Watching the Effects of Gravity. Vestibular Cortex and the Neural Representation of “Visual” Gravity

Monache, Sergio Delle; Indovina, Iole; Zago, Myrka; Daprati, Elena; Lacquaniti, Francesco; Bosco, Gianfranco

doi:10.3389/fnint.2021.793634

Cited by 17 publications

(14 citation statements)

References 174 publications

(268 reference statements)

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“…In addition, the degree of congruency between the visual motion and the motor response can influence rhythm synchronization, as tapping movements aligned with the direction of the visual motion accomplish better synchronization than when the tapping and visual motion direction are incongruent (Hove et al, 2010). These findings are in line with the notion that gravitational cues can facilitate some perceptual functions, like interpreting the causality and the naturalness of object motion or discriminating pendular motion (Pittenger, 1990; Kim and Spelke, 1992; Bingham et al, 1995; Twardy and Bingham, 2002), and can lead to an advantage in manual interceptions, by engaging an internal representation of gravity in the vestibular cortex (Indovina et al, 2005; Lacquaniti et al, 2013; Delle Monache et al, 2021). Interestingly, this internal representation of gravity can be engaged even by the mere object kinematics displayed on a computer screen, especially over a pictorial background providing scaling cues to real world metrics (Moscatelli and Lacquaniti, 2011; La Scaleia et al, 2015; Delle Monache et al, 2017, 2019; Ceccarelli et al, 2018).…”

Section: Introductionsupporting

confidence: 81%

“…The present study was designed to test whether physically realistic motion trajectories with downward-acceleration or upward-deceleration profiles induced better rhythm entraining in the SCT than the non-naturalistic upward-acceleration/downward-deceleration or accelerating/decelerating horizontal motion metronomes. In effect, a natural gravity gain on rhythmic timing might be expected based on the evidence that diving gannets use gravitational signals to compute the time-to-contact and fold their wings before entering the water (Lee and Reddish, 1981), and that humans can use an internal representation of gravity effects residing in the vestibular cortex to time accurately the interception of vertically falling objects (Lacquaniti and Maioli, 1989; Indovina et al, 2005; Lacquaniti et al, 2015; Delle Monache et al, 2021). However, our findings were not congruent with this expectation, since the timing accuracy, precision, and the correlation of consecutively produced intervals were not different between the natural and non-natural gravity vertical motion nor with horizontal motion.…”

Section: Discussionmentioning

confidence: 99%

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Rhythmic tapping to a moving beat: motion kinematics overrules motion naturalness

Pérez

Monache

Lacquaniti

et al. 2023

Preprint

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Beat induction is the cognitive ability that allow humans to listen to a regular pulse in music and move in synchrony with it. Although auditory rhythmic cues are known to induce more consistent synchronization than flashing visual metronomes, this asymmetry can be canceled out by visual moving metronomes. Here, we investigated whether the naturalness of the visual motion or its kinematics could provide a synchronization advantage over flashing metronomes. Subjects tap in sync with visual isochronous metronomes defined by vertically or horizontally accelerating and decelerating motion, either congruent or not with natural gravity, and then continue tapping with no metronome. We found that motion kinematics was the predominant factor determining rhythm synchronization, as accelerating moving metronomes in either cardinal direction produced more precise and predictive tapping than decelerating or flashing conditions. Notably, a Bayesian observer model revealed that error correction during tapping synchronization and regression towards the mean in accuracy during tapping continuation in the absence of external cues are optimal control strategies independently of the moving properties of the visual metronomes. Our results support the notion that accelerating visual metronomes convey a strong sense of beat as seen in the cueing movements of an orchestra director.

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Section: Introductionsupporting

confidence: 81%

Section: Discussionmentioning

confidence: 99%

Rhythmic tapping to a moving beat: motion kinematics overrules motion naturalness

Pérez

Monache

Lacquaniti

et al. 2023

Preprint

Self Cite

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“…This Group 3 part of the PCC may also provide a route for vestibular and optic flow information useful in navigation to reach hippocampal whole body motion neurons, for it receives inputs from VIP and V6A in which optic flow is represented (Delle Monache et al, 2021 ; Duhamel et al, 1997 ; Sherrill et al, 2015 ).…”

Section: Discussionmentioning

confidence: 99%

The human posterior cingulate, retrosplenial, and medial parietal cortex effective connectome, and implications for memory and navigation

Rolls

Wirth

Deco

et al. 2022

Human Brain Mapping

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The human posterior cingulate, retrosplenial, and medial parietal cortex are involved in memory and navigation. The functional anatomy underlying these cognitive functions was investigated by measuring the effective connectivity of these Posterior Cingulate Division (PCD) regions in the Human Connectome Project-MMP1 atlas in 171 HCP participants, and complemented with functional connectivity and diffusion tractography. First, the postero-ventral parts of the PCD (31pd, 31pv, 7m, d23ab, and v23ab) have effective connectivity with the temporal pole, inferior temporal visual cortex, cortex in the superior temporal sulcus implicated in auditory and semantic processing, with the reward-related vmPFC and pregenual anterior cingulate cortex, with the inferior parietal cortex, and with the hippocampal system. This connectivity implicates it in hippocampal episodic memory, providing routes for "what," reward and semantic schema-related information to access the hippocampus. Second, the antero-dorsal parts of the PCD (especially 31a and 23d, PCV, and also RSC) have connectivity with early visual cortical areas including those that represent spatial scenes, with the superior parietal cortex, with the pregenual anterior cingulate cortex, and with the hippocampal system. This connectivity implicates it in the "where" component for hippocampal episodic memory and for spatial navigation. The dorsal-

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“…The fact that the cerebellar contribution to the P300 was mainly observed when the docking task was performed on Earth and not when the same task was realized in weightlessness might be explained by the major contribution of the cerebellum to the body control during the free-floating posture adopted by the astronaut during the realization of the docking task (Cebolla et al 5 ). On Earth, the cerebellum integrates the semicircular and otolith signals, providing a neural representation of the head orientation relative to gravity 38 – 40 . Because the decision to dock necessitates perceptual stability, the dynamic prediction of the sensory consequences of gravity realized by the internal model of the cerebellum is crucial.…”

Section: Discussionmentioning

confidence: 99%

Brain potential responses involved in decision-making in weightlessness

Cebolla

Petieau

Palmero‐Soler

et al. 2022

Sci Rep

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The brain is essential to human adaptation to any environment including space. We examined astronauts’ brain function through their electrical EEG brain potential responses related to their decision of executing a docking task in the same virtual scenario in Weightlessness and on Earth before and after the space stay of 6 months duration. Astronauts exhibited a P300 component in which amplitude decreased during, and recovered after, their microgravity stay. This effect is discussed as a post-value-based decision-making closing mechanism; The P300 amplitude decrease in weightlessness is suggested as an emotional stimuli valence reweighting during which orbitofrontal BA10 would play a major role. Additionally, when differentiating the bad and the good docks on Earth and in Weightlessness and keeping in mind that astronauts were instantaneously informed through a visual cue of their good or bad performance, it was observed that the good dockings resulted in earlier voltage redistribution over the scalp (in the 150–250 ms period after the docking) than the bad dockings (in the 250–400 ms) in Weightlessness. These results suggest that in Weightlessness the knowledge of positive or negative valence events is processed differently than on Earth.

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Watching the Effects of Gravity. Vestibular Cortex and the Neural Representation of “Visual” Gravity

Cited by 17 publications

References 174 publications

Rhythmic tapping to a moving beat: motion kinematics overrules motion naturalness

Rhythmic tapping to a moving beat: motion kinematics overrules motion naturalness

The human posterior cingulate, retrosplenial, and medial parietal cortex effective connectome, and implications for memory and navigation

Brain potential responses involved in decision-making in weightlessness

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