Joint speed feedback improves myoelectric prosthesis adaptation after perturbed reaches in non amputees

AbstractAccurate control of human limbs involves both feedforward and feedback signals. For prosthetic arms, feedforward control is commonly accomplished by recording myoelectric signals from the residual limb to predict the user’s intent, but augmented feedback signals are not explicitly provided in commercial devices. Previous studies have demonstrated inconsistent results when artificial feedback was provided in the presence of vision; some studies showed benefits, while others did not. We hypothesized that negligible benefits in past studies may have been due to artificial feedback with low precision compared to vision, which results in heavy reliance on vision during reaching tasks. Furthermore, we anticipated more reliable benefits from artificial feedback when providing information that vision estimates with high uncertainty (e.g. joint speed). In this study, we test an artificial sensory feedback system providing joint speed information and how it impacts performance and adaptation during a hybrid positional-and-myoelectric ballistic reaching task. We found that overall reaching errors were reduced after perturbed control, but did not significantly improve steady-state reaches. Furthermore, we found that feedback about the joint speed of the myoelectric prosthesis control improved the adaptation rate of biological limb movements, which may have resulted from high prosthesis control noise and strategic overreaching with the positional control and underreaching with the myoelectric control. These results provide insights into the relevant factors influencing the improvements conferred by artificial sensory feedback.

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Artificial Joint Speed Feedback for Myoelectric Prosthesis Controls

10.1101/2020.11.17.385450 ◽

2020 ◽

Cited By ~ 1

Author(s):

Eric J. Earley ◽

Reva E. Johnson ◽

Jonathon W. Sensinger ◽

Levi J. Hargrove

Keyword(s):

Sensory Feedback ◽

Feedforward Control ◽

Feedback System ◽

Modest Improvement ◽

Myoelectric Prosthesis ◽

Reaching Task ◽

Prosthesis Control ◽

High Uncertainty ◽

Relevant Factors ◽

Positional Control

I.AbstractAccurate control of human limbs involves both feedforward and feedback signals. For prosthetic arms, feedforward control is commonly accomplished by recording myoelectric signals from the residual limb to predict the user’s intent, but augmented feedback signals are not explicitly provided in commercial devices. Previous studies have demonstrated inconsistent results when artificial feedback was provided in the presence of vision. We hypothesized that negligible benefits in past studies may have been due to artificial feedback with low precision compared to vision, which results in heavy reliance on vision during reaching tasks. Furthermore, we anticipated more reliable benefits from artificial feedback when providing information that vision estimates with high uncertainty – joint speed. In this study, we test an artificial sensory feedback system providing joint speed information and how it impacts performance and adaptation during a hybrid positional-and-myoelectric ballistic reaching task. We found modest improvement in overall reaching errors after perturbed control, and that high prosthesis control noise was compensated for by strategic overreaching with the positional control and underreaching with the myoelectric control. These results provide insights into the relevant factors influencing the improvements conferred by artificial sensory feedback.

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Short- and Long-Term Learning of Feedforward Control of a Myoelectric Prosthesis with Sensory Feedback by Amputees

IEEE Transactions on Neural Systems and Rehabilitation Engineering ◽

10.1109/tnsre.2017.2712287 ◽

2017 ◽

Vol 25 (11) ◽

pp. 2133-2145 ◽

Cited By ~ 19

Author(s):

Matija Strbac ◽

Milica Isakovic ◽

Minja Belic ◽

Igor Popovic ◽

Igor Simanic ◽

...

Keyword(s):

Sensory Feedback ◽

Feedforward Control ◽

Myoelectric Prosthesis ◽

Short And Long Term

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Sensory feedback add-on for upper-limb prostheses

Prosthetics and Orthotics International ◽

10.1177/0309364616677653 ◽

2016 ◽

Vol 41 (3) ◽

pp. 314-317 ◽

Cited By ~ 5

Author(s):

Nader Fallahian ◽

Hassan Saeedi ◽

Hamidreza Mokhtarinia ◽

Farhad Tabatabai Ghomshe

Keyword(s):

Upper Limb ◽

Sensory Feedback ◽

Feedback System ◽

Technical Note ◽

High Tech ◽

Feedback Systems ◽

Myoelectric Prosthesis ◽

Upper Limb Prostheses ◽

Direct Feedback ◽

A Current

Background and aim:Sensory feedback systems have been of great interest in upper-limb prosthetics. Despite tremendous research, there are no commercial modality-matched feedback systems. This article aims to introduce the first detachable and feedback add-on option that can be attached to in-use prostheses.Technique:A sensory feedback system was tested on a below-elbow myoelectric prosthesis. The aim was to have the amputee grasp fragile objects without crushing while other accidental feedback sources were blocked.Discussion:A total of 8 successful trials (out of 10) showed that sensory feedback system decreased the amputee’s visual dependency by improving awareness of his prosthesis. Sensory feedback system can be used either as post-fabrication (prosthetic add-on option) or para-fabrication (incorporated into prosthetic design). The use of these direct feedback systems can be explored with a current prosthesis before ordering new high-tech prosthesis.Clinical relevanceThis technical note introduces the first attach/detach-able sensory feedback system that can simply be added to in-use (myo)electric prosthesis, with no obligation to change prosthesis design or components.

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Neurophysiology of slip sensation and grip reaction: insights for hand prosthesis control of slippage.

Journal of Neurophysiology ◽

10.1152/jn.00087.2021 ◽

2021 ◽

Author(s):

Andrea Zangrandi ◽

Marco D'Alonzo ◽

Christian Cipriani ◽

Giovanni Di Pino

Keyword(s):

Human Physiology ◽

Sensory Feedback ◽

Grip Force ◽

Feedback System ◽

Hand Movements ◽

Load Force ◽

Physiological Basis ◽

Three Phase ◽

Phase Slippage ◽

Prosthesis Control

Sensory feedback is pivotal for a proficient dexterity of the hand. By modulating the grip force in function of the quick and not completely predictable change of the load force, grabbed objects are prevented to slip from the hand. Slippage control is an enabling achievement to all manipulation abilities. However, in hand prosthetics, the performance of even the most innovative research solutions proposed so far to control slippage remain distant from the human physiology. Indeed, slippage control involves parallel and compensatory activation of multiple mechanoceptors, spinal and supraspinal reflexes and higher-order voluntary behavioral adjustments. In this work, we reviewed the literature on physiological correlates of slippage to propose a three-phases model for the slip sensation and reaction. Furthermore, we discuss the main strategies employed so far in the research studies that tried to restore slippage control in amputees. In the light of the proposed three-phase slippage model, and from the weaknesses of already implemented solutions, we proposed several physiology-inspired solutions for slippage control, to be implemented in the future hand prostheses. Understanding the physiological basis of slip detection and perception and implementing them in novel hand feedback system would make prosthesis manipulation more efficient and would boost its perceived naturalness, fostering the sense of agency for the hand movements.

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Ideas on sensory feedback in hand prostheses

Prosthetics and Orthotics International ◽

10.3109/03093647909103104 ◽

1979 ◽

Vol 3 (3) ◽

pp. 157-162 ◽

Cited By ~ 11

Author(s):

P. Herberts ◽

L. Körner

Keyword(s):

Pattern Recognition ◽

Control Systems ◽

Future Development ◽

Sensory Feedback ◽

Feedback System ◽

Signal Acquisition ◽

Feedback Systems ◽

Proportional Control ◽

Prosthesis Control ◽

Further Development

Development of systems for sensory feedback in hand prostheses has not been as successful as that of modern prosthesis control systems. The discrepancy is partly caused by an insufficient analysis of the concept of sensory feedback and by neglect of knowledge on the physiology of kinesthesis. In the present paper modern theories on physiologic kinesthesis are briefly summarized and the implication of these theories on the development of prosthesis sensory feedback systems are discussed. It is concluded that the future development of sensory feedback systems for hand prostheses should be directed towards increased utilization of the physiologic kinesthesis resulting from operation of the prosthesis control systems. This can be obtained by further development of the control systems. One promising approach in this direction is the use of a proportional control signal based on signal acquisition through pattern recognition of multiple myoelectric signals. Development of artificial systems for feedback should be restricted to situations when feedback emerging from the prosthesis control is insufficient. The importance of simplicity and reliability of feedback systems is stressed as well as the necessity to maintain prosthesis self-containment even after application of a feedback system.

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