A computational study on off-center rotational dynamics of human semicircular canals with implications for real and virtual worlds

This study investigates human semicircular canal (SCC) dynamics under off-center rotational conditions. Previous research has modeled human rotational perception and the dynamic response of the SCCs by assuming a centered rotation state, where the rotation axis aligns with the SCC's center. How...

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Bibliographic Details
Published in:Heliyon 2024-12, Vol.10 (24), p.e41035, Article e41035
Main Authors: Cha, Sion, Kim, Wooksung
Format: Article
Language:English
Subjects:
Eccentric rotation
Finite element method
Fluid-structure interaction
Rotational perception
Sensory conflict
Spatial orientation
Vestibular system
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Summary:This study investigates human semicircular canal (SCC) dynamics under off-center rotational conditions. Previous research has modeled human rotational perception and the dynamic response of the SCCs by assuming a centered rotation state, where the rotation axis aligns with the SCC's center. However, this assumption is not representative of most real-life rotational situations. Understanding the effect of the offset distance between the rotation axis and the centers of the SCCs is essential, yet many studies still rely on bandpass filter models that do not account for this factor. Experimental studies are also limited, and mock-up models have difficulty accurately depicting these dynamics due to the cupula's low Young's modulus. Therefore, this study models endolymph and cupula within the SCCs using the finite element method (FEM) and a two-way fluid-structure interaction (FSI) approach. The results compare cupula displacement across different rotational conditions: step velocity motion (SVM), step acceleration motion (SAM), and sinusoidal motion. Notably, as the offset distance increases, the gain factor increases while the long time constant decreases. This finding highlights the limitations of existing centered rotation-based bandpass filter models. Based on these findings, we propose a modified transfer function that accounts for offset distance, offering a more generalizable model for human rotational perception and the dynamic responses of the SCCs. Additionally, this study provides foundational data to address sensory conflict, spatial disorientation, and various applications that require a precise dynamics model. •Quantitative analysis of cupula deformation under off-center rotation conditions.•Identification of differences in semicircular canal dynamic responses between off-center and centered rotations.•Development of a modified bandpass filter model considering offset distance.•Providing insights that contribute to understanding sensory conflicts in real and virtual environments.
ISSN:2405-8440
2405-8440
DOI:10.1016/j.heliyon.2024.e41035