A new quantitative evaluation system for distal radioulnar joint instability using a three-dimensional electromagnetic sensor

Mukohara, Shintaro; Mifune, Yutaka; Inui, Atsuyuki; Nishimoto, Hanako; Kitaoka, Takashi; Yamaura, Kohei; Yoshikawa, Tomoya; Shinohara, Issei; Hoshino, Yuichi; Nagamune, Kouki; Kuroda, Ryosuke

doi:10.1186/s13018-021-02601-4

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…However, UG measurements cannot evaluate joint angles during movement. Alternative methods, such as 3-dimensional gyroscopes [6,7], marker motion capture systems [8][9][10], inertial sensors and magnetic sensors [11][12][13][14], are limited by high costs, poor accessibility, requirement for skilled operators, and environmental constraints. Challenges in acquiring valid and repeatable data in human subjects can arise due to the relative motion and location of the skin, where markers are placed, with respect to the actual skeletal movement and location, as highlighted in previous research studies [15].…”

Section: Introductionmentioning

confidence: 99%

Measurement of Shoulder Abduction Angle with Posture Estimation Artificial Intelligence Model

Kusunose

Inui

Nishimoto

et al. 2023

Sensors

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Substantial advancements in markerless motion capture accuracy exist, but discrepancies persist when measuring joint angles compared to those taken with a goniometer. This study integrates machine learning techniques with markerless motion capture, with an aim to enhance this accuracy. Two artificial intelligence-based libraries—MediaPipe and LightGBM—were employed in executing markerless motion capture and shoulder abduction angle estimation. The motion of ten healthy volunteers was captured using smartphone cameras with right shoulder abduction angles ranging from 10° to 160°. The cameras were set diagonally at 45°, 30°, 15°, 0°, −15°, or −30° relative to the participant situated at a distance of 3 m. To estimate the abduction angle, machine learning models were developed considering the angle data from the goniometer as the ground truth. The model performance was evaluated using the coefficient of determination R2 and mean absolute percentage error, which were 0.988 and 1.539%, respectively, for the trained model. This approach could estimate the shoulder abduction angle, even if the camera was positioned diagonally with respect to the object. Thus, the proposed models can be utilized for the real-time estimation of shoulder motion during rehabilitation or sports motion.

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Section: Introductionmentioning

confidence: 99%

Measurement of Shoulder Abduction Angle with Posture Estimation Artificial Intelligence Model

Kusunose

Inui

Nishimoto

et al. 2023

Sensors

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“…Electromagnetic vibration sensors can directly convert mechanical vibration into current due to the Lenz effect, allowing a battery-less and self-sustainable operation to monitor the vibration of mechanical structures − and machines , as well as motions of the body − and joints. , Their core components are magnetically coupled to allow contactless operation and avoid mechanical abrasion, resulting in prolonged life spans and high durability that are preferable in harsh environments. Various electromagnetic vibration sensors have been developed with essential vibration elements physically connected with elastic springs, − diaphragms , and cantilevers − or levitated by a magnetic field. − Different from spring and diaphragm-based sensors whose resonance frequencies can be specifically designed based on the properties of the spring and the cantilever, the levitation-based sensor requires no additional elastic elements and no structure deformation.…”

Section: Introductionmentioning

confidence: 99%

Magnetically Levitated Flexible Vibration Sensors with Surficial Micropyramid Arrays for Magnetism Enhancement

Zhang

Zheng²,

et al. 2022

ACS Appl. Mater. Interfaces

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Magnetically levitated vibration sensors possess wide frequency response ranges and high sensitivity. Compared with springs and cantilevers, the levitated magnet suffers no mechanical abrasion, allowing minimized mechanical fatigue after prolonged exposure to vibration. However, magnetic levitated sensors are mostly based on fully rigid components, which are difficult to match the soft and curvilinear surface of the biological tissues and machines. Here, an innovative vibration sensor based on magnetic levitation has been developed. The proposed sensor contains two parallel magnetic membranes, one of which is levitated by magnetic force and connected to a specially designed sensor package. The surfaces of the membranes are modified with micropyramid arrays to enhance the magnetism and integrated with flexible coil arrays to maximize the changes in magnetic flux during vibration. The sensor exhibits a wide frequency response ranging from 1 Hz to 20 kHz and high sensitivity of 0.82 mV/μm at an operating frequency of 120 Hz. Various applications have been demonstrated through bone-conducted speech acquisition, sound recording, human motion detection, and machine condition evaluation. The sensor is one of the first flexible vibration sensors based on magnetic levitation. Its innovative levitated sensing structures may inspire development of novel flexible sensors with soft mechanical moving structures for force and displacement sensing in healthcare and industrial monitoring.

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Reliability and Validity Analysis of the Distal Radioulnar Joint Ballottement Test

Nagashima,

Omokawa,

Hasegawa

et al. 2024

The Journal of Hand Surgery

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A new quantitative evaluation system for distal radioulnar joint instability using a three-dimensional electromagnetic sensor

Cited by 3 publications

References 33 publications

Measurement of Shoulder Abduction Angle with Posture Estimation Artificial Intelligence Model

Measurement of Shoulder Abduction Angle with Posture Estimation Artificial Intelligence Model

Magnetically Levitated Flexible Vibration Sensors with Surficial Micropyramid Arrays for Magnetism Enhancement

Reliability and Validity Analysis of the Distal Radioulnar Joint Ballottement Test

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