypothesis is that the previously observed alteration in 3D visual perception in 0G, particularly in the height of 3D objects, as well as the change in proprioceptive inputs, will be responsible for changes in the SMI in 0G and 1.8G compared to 1G. In a separate proposal, investigators will also propose to perform this experiment using the ESA short-arm human centrifuge (SAHC), with subjects exposed to various centrifugal force levels, to further investigate the role of proprioceptive cues in the size-mass illusion.

Conditions

• Healthy

Interventions

OTHER

parabolic flight

OTHER

mass/weight perception estimation

estimate the mass/weight perception, expressed by verbally report the absolute and relative mass of the object using a scale from 1 to 10 (1 being light and 10 being heavy)

DEVICE

ESA short-arm human centrifuge (SAHC)

Sponsors & Collaborators

• University Hospital, Caen

  lead OTHER

Study Design

Allocation

NA

Purpose

BASIC_SCIENCE

Masking

NONE

Model

SINGLE_GROUP

Eligibility

Min Age

21 Years

Max Age

65 Years

Sex

ALL

Healthy Volunteers

Yes

Timeline & Regulatory

Start

2013-10-31

Primary Completion

2016-10-31

Countries

• France

Study Locations