Frontiers in Physiology (Jul 2019)

Alterations of Functional Brain Connectivity After Long-Duration Spaceflight as Revealed by fMRI

  • Ekaterina Pechenkova,
  • Inna Nosikova,
  • Alena Rumshiskaya,
  • Liudmila Litvinova,
  • Ilya Rukavishnikov,
  • Elena Mershina,
  • Valentin Sinitsyn,
  • Angelique Van Ombergen,
  • Ben Jeurissen,
  • Steven Jillings,
  • Steven Jillings,
  • Steven Laureys,
  • Jan Sijbers,
  • Alexey Grishin,
  • Ludmila Chernikova,
  • Ivan Naumov,
  • Ludmila Kornilova,
  • Floris L. Wuyts,
  • Elena Tomilovskaya,
  • Inessa Kozlovskaya

DOI
https://doi.org/10.3389/fphys.2019.00761
Journal volume & issue
Vol. 10

Abstract

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The present study reports alterations of task-based functional brain connectivity in a group of 11 cosmonauts after a long-duration spaceflight, compared to a healthy control group not involved in the space program. To elicit the postural and locomotor sensorimotor mechanisms that are usually most significantly impaired when space travelers return to Earth, a plantar stimulation paradigm was used in a block design fMRI study. The motor control system activated by the plantar stimulation involved the pre-central and post-central gyri, SMA, SII/operculum, and, to a lesser degree, the insular cortex and cerebellum. While no post-flight alterations were observed in terms of activation, the network-based statistics approach revealed task-specific functional connectivity modifications within a broader set of regions involving the activation sites along with other parts of the sensorimotor neural network and the visual, proprioceptive, and vestibular systems. The most notable findings included a post-flight increase in the stimulation-specific connectivity of the right posterior supramarginal gyrus with the rest of the brain; a strengthening of connections between the left and right insulae; decreased connectivity of the vestibular nuclei, right inferior parietal cortex (BA40) and cerebellum with areas associated with motor, visual, vestibular, and proprioception functions; and decreased coupling of the cerebellum with the visual cortex and the right inferior parietal cortex. The severity of space motion sickness symptoms was found to correlate with a post- to pre-flight difference in connectivity between the right supramarginal gyrus and the left anterior insula. Due to the complex nature and rapid dynamics of adaptation to gravity alterations, the post-flight findings might be attributed to both the long-term microgravity exposure and to the readaptation to Earth’s gravity that took place between the landing and post-flight MRI session. Nevertheless, the results have implications for the multisensory reweighting and gravitational motor system theories, generating hypotheses to be tested in future research.

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