Prehension synergies: Effects of object geometry and prescribed torques

Abstract. We studied the coordination of forces and moments exerted by individual digits in static tasks that required balancing an external load and torque. Subjects (n=10) stabilized a handle with an attachment that allowed for change of external torque. Thumb position and handle width systematically varied among the trials. Each subject performed 63 tasks (7 torque values × 3 thumb locations × 3 widths). Forces and moments exerted by the digit tips on the object were recorded. Although direction and magnitude of finger forces varied among subjects, each subject used a similar multidigit synergy: a single eigenvalue accounted for 95.2–98.5% of the total variance. When task parameters were varied, regular conjoint digital force changes (prehension synergies) were observed. Synergies represent preferential solutions used by the subjects to satisfy mechanical requirements of the tasks. In particular, chain effects in force adjustments to changes in the handle geometry were documented. An increased handle width induced the following effects: (a) tangential forces remained unchanged, (b) the same tangential forces produced a larger moment Tt, (c) the increased Tt was compensated by a smaller moment of the normal forces Tn, and (d) normal finger forces were rearranged to generate a smaller moment. Torque control is a core component of prehension synergies. Observed prehension synergies are only mechanically necessitated in part. The data support a theory of hierarchical organization of prehension synergies.

[1]  J. Foley The co-ordination and regulation of movements , 1968 .

[2]  I. Gartside Models of the Structural—Functional Organization of Certain Biological Systems , 1973 .

[3]  S. Gruber,et al.  Robot hands and the mechanics of manipulation , 1987, Proceedings of the IEEE.

[4]  K. J. Cole,et al.  Kinematic and electromyographic responses to perturbation of a rapid grasp. , 1987, Journal of neurophysiology.

[5]  K. J. Cole,et al.  Grip force adjustments evoked by load force perturbations of a grasped object. , 1988, Journal of neurophysiology.

[6]  R. Howe,et al.  Human grasp choice and robotic grasp analysis , 1990 .

[7]  Philippe Gorce,et al.  Grasping, coordination and optimal force distribution in multifingered mechanisms , 1994, Robotica.

[8]  H. Kinoshita,et al.  Contributions and co-ordination of individual fingers in multiple finger prehension. , 1995, Ergonomics.

[9]  M. Schieber Individuated Finger Movements: Rejecting the Labeled-Line Hypothesis , 1996 .

[10]  Thea Iberall,et al.  Human Prehension and Dexterous Robot Hands , 1997, Int. J. Robotics Res..

[11]  M. Latash,et al.  A principle of error compensation studied within a task of force production by a redundant set of fingers , 1998, Experimental Brain Research.

[12]  Vladimir M. Zatsiorsky,et al.  Coordinated force production in multi-finger tasks: finger interaction and neural network modeling , 1998, Biological Cybernetics.

[13]  Karl M. Newell,et al.  Motor redundancy during maximal voluntary contraction in four-finger tasks , 1998, Experimental Brain Research.

[14]  M. Latash,et al.  Force sharing among fingers as a model of the redundancy problem , 1998, Experimental Brain Research.

[15]  R S Johansson,et al.  Control of fingertip forces in multidigit manipulation. , 1999, Journal of neurophysiology.

[16]  R. Johansson,et al.  Control of grasp stability in humans under different frictional conditions during multidigit manipulation. , 1999, Journal of neurophysiology.

[17]  J. F. Soechting,et al.  Force synergies for multifingered grasping , 2000, Experimental Brain Research.

[18]  M H Schieber,et al.  Quantifying the Independence of Human Finger Movements: Comparisons of Digits, Hands, and Movement Frequencies , 2000, The Journal of Neuroscience.

[19]  M. Latash,et al.  Enslaving effects in multi-finger force production , 2000, Experimental Brain Research.

[20]  J. F. Soechting,et al.  Factors influencing variability in load forces in a tripod grasp , 2002, Experimental Brain Research.

[21]  J. F. Soechting,et al.  Two virtual fingers in the control of the tripod grasp. , 2001, Journal of neurophysiology.

[22]  M. Latash,et al.  Structure of motor variability in marginally redundant multifinger force production tasks , 2001, Experimental Brain Research.

[23]  Gregor Schöner,et al.  Understanding finger coordination through analysis of the structure of force variability , 2002, Biological Cybernetics.

[24]  M. Latash,et al.  Motor Control Strategies Revealed in the Structure of Motor Variability , 2002, Exercise and sport sciences reviews.

[25]  Vladimir M. Zatsiorsky,et al.  Force and torque production in static multifinger prehension: biomechanics and control. I. Biomechanics , 2002, Biological Cybernetics.

[26]  Zong-Ming Li Inter-digit co-ordination and object-digit interaction when holding an object with five digits , 2002, Ergonomics.

[27]  Nirmal K. Bose,et al.  Anatomically and experimentally based neural networks modeling force coordination in static multi-finger tasks , 2002, Neurocomputing.

[28]  Gregor Schöner,et al.  A mode hypothesis for finger interaction during multi-finger force-production tasks , 2003, Biological Cybernetics.