Abstract

Dexterous use of the hands depends critically on sensory feedback, so it is generally agreed that functional supplementary feedback would greatly improve the use of hand prostheses. Much research still focuses on improving non-invasive feedback that could potentially become available to all prosthesis users. However, few studies on supplementary tactile feedback for hand prostheses demonstrated a functional benefit. We suggest that confounding factors impede accurate assessment of feedback, e.g., testing non-amputee participants that inevitably focus intently on learning EMG control, the EMG’s susceptibility to noise and delays, and the limited dexterity of hand prostheses. In an attempt to assess the effect of feedback free from these constraints, we used silicone digit extensions to suppress natural tactile feedback from the fingertips and thus used the tactile feedback-deprived human hand as an approximation of an ideal feed-forward tool. Our non-amputee participants wore the extensions and performed a simple pick-and-lift task with known weight, followed by a more difficult pick-and-lift task with changing weight. They then repeated these tasks with one of three kinds of audio feedback. The tests were repeated over three days. We also conducted a similar experiment on a person with severe sensory neuropathy to test the feedback without the extensions. Furthermore, we used a questionnaire based on the NASA Task Load Index to gauge the subjective experience. Unexpectedly, we did not find any meaningful differences between the feedback groups, neither in the objective nor the subjective measurements. It is possible that the digit extensions did not fully suppress sensation, but since the participant with impaired sensation also did not improve with the supplementary feedback, we conclude that the feedback failed to provide relevant grasping information in our experiments. The study highlights the complex interaction between task, feedback variable, feedback delivery, and control, which seemingly rendered even rich, high-bandwidth acoustic feedback redundant, despite substantial sensory impairment.

Highlights

  • Skilled use of our hands, whether to pick up a bottle of water or to perform brain surgery, depends crucially on somatosensory feedback from our fingers [1]

  • We provided three different kinds of non-invasive feedback–discrete, continuous, and a hybrid of the two–in an attempt to measure and compare the effect it would have on grasping with reduced finger-sensitivity

  • We used the well-established NASA Task-Load Index (TLX) questionnaire [45], and we expected to find a difference in task-load scores between feedback and no-feedback groups and hoped to be able to describe the contribution of the individual factors to the overall workload

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Summary

Introduction

Skilled use of our hands, whether to pick up a bottle of water or to perform brain surgery, depends crucially on somatosensory feedback from our fingers [1]. Some studies have shown that continuous force feedback can lead to improved grasping control in functional tasks or every-day use [11,12,13]. This form of feedback is not available to the overwhelming majority of prosthesis users. In an attempt to increase the comparability of our results to those of previous studies, we assessed the effect of the impaired natural feedback as well as the supplementary feedback with a common pick-and-lift task used by many other studies and research groups (see, for example, [28, 29, 37, 41,42,43]). We used the well-established NASA Task-Load Index (TLX) questionnaire [45], and we expected to find a difference in task-load scores between feedback and no-feedback groups and hoped to be able to describe the contribution of the individual factors (cognitive, physical, etc.) to the overall workload (see [14, 46])

Participants
Experimental procedure
Results
Discussion

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