Kinematic analysis of the human wrist during pointing tasks

In this work, we tested the hypothesis that intrinsic kinematic constraints such as Donders’ law are adopted by the brain to solve the redundancy in pointing at targets with the wrist. Ten healthy subjects were asked to point at visual targets displayed on a monitor with the three dof of the wrist. Three-dimensional rotation vectors were derived from the orientation of the wrist acquired during the execution of the motor task and numerically fitted to a quadratic surface to test Donders’ law. The thickness of the Donders’ surfaces, i.e., the deviation from the best fitting surface, ranged between 1° and 2°, for angular excursions from ±15° to ±30°. The results support the hypothesis under test, in particular: (a) Two-dimensional thick surfaces may represent a constraint for wrist kinematics, and (b) inter-subject differences in motor strategies can be appreciated in terms of curvature of the Donders’ surfaces.

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