A-25 The Effect of Cognitive Dual-Tasks on Dynamic Postural Sway During Sub-Maximal Gait on a Treadmill

Abstract

Abstract Objective To investigate the effect of a cognitive task on postural control during treadmill walking. We hypothesized that postural sway acceleration would decrease during dual-task compared to single-task gait. Method Ten (5 females, 5 males) physically active, healthy young adults (Age: 22.50 ± 3.01) with no history of cognitive deficits or head injury were recruited from a University campus for this cross-sectional study. Participants reported to a biomechanics laboratory for a single testing session and completed two, 5-minute walking trials on a treadmill at 90% of maximal gait-speed under single and dual-task conditions while instrumented with a single inertial measurement unit (IMU) on the lower-back. During dual-task gait, participants concurrently performed a Stroop Test displayed on a mounted screen in front of the treadmill during the entire trial. Root mean square (RMS) of acceleration was analyzed in the medial-lateral, anterior-posterior, superior-inferior, and resultant planes during the dual-task trial. Paired t-tests and effect sizes (ES) were calculated for each sway plane between single and dual-tasks. Results No differences were identified between single and dual-task RMS acceleration in the medial-lateral (p = 0.98, ES = 0.01), anterior-posterior (p = 0.49, ES = 0.23) or superior-inferior (p = 0.98, ES = 0.01) planes. However, the RMS acceleration in the resultant plane was lower in the dual-task condition (Mean Difference: 0.031 ± 0.037; p = 0.02, ES = 0.85). Conclusions This novel dual-task gait paradigm utilized constant sub-maximal gait speed to investigate the influence of a sustained cognitive dual-task on postural sway using a single IMU. These preliminary results indicate that this dual-task gait paradigm may affect gross postural sway in healthy adults.