Abstract
BackgroundProsthetic restoration of reach and grasp function after a trans-humeral amputation requires control of multiple distal degrees of freedom in elbow, wrist and fingers. However, such a high level of amputation reduces the amount of available myoelectric and kinematic information from the residual limb.MethodsTo overcome these limits, we added contextual information about the target’s location and orientation such as can now be extracted from gaze tracking by computer vision tools. For the task of picking and placing a bottle in various positions and orientations in a 3D virtual scene, we trained artificial neural networks to predict postures of an intact subject’s elbow, forearm and wrist (4 degrees of freedom) either solely from shoulder kinematics or with additional knowledge of the movement goal. Subjects then performed the same tasks in the virtual scene with distal joints predicted from the context-aware network.ResultsAverage movement times of 1.22s were only slightly longer than the naturally controlled movements (0.82 s). When using a kinematic-only network, movement times were much longer (2.31s) and compensatory movements from trunk and shoulder were much larger. Integrating contextual information also gave rise to motor synergies closer to natural joint coordination.ConclusionsAlthough notable challenges remain before applying the proposed control scheme to a real-world prosthesis, our study shows that adding contextual information to command signals greatly improves prediction of distal joint angles for prosthetic control.
Highlights
Prosthetic restoration of reach and grasp function after a trans-humeral amputation requires control of multiple distal degrees of freedom in elbow, wrist and fingers
This is in principle sufficient to enable people with trans-humeral amputation to reach various positions in space, but it is not good enough for them to correctly orient their prosthetic hand to grasp oriented objects using the additional degrees of freedom (DoF) that are available in some prosthetic limbs
On average, when computed on samples from the training dataset, the root mean square error (RMSE) achieved by networks C+ and C− were 4.0◦ and 9.7◦ respectively
Summary
Prosthetic restoration of reach and grasp function after a trans-humeral amputation requires control of multiple distal degrees of freedom in elbow, wrist and fingers. [6,7,8] could be exploited to reconstruct missing distal joints from that of remaining proximal ones for prosthesis control [9,10,11,12,13,14,15,16,17,18] This approach faces a dimensionality problem similar to that associated with myoelectric control, because higher amputation still requires more distal joints to be controlled by fewer proximal degrees of freedom. In this context, it is revealing that most of those attempts have been restricted to the sole control of an artificial elbow on the bases of actual shoulder movements [9, 10, 15,16,17,18]. This is in principle sufficient to enable people with trans-humeral amputation to reach various positions in space, but it is not good enough for them to correctly orient their prosthetic hand to grasp oriented objects using the additional degrees of freedom (DoF) that are available in some prosthetic limbs
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