Development of a bio-inspired angular acceleration sensor : towards the non-invasive investigation of inner ear pathologies

The vestibular system contains semicircular canals that respond to angular acceleration and otoconial organs that respond to linear acceleration of the head. Information is sent to the motor system and, under normal circumstances, does not lead to conscious perception. Yet damage to the vestibular system can result in disequilibrium or vertigo, disturbing perceptions that dominate conscious experience. The shared residence of the cochlear and vestibular end organs in the inner ear can give rise to inner ear disorders such as Ménière’s disease. The effect of gravity on the otoconial masses in the sacculus and utriculus enable detection of static head tilt. Age-related disequilibrium, benign paroxysmal positional vertigo, motion sickness, and alcohol intoxication–induced vertigo are explained. How natural head movements elicit combined canal and otoconial organ responses is described. Finally, the dependence of posture and gaze on vestibular inputs is introduced as a segue to the next chapter.

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Introduction

10.1093/med/9780190600129.003.0001 ◽

2016 ◽

Author(s):

Robert W. Baloh

Keyword(s):

Inner Ear ◽

Angular Acceleration ◽

Organ Of Corti ◽

Semicircular Canals ◽

Linear Acceleration ◽

Positional Vertigo ◽

Linear Movement ◽

The Brain ◽

Simple Bedside ◽

Paroxysmal Positional Vertigo

The inner ear contains three major sensory receptors: the crista of the semicircular canals for sensing angular acceleration, the macule of the utricle and saccule for sensing linear acceleration, and the organ of Corti of the cochlea for sensing sound. Vertigo is an illusion of movement—usually spinning or turning but occasionally linear movement or tilt. Abnormalities of the inner ear or its connections in the brain cause an illusion of movement—vertigo. Benign paroxysmal positional vertigo (BPPV) is by far the most common cause of vertigo. Sudden violent spells of spinning are triggered by a change in position, such as turning over in bed, getting in and out of bed, and extending the head back to look up. This book tells the story of how the cause of BPPV was discovered and how a simple bedside cure was developed.

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Biaxial angular acceleration sensor using inertial force in the spiral channels and MEMS differential pressure sensors

The Proceedings of JSME annual Conference on Robotics and Mechatronics (Robomec) ◽

10.1299/jsmermd.2021.1a1-j02 ◽

2021 ◽

Vol 2021 (0) ◽

pp. 1A1-J02

Author(s):

Rihachiro NAKASHIMA ◽

Hidetoshi TAKAHASHI

Keyword(s):

Pressure Sensors ◽

Angular Acceleration ◽

Inertial Force ◽

Differential Pressure ◽

Acceleration Sensor

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A Novel Permanent Magnetic Angular Acceleration Sensor

Sensors ◽

10.3390/s150716136 ◽

2015 ◽

Vol 15 (7) ◽

pp. 16136-16152 ◽

Cited By ~ 7

Author(s):

Hao Zhao ◽

Hao Feng

Keyword(s):

Angular Acceleration ◽

Acceleration Sensor

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Using a smartphone acceleration sensor to study uniform and uniformly accelerated circular motions

Revista Brasileira de Ensino de Física ◽

10.1590/s1806-11172014000200015 ◽

2014 ◽

Vol 36 (2) ◽

Author(s):

Juan C. Castro-Palacio ◽

Luisberis Velazquez ◽

José A. Gómez-Tejedor ◽

Francisco J. Manjón ◽

Juan A. Monsoriu

Keyword(s):

Angular Velocity ◽

Physical Model ◽

Angular Acceleration ◽

Alternative Methods ◽

Acceleration Sensor ◽

Video Recordings ◽

Good Agreement

The acceleration sensor of a smartphone is used for the study of the uniform and uniformly accelerated circular motions in two experiments. Data collected from both experiments are used for obtaining the angular velocity and the angular acceleration, respectively. Results obtained with the acceleration sensor are in good agreement with alternative methods, like using video recordings of both experiments and a physical model of the second experiment.

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Proteomics and the Inner Ear

Disease Markers ◽

10.1155/2001/476738 ◽

2001 ◽

Vol 17 (4) ◽

pp. 259-270 ◽

Cited By ~ 14

Author(s):

Isolde Thalmann

Keyword(s):

Inner Ear ◽

Calcium Binding ◽

Angular Acceleration ◽

Organ Of Corti ◽

Semicircular Canals ◽

Frequency Discrimination ◽

Receptor System ◽

Perilymphatic Fistula ◽

Proteomics Approach

The inner ear, one of the most complex organs, contains within its bony shell three sensory systems, the evolutionary oldest gravity receptor system, the three semicircular canals for the detection of angular acceleration, and the auditory system - unrivaled in sensitivity and frequency discrimination. All three systems are susceptible to a host of afflictions affecting the quality of life for all of us. In the first part of this review we present an introduction to the milestones of inner ear research to pave the way for understanding the complexities of a proteomics approach to the ear. Minute sensory structures, surrounded by large fluid spaces and a hard bony shell, pose extreme challenges to the ear researcher. In spite of these obstacles, a powerful preparatory technique was developed, whereby precisely defined microscopic tissue elements can be isolated and analyzed, while maintaining the biochemical state representative of thein vivoconditions. The second part consists of a discussion of proteomics as a tool in the elucidation of basic and pathologic mechanisms, diagnosis of disease, as well as treatment. Examples are the organ of Corti proteins OCP1 and OCP2, oncomodulin, a highly specific calcium-binding protein, and several disease entities, Meniere's disease, benign paroxysmal positional vertigo, and perilymphatic fistula.

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IE-Map: A novel in-vivo atlas template of the human inner ear

10.1101/19011908 ◽

2019 ◽

Author(s):

Seyed-Ahmad Ahmadi ◽

Theresa Raiser ◽

Ria Maxine Rühl ◽

Virginia L. Flanagin ◽

Peter zu Eulenburg

Keyword(s):

Inner Ear ◽

Normal Subjects ◽

Intracranial Volume ◽

Imaging Data ◽

Magnetic Resonance Imaging Data ◽

Non Invasive ◽

Substructure Analysis ◽

Auditory Organ ◽

Human Inner Ear

AbstractBrain atlases and templates are core tools in scientific research with increasing importance also in clinical applications. Advances in neuroimaging now allowed us to expand the atlas domain to the vestibular and auditory organ, the inner ear. In this study, we present IE-Map, an in-vivo template and atlas of all known substructures of the human labyrinth derived from multi-modal high-resolution magnetic resonance imaging data in a non-invasive manner (no contrast agent or radiation). We reconstructed a common template from 126 inner ears (63 normal subjects) and annotated it with 94 established landmarks and semi-automatic segmentations. Quantitative substructure analysis revealed a correlation of labyrinth parameters with total intracranial volume. No effects of gender or laterality were found. We provide the validated templates, atlas segmentations, surface meshes and landmark annotations as open-access material, to provide neuroscience researchers and clinicians in neurology, neurosurgery, and otorhinolaryngology with a widely applicable tool for computational neurootology.

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