TY - JOUR
T1 - Are reaching and grasping effector-independent? Similarities and differences in reaching and grasping kinematics between the hand and foot
AU - Liu, Yuqi
AU - Caracoglia, James
AU - Sen, Sriparna
AU - Freud, Erez
AU - Striem-Amit, Ella
N1 - Publisher Copyright:
© 2022, The Author(s).
PY - 2022/6/1
Y1 - 2022/6/1
N2 - While reaching and grasping are highly prevalent manual actions, neuroimaging studies provide evidence that their neural representations may be shared between different body parts, i.e., effectors. If these actions are guided by effector-independent mechanisms, similar kinematics should be observed when the action is performed by the hand or by a cortically remote and less experienced effector, such as the foot. We tested this hypothesis with two characteristic components of action: the initial ballistic stage of reaching, and the preshaping of the digits during grasping based on object size. We examined if these kinematic features reflect effector-independent mechanisms by asking participants to reach toward and to grasp objects of different widths with their hand and foot. First, during both reaching and grasping, the velocity profile up to peak velocity matched between the hand and the foot, indicating a shared ballistic acceleration phase. Second, maximum grip aperture and time of maximum grip aperture of grasping increased with object size for both effectors, indicating encoding of object size during transport. Differences between the hand and foot were found in the deceleration phase and time of maximum grip aperture, likely due to biomechanical differences and the participants’ inexperience with foot actions. These findings provide evidence for effector-independent visuomotor mechanisms of reaching and grasping that generalize across body parts.
AB - While reaching and grasping are highly prevalent manual actions, neuroimaging studies provide evidence that their neural representations may be shared between different body parts, i.e., effectors. If these actions are guided by effector-independent mechanisms, similar kinematics should be observed when the action is performed by the hand or by a cortically remote and less experienced effector, such as the foot. We tested this hypothesis with two characteristic components of action: the initial ballistic stage of reaching, and the preshaping of the digits during grasping based on object size. We examined if these kinematic features reflect effector-independent mechanisms by asking participants to reach toward and to grasp objects of different widths with their hand and foot. First, during both reaching and grasping, the velocity profile up to peak velocity matched between the hand and the foot, indicating a shared ballistic acceleration phase. Second, maximum grip aperture and time of maximum grip aperture of grasping increased with object size for both effectors, indicating encoding of object size during transport. Differences between the hand and foot were found in the deceleration phase and time of maximum grip aperture, likely due to biomechanical differences and the participants’ inexperience with foot actions. These findings provide evidence for effector-independent visuomotor mechanisms of reaching and grasping that generalize across body parts.
KW - Effector-independent
KW - Grasping
KW - Motor cortex
KW - Reaching
KW - Visuomotor
UR - http://www.scopus.com/inward/record.url?scp=85128206566&partnerID=8YFLogxK
U2 - 10.1007/s00221-022-06359-x
DO - 10.1007/s00221-022-06359-x
M3 - Article
C2 - 35426511
AN - SCOPUS:85128206566
SN - 0014-4819
VL - 240
SP - 1833
EP - 1848
JO - Experimental Brain Research
JF - Experimental Brain Research
IS - 6
ER -