Direction-dependent arm kinematics reveal optimal integration of gravity cues
QH301-705.5
Science
visual gravitational motion
linear acceleration
optimal control
03 medical and health sciences
0302 clinical medicine
internal-models
motor planning
motor control
Humans
Biology (General)
muscle activation
pointing movements
sensorimotor adaptation
macaque cerebellum
Q
R
Brain
decision-making
stroke patients
gravity
Biomechanical Phenomena
torque-change model
kinematics
Arm
Medicine
[SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]
Psychomotor Performance
Computational and Systems Biology
Gravitation
DOI:
10.7554/elife.16394
Publication Date:
2016-11-02T12:00:19Z
AUTHORS (4)
ABSTRACT
The brain has evolved an internal model of gravity to cope with life in the Earth's gravitational environment. How this internal model benefits the implementation of skilled movement has remained unsolved. One prevailing theory has assumed that this internal model is used to compensate for gravity's mechanical effects on the body, such as to maintain invariant motor trajectories. Alternatively, gravity force could be used purposely and efficiently for the planning and execution of voluntary movements, thereby resulting in direction-depending kinematics. Here we experimentally interrogate these two hypotheses by measuring arm kinematics while varying movement direction in normal and zero-G gravity conditions. By comparing experimental results with model predictions, we show that the brain uses the internal model to implement control policies that take advantage of gravity to minimize movement effort.
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