Do Gravity-Related Sensory Information Enable the Enhancement of Cortical Proprioceptive Inputs When Planning a Step in Microgravity?

Saradjian, Anahid H.; Paleressompoulle, Dany; Louber, Didier; Coyle, Thelma; Blouin, Jean; Mouchnino, Laurence

doi:10.1371/journal.pone.0108636

Cited by 15 publications

(7 citation statements)

References 66 publications

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“…The nature of these changes suggests that new relationships between proprioceptive sensory afferents and motor command are set up in weightless environments, which involves a high degree of sensorimotor adaptability[ 36 ] The second point concerns the finding that proprioceptive feedback contributes less efficiently to postural regulation during the early post-flight period, as demonstrated by the gradual increase in the amplitude of the vibration-induced postural responses recorded during the first week [ 36 ]. A large depression of the cortical response to vibration in weightlessness compared to normogravity was observed [ 37 ].…”

Section: Discussionmentioning

confidence: 99%

Dry immersion as a model of deafferentation: A neurophysiology study using somatosensory evoked potentials

Acket¹,

Amirova²,

Gerdelat³

et al. 2018

PLoS ONE

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IntroductionDry immersion is a ground-based experiment simulating the effects of weightlessness, and it is a model of acute symmetrical bilateral deafferentation. This exploratory study aimed to investigate the effects of three days of dry immersion (DI) on sensory thresholds and the functioning of lemniscal pathways, assessed by somatosensory evoked potentials (SEPs).MethodsTwelve healthy male volunteers (32+/-4.8 years) participated in the study. Sensory thresholds and SEPs of the tibial nerve of both limbs were recorded before (D-1) and on the third day of dry immersion (D3).ResultsSensory thresholds significantly decreased on D3 (-20.75 +/-21.7%; z = -2.54; p = 0.0109 on the right side and -22.18+/-17.28%; z = -3.059; p = 0.002 on the left side). The amplitude of P40 responses did not differ between D-1 and D3. Latencies of all central responses until P30 were shortened on D3 (N21 right:-0.57+/-0.31; z = -3.06; p = 0.002; N21 left -0.83+/-0.53; z = -2.94; p = 0.003; P30 right: -1.26+/-1.42; z = -3.059; p = 0.002; P30 left: -1.11+/-1.55; z = -2.27; p = 0.02)ConclusionThree days of dry immersion can induce hyperexcitability of lemniscal pathways.SignificanceThis may be explained by a change in the expression of membrane channels and/or medullar plasticity and/or hypersensitization of peripheral sensory receptors induced by this acute deafferentation. Additional studies are needed to further elucidate the mechanisms.

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Section: Discussionmentioning

confidence: 99%

Dry immersion as a model of deafferentation: A neurophysiology study using somatosensory evoked potentials

Acket¹,

Amirova²,

Gerdelat³

et al. 2018

PLoS ONE

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“…It is known that the cortical response to sensory stimulation decreases when another stimulation occurs shortly before (~300 ms, Morita et al. 1998 ; ~500 ms, Saradjian et al. 2014 ).…”

Section: Methodsmentioning

confidence: 99%

Large Postural Sways Prevent Foot Tactile Information From Fading: Neurophysiological Evidence

Fabre

Antoine

Robitaille

et al. 2020

Cerebral Cortex Communications

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Cutaneous foot receptors are important for balance control, and their activation during quiet standing depends on the speed and the amplitude of postural oscillations. We hypothesized that the transmission of cutaneous input to the cortex is reduced during prolonged small postural sways due to receptor adaptation during continued skin compression. Central mechanisms would trigger large sways to reactivate the receptors. We compared the amplitude of positive and negative post-stimulation peaks (P50N90) somatosensory cortical potentials evoked by the electrical stimulation of the foot sole during small and large sways in 16 young adults standing still with their eyes closed. We observed greater P50N90 amplitudes during large sways compared with small sways consistent with increased cutaneous transmission during large sways. Postural oscillations computed 200 ms before large sways had smaller amplitudes than those before small sways, providing sustained compression within a small foot sole area. Cortical source analyses revealed that during this interval, the activity of the somatosensory areas decreased, whereas the activity of cortical areas engaged in motor planning (supplementary motor area, dorsolateral prefrontal cortex) increased. We concluded that large sways during quiet standing represent self-generated functional behavior aiming at releasing skin compression to reactivate mechanoreceptors. Such balance motor commands create sensory reafference that help control postural sway.

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“…Amongst others, one of these solutions is to learn and store internal models to disambiguate sensory information and to predict forthcoming movement dynamics. On earth, a pervasive component affecting perception and motion is gravity (Bringoux et al, 2012; Dakin and Rosenberg, 2018; Elmore et al, 2014; Gaveau et al, 2011, 2016; Jorges and Lopez-Moliner, 2017; Klein et al, 2018; Lacquaniti et al, 2013; McIntyre et al, 2001; Van Pelt et al, 2005; Rosenberg and Angelaki, 2014; Saradjian et al, 2014; La Scaleia et al, 2019; Senot et al, 2005; Tajadura-Jimenez et al, 2018; De Vrijer et al, 2008). Studies in both humans and non-human primates have provided strong evidence that the brain evolved an internal representation of gravity.…”

Section: Introductionmentioning

confidence: 99%

A cross-species neural integration of gravity for motor optimisation

Gaveau

Grosprêtre

Angelaki

et al. 2019

Preprint

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15Recent kinematic results, combined with model simulations, have provided support for the 16 hypothesis that the human brain uses an internal model of gravity to shape motor patterns that 17 minimise muscle effort. Because many different muscular activation patterns can give rise to 18 the same trajectory, here we analyse muscular activation patterns during single-degree-of-19 freedom arm movements in various directions, which allow to specifically investigating 20 gravity-related movement properties. Using a well-known decomposition method of tonic and 21 phasic electromyographic activities, we demonstrate that phasic EMGs present systematic 22 negative phases. This negativity demonstrates that gravity effects are harvested to save 23 muscle effort and reveals that the brain implements an optimal motor plan using gravity to 24 accelerate downward and decelerate upward movements. Furthermore, for the first time, we 25 compare experimental findings in humans to monkeys, thereby generalising the Effort-26 optimization strategy across species. 27 the velocity and acceleration of the limb -and the gravity forces -related to the position of 51

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Do Gravity-Related Sensory Information Enable the Enhancement of Cortical Proprioceptive Inputs When Planning a Step in Microgravity?

Cited by 15 publications

References 66 publications

Dry immersion as a model of deafferentation: A neurophysiology study using somatosensory evoked potentials

Dry immersion as a model of deafferentation: A neurophysiology study using somatosensory evoked potentials

Large Postural Sways Prevent Foot Tactile Information From Fading: Neurophysiological Evidence

A cross-species neural integration of gravity for motor optimisation

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