Abstract
Astronauts experience post-flight disturbances in postural and locomotor control due to sensorimotor adaptations during spaceflight. These alterations may have adverse consequences if a rapid egress is required after landing. Although current exercise protocols can effectively mitigate cardiovascular and muscular deconditioning, the benefits to post-flight sensorimotor dysfunction are limited. Furthermore, some exercise capabilities like treadmill running are currently not feasible on exploration spaceflight vehicles. Thus, new in-flight operational countermeasures are needed to mitigate postural and locomotor control deficits after exploration missions. Data from spaceflight and from analog studies collectively suggest that body unloading decreases the utilization of proprioceptive input, and this adaptation strongly contributes to balance dysfunction after spaceflight. For example, on return to Earth, an astronaut’s vestibular input may be compromised by adaptation to microgravity, but their proprioceptive input is compromised by body unloading. Since proprioceptive and tactile input are important for maintaining postural control, keeping these systems tuned to respond to upright balance challenges during flight may improve functional task performance after flight through dynamic reweighting of sensory input. Novel approaches are needed to compensate for the challenges of balance training in microgravity and must be tested in a body unloading environment such as head down bed rest. Here, we review insights from the literature and provide observations from our laboratory that could inform the development of an in-flight proprioceptive countermeasure.
Highlights
Crew health and safety are NASA’s top priorities for future exploration missions to the Moon and Mars (Charles and Pietrzyk, 2019)
Exercise is an effective countermeasure to mitigate muscular and cardiovascular deconditioning during spaceflight, functional performance decrements on tasks requiring dynamic control of postural stability remain ubiquitous among crewmembers returning to Earth after 6 months missions on board the International Space Station (ISS) (Reschke et al, 2015, 2019)
Earlier we described how greater resistance training loads provided by the Advanced Resistive Exercise Device (ARED) attenuates post-flight decrements in agility and postural stability compared to its predecessor (Wood et al, 2011)
Summary
Crew health and safety are NASA’s top priorities for future exploration missions to the Moon and Mars (Charles and Pietrzyk, 2019). Exercise is an effective countermeasure to mitigate muscular and cardiovascular deconditioning during spaceflight, functional performance decrements on tasks requiring dynamic control of postural stability remain ubiquitous among crewmembers returning to Earth after 6 months missions on board the International Space Station (ISS) (Reschke et al, 2015, 2019). These impairments will presumably be exacerbated after exploration-class missions to Mars, which, based on current propulsion technology, will last about 30 months. New countermeasures must be developed to physically prepare crewmembers for transitions from microgravity to Mars gravity and from microgravity back to Earth gravity after these very long-duration spaceflights
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