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contributor authorBian, Yixiang
contributor authorLiu, Wujie
contributor authorDai, Junjie
contributor authorWen, Xianhua
contributor authorJiang, Yani
date accessioned2025-04-21T10:16:16Z
date available2025-04-21T10:16:16Z
date copyright10/11/2024 12:00:00 AM
date issued2024
identifier issn0148-0731
identifier otherbio_147_01_011001.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4305841
description abstractAcademia often uses the “circular geometry hypothesis” to explain the sensing principle of the human semicircular canal (SCC) system for angular acceleration, which is widely accepted as an important angular acceleration sensor in the human balance system. On the basis of this hypothesis and the anatomical structure of human SCCs, a series of physical SCC models with different geometries at 4× magnification were prepared via three-dimensional printing and modification of hydrogels. Theoretical models of the SCC perception mechanism were established. Then, impulse angular acceleration, sinusoidal rotation, and sinusoidal linear stimulation were applied to the models, and their responses were visually observed and analyzed in detail. As a result, the circular SCC model had a larger system gain and a smaller phase difference for angular acceleration stimulation but a smaller system gain and a larger phase difference for linear acceleration stimulation. These results verified that the circular semicircular canal was more sensitive to angular acceleration. Our bionic model is hoped to be used for demonstrating the human SCC working process, facilitating researchers in better understanding of the working mechanism of the human SCC, or as a manual model for medical staff to simulate the diagnosis and treatment of human SCC.
publisherThe American Society of Mechanical Engineers (ASME)
titleStudy of the Mechanism of Perceived Rotational Acceleration of a Bionic Semicircular Canal on the Basis of the “Circular Geometry Hypothesis”
typeJournal Paper
journal volume147
journal issue1
journal titleJournal of Biomechanical Engineering
identifier doi10.1115/1.4066526
journal fristpage11001-1
journal lastpage11001-9
page9
treeJournal of Biomechanical Engineering:;2024:;volume( 147 ):;issue: 001
contenttypeFulltext


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