Internal models of upper limb prosthesis users when grasping and lifting a fragile object with their prosthetic limb

Lum, Peter S.; Black, I.; Holley, Rahsaan J.; Barth, Jessica; Dromerick, Alexander W.

doi:10.1007/s00221-014-4071-1

Cited by 37 publications

(34 citation statements)

References 52 publications

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“…30,31 These findings were higher than our mean score of 13.7blocks/min in experienced upper limb amputees, probably because the previous studies were executed with the patient's own prosthesis instead of a simulator, used a body-powered simulator, or concerned a younger test population. A decrease in BBT scores related to age has been demonstrated previously.…”

Section: Discussioncontrasting

confidence: 79%

Intermanual Transfer Effects in Below-Elbow Myoelectric Prosthesis Users

Boer

Romkema

Cutti³

et al. 2016

Archives of Physical Medicine and Rehabilitation

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Section: Discussioncontrasting

confidence: 79%

Intermanual Transfer Effects in Below-Elbow Myoelectric Prosthesis Users

Boer

Romkema

Cutti³

et al. 2016

Archives of Physical Medicine and Rehabilitation

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“…However, the current study also pointed out that this process has a time dimension and that the model will inevitably deteriorate if not updated again, even in the ideal conditions. The conclusion of another, very recent study (Lum et al 2014) was that the users of open-loop prostheses employ internal models for grasping, but that the accuracy of these models is poor. This is in accordance with what was observed here for the myoelectric control.…”

Section: The Role Of Feedbackmentioning

confidence: 97%

“…Recent studies demonstrated that prosthesis users, similar to able-bodied subjects, might employ internal models for feedforward control of prostheses with no somatosensory feedback (Lum et al 2014;Metzger et al 2010;Weeks et al 2000). However, there is only a single study (Saunders and Vijayakumar 2011) addressing the role of feedforward and feedback processes when using a closed-loop prosthesis.…”

Section: Introductionmentioning

confidence: 98%

Building an internal model of a myoelectric prosthesis via closed-loop control for consistent and routine grasping

et al. 2015

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Prosthesis users usually agree that myoelectric prostheses should be equipped with somatosensory feedback. However, the exact role of feedback and potential benefits are still elusive. The current study investigates the nature of human control processes within a specific context of routine grasping. Although the latter includes a fast feedforward control of the grasping force, the assumption was that the feedback would still be useful; it would communicate the outcome of the grasping trial, which the subjects could use to learn an internal model of feedforward control. Nine able-bodied subjects produced repeatedly a desired level of grasping force using different control configurations: feedback versus no-feedback, virtual versus real prosthetic hand, and joystick versus myocontrol. The outcome measures were the median and dispersion of the relative force errors. The results demonstrated that the feedback was successful in limiting the variability of the routine grasping due to uncertainties in the system and/or the command interface. The internal models of feedforward control could be employed by the subjects to control the prosthesis without the loss of performance even after the force feedback was removed. The models were, however, unstable over time, especially with myocontrol. Overall, the study demonstrates that the prosthesis system can be learned by the subjects using feedback. The feedback is also essential to maintain the model, and it could be delivered intermittently. This approach has practical advantages, but the level to which this mechanism can be truly exploited in practice depends directly on the consistency of the prosthesis control interface.

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“…The study of Lum et al shows that fragile object manipulation is inferior with a prosthesis than with the intact biological hand [24]. However, the performance of the VC BPP user was exceptional compared to the other prosthetic users.…”

Section: Discussionmentioning

confidence: 99%

“…In order to inherently include interaction force limits in this manipulation task, a “mechanical egg” [5] was used which offers repeatable limits: at too little force subjects can’t lift it, and at an adjustable level it “breaks” mechanically. Abstract collapsible objects have been used in diverse studies investigating feedback and pinch force control [5,24], since they offer a natural challenging dynamic grasping task. As prosthetic users aim to execute grasping tasks as quickly as they would with an intact hand, time to execute the task was taken as an outcome measure.…”

Section: Introductionmentioning

confidence: 99%

High Cable Forces Deteriorate Pinch Force Control in Voluntary-Closing Body-Powered Prostheses

et al. 2017

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BackgroundIt is generally asserted that reliable and intuitive control of upper-limb prostheses requires adequate feedback of prosthetic finger positions and pinch forces applied to objects. Body-powered prostheses (BPPs) provide the user with direct proprioceptive feedback. Currently available BPPs often require high cable operation forces, which complicates control of the forces at the terminal device. The aim of this study is to quantify the influence of high cable forces on object manipulation with voluntary-closing prostheses.MethodAble-bodied male subjects were fitted with a bypass-prosthesis with low and high cable force settings for the prehensor. Subjects were requested to grasp and transfer a collapsible object as fast as they could without dropping or breaking it. The object had a low and a high breaking force setting.ResultsSubjects conducted significantly more successful manipulations with the low cable force setting, both for the low (33% more) and high (50%) object’s breaking force. The time to complete the task was not different between settings during successful manipulation trials.ConclusionHigh cable forces lead to reduced pinch force control during object manipulation. This implies that low cable operation forces should be a key design requirement for voluntary-closing BPPs.

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Internal models of upper limb prosthesis users when grasping and lifting a fragile object with their prosthetic limb

Cited by 37 publications

References 52 publications

Intermanual Transfer Effects in Below-Elbow Myoelectric Prosthesis Users

Intermanual Transfer Effects in Below-Elbow Myoelectric Prosthesis Users

Building an internal model of a myoelectric prosthesis via closed-loop control for consistent and routine grasping

High Cable Forces Deteriorate Pinch Force Control in Voluntary-Closing Body-Powered Prostheses

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