O Bock1, B S Cheung. 1. German Sports University, Köln, Germany.
Abstract
BACKGROUND: Previous work suggests that proprioceptive signals are degraded in hypergravity (hyper-G). We therefore, expected that production of finely graded force is disturbed as well. METHODS: Subjects produced isometric force with their thumb and index finger upon verbal instruction, before, during and after exposure to +1.5 Gz and +3 Gz. Produced force was orthogonal to the direction of gravity. RESULTS: In hyper-G, responses to a given target value were significantly higher (by about 400 pond) than in normal gravity, while the modulation of produced force with target force didn't change. The results in +1.5 Gz and +3 Gz were quantitatively similar, and a positive aftereffect was found. CONCLUSIONS: Subjects underestimate by a constant amount the force they produce in hyper-G. Our results are reminiscent of similar findings with pointing and grasping movements in hyper-G.
BACKGROUND: Previous work suggests that proprioceptive signals are degraded in hypergravity (hyper-G). We therefore, expected that production of finely graded force is disturbed as well. METHODS: Subjects produced isometric force with their thumb and index finger upon verbal instruction, before, during and after exposure to +1.5 Gz and +3 Gz. Produced force was orthogonal to the direction of gravity. RESULTS: In hyper-G, responses to a given target value were significantly higher (by about 400 pond) than in normal gravity, while the modulation of produced force with target force didn't change. The results in +1.5 Gz and +3 Gz were quantitatively similar, and a positive aftereffect was found. CONCLUSIONS: Subjects underestimate by a constant amount the force they produce in hyper-G. Our results are reminiscent of similar findings with pointing and grasping movements in hyper-G.
Authors: Ana Diaz-Artiles; Yiyu Wang; Madison M Davis; Renee Abbott; Nathan Keller; Deanna M Kennedy Journal: Front Physiol Date: 2022-01-07 Impact factor: 4.566