COMPASS: Computations for Orientation and Motion Perception in Altered Sensorimotor States

Reliable perception of self-motion and orientation requires the central nervous system (CNS) to adapt to changing environments, stimuli, and sensory organ function. The proposed computations required of neural systems for this adaptation process remain conceptual, limiting our understanding and abil...

Full description

Saved in:
Bibliographic Details
Published in:Frontiers in neural circuits 2021-10, Vol.15, p.757817-757817
Main Authors: Kravets, Victoria G, Dixon, Jordan B, Ahmed, Nisar R, Clark, Torin K
Format: Article
Language:English
Subjects:
Adaptation
astronaut
Astronauts
Bayes rule
Bayes Theorem
Bayesian analysis
Central nervous system
cognitive modeling
Computer applications
Environmental effects
Gravitation
Gravity
Hypotheses
Information processing
Motion detection
Motion Perception
Motion sickness
Neural Circuits
Perception
Perceptions
Sensation
Sense organs
Sensorimotor system
sensory conflict
Space Flight
Space Perception
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Reliable perception of self-motion and orientation requires the central nervous system (CNS) to adapt to changing environments, stimuli, and sensory organ function. The proposed computations required of neural systems for this adaptation process remain conceptual, limiting our understanding and ability to quantitatively predict adaptation and mitigate any resulting impairment prior to completing adaptation. Here, we have implemented a computational model of the internal calculations involved in the orientation perception system's adaptation to changes in the magnitude of gravity. In summary, we propose that the CNS considers parallel, alternative hypotheses of the parameter of interest (in this case, the CNS's internal estimate of the magnitude of gravity) and uses the associated sensory conflict signals (i.e., difference between sensory measurements and the expectation of them) to sequentially update the posterior probability of each hypothesis using Bayes rule. Over time, an updated central estimate of the internal magnitude of gravity emerges from the posterior probability distribution, which is then used to process sensory information and produce perceptions of self-motion and orientation. We have implemented these hypotheses in a computational model and performed various simulations to demonstrate quantitative model predictions of adaptation of the orientation perception system to changes in the magnitude of gravity, similar to those experienced by astronauts during space exploration missions. These model predictions serve as quantitative hypotheses to inspire future experimental assessments.
ISSN:1662-5110
1662-5110
DOI:10.3389/fncir.2021.757817