Obstacle avoidance and smooth trajectory control: neural areas highlighted during improved locomotor performance

Billington, Jac and Wilkie, Richard M. and Wann, John P. (2013) Obstacle avoidance and smooth trajectory control: neural areas highlighted during improved locomotor performance. Frontiers in Behavioral Neuroscience, 7. ISSN 1662-5153

[thumbnail of pubmed-zip/versions/1/package-entries/fnbeh-07-00009/fnbeh-07-00009.pdf] Text
pubmed-zip/versions/1/package-entries/fnbeh-07-00009/fnbeh-07-00009.pdf - Published Version

Download (1MB)

Abstract

Visual control of locomotion typically involves both detection of current egomotion as well as anticipation of impending changes in trajectory. To determine if there are distinct neural systems involved in these aspects of steering control we used a slalom paradigm, which required participants to steer around objects in a computer simulated environment using a joystick. In some trials the whole slalom layout was visible (steering “preview” trials) so planning of the trajectory around future waypoints was possible, whereas in other trials the slalom course was only revealed one object at a time (steering “near” trials) so that future planning was restricted. In order to control for any differences in the motor requirements and visual properties between “preview” and “near” trials, we also interleaved control trials which replayed a participants' previous steering trials, with the task being to mimic the observed steering. Behavioral and fMRI results confirmed previous findings of superior parietal lobe (SPL) recruitment during steering trials, with a more extensive parietal and sensorimotor network during steering “preview” compared to steering “near” trials. Correlational analysis of fMRI data with respect to individual behavioral performance revealed that there was increased activation in the SPL in participants who exhibited smoother steering performance. These findings indicate that there is a role for the SPL in encoding path defining targets or obstacles during forward locomotion, which also provides a potential neural underpinning to explain improved steering performance on an individual basis.

Item Type: Article
Subjects: STM One > Biological Science
Depositing User: Unnamed user with email support@stmone.org
Date Deposited: 18 Mar 2023 09:00
Last Modified: 17 Jun 2024 06:46
URI: http://publications.openuniversitystm.com/id/eprint/566

Actions (login required)

View Item
View Item