Biomechanical Analysis of Body Movements of Myoelectric Prosthesis Users During Standardized Clinical Tests

Vujaklija, Ivan; Jung, Moonki; Hasenoehrl, Timothy; Roche, Aidan D.; Sturma, Agnes; Muceli, Silvia; Crevenna, Richard; Farina, Dario

doi:10.1109/tbme.2022.3202250

Cited by 3 publications

(1 citation statement)

References 45 publications

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“…Furthermore, nanoscale actuators and shape memory alloys enable prosthetic devices to adjust their configuration based on the user's activities, promoting seamless transitions between different modes of operation. As a result, electric and myoelectric prosthetic limbs with embedded nanomaterials have unlocked a new realm of functionality and adaptability, empowering users with enhanced control and responsiveness that mimic the intricacies of natural limb movement (Chuang et al, 2012;Nowak et al, 2023;Touillet et al, 2023;Vujaklija et al, 2023).…”

Section: Nanomaterials In Electric and Myoelectric Prosthetic Limbsmentioning

confidence: 99%

Nanotechnology and Prosthetic Devices: Integrating Biomedicine and Materials Science for Enhanced Performance and Adaptability

Karim,

Siddiqui,

Assaifan

et al. 2024

Journal of Disability Research

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Nanomaterials are revolutionizing prosthetic device development. Nanotechnology has made prosthetic devices that replicate natural limb behavior and respond to users’ intentions possible. Nanomaterials improve prosthetic functionality, comfort, and lifespan. Nanocomposites, smart sensors, and medication delivery systems have addressed mechanical strength, control, and biocompatibility, resulting in enhanced prosthetic devices that improve user freedom, mobility, and quality of life. Biomedicine and materials science have helped nanomaterials reach their full potential, enabling their seamless integration into prosthetic devices and fostering interdisciplinary collaborations that advance prosthetics. The literature study shows substantial advances in nanomaterials for prosthetic devices; however, various gaps in present research and possible future research areas are indicated. First, long-term biocompatibility studies are needed to understand nanomaterials’ long-term effects on humans. Nanomaterial-based prosthetic devices must be tested and researched to assure safety and efficacy in real-world situations. Second, nanocomposites and nanoscale components must be standardized and quality-controlled to enable consistency and scalability in prosthetic devices. Third, nanoscale sensor and neural interface ethics must address privacy, security, and user consent issues. The nanomaterial-based prosthetic devices must be made more inexpensive and accessible to more disabled people. The study design was carried out to incorporate significant literature on the application of nanotechnology related to prosthetic devices. The literature was filtered from the Scopus database. The selected literature belongs to the original articles in which experimental work was carried out. Future research could combine nanotechnology with other developing technologies like artificial intelligence and robotics to produce more advanced and adaptable prosthetic devices.

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Section: Nanomaterials In Electric and Myoelectric Prosthetic Limbsmentioning

confidence: 99%

Nanotechnology and Prosthetic Devices: Integrating Biomedicine and Materials Science for Enhanced Performance and Adaptability

Karim,

Siddiqui,

Assaifan

et al. 2024

Journal of Disability Research

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Shoulder Kinematics Predicts Lateral Asymmetries in Functional Tests of Hand Dexterity

De Villa,

Molinari,

Carrillo

et al. 2024

Biosystems &Amp; Biorobotics

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Perspectives on the comparative benefits of body-powered and myoelectric upper limb prostheses

Engdahl,

Gonzalez,

Lee

et al. 2024

J NeuroEngineering Rehabil

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Background Patient access to body-powered and myoelectric upper limb prostheses in the United States is often restricted by a healthcare system that prioritizes prosthesis prescription based on cost and perceived value. Although this system operates on an underlying assumption that design differences between these prostheses leads to relative advantages and disadvantages of each device, there is limited empirical evidence to support this view. Main text This commentary article will review a series of studies conducted by our research team with the goal of differentiating how prosthesis design might impact user performance on a variety of interrelated domains. Our central hypothesis is that the design and actuation method of body-powered and myoelectric prostheses might affect users’ ability to access sensory feedback and account for device properties when planning movements. Accordingly, other domains that depend on these abilities may also be affected. While our work demonstrated some differences in availability of sensory feedback based on prosthesis design, this did not result in consistent differences in prosthesis embodiment, movement accuracy, movement quality, and overall kinematic patterns. Conclusion Collectively, our findings suggest that performance may not necessarily depend on prosthesis design, allowing users to be successful with either device type depending on the circumstances. Prescription practices should rely more on individual needs and preferences than cost or prosthesis design. However, we acknowledge that there remains a dearth of evidence to inform decision-making and that an expanded research focus in this area will be beneficial.

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Biomechanical Analysis of Body Movements of Myoelectric Prosthesis Users During Standardized Clinical Tests

Cited by 3 publications

References 45 publications

Nanotechnology and Prosthetic Devices: Integrating Biomedicine and Materials Science for Enhanced Performance and Adaptability

Nanotechnology and Prosthetic Devices: Integrating Biomedicine and Materials Science for Enhanced Performance and Adaptability

Shoulder Kinematics Predicts Lateral Asymmetries in Functional Tests of Hand Dexterity

Perspectives on the comparative benefits of body-powered and myoelectric upper limb prostheses

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