Dual-task walking poses substantial challenges for individuals with Parkinson’s disease (PD), particularly those with freezing of gait (FOG), as dual-task interference increases fall risk and limits functional mobility.
Objective:
To investigate dual-task interference at both the behavioral and neural levels in PD individuals with FOG (PDFOG+) and those without FOG (PDFOG−) during dual-task walking involving a demanding manual task.
Methods:
Seventeen PDFOG− and 17 PDFOG+ participated in this study. Gait performance, manual-task performance, and scalp electroencephalograph (EEG) were recorded in single-task condition and dual-task walking while performing a high attentional-load manual task (an interlocking ring task). The primary behavioral outcomes were dual-task costs (DTC) of gait velocity and ring performance, representing locomotor interference and manual-task interference, respectively. The primary neural outcomes focused on theta-band EEG measures, including regional theta power and inter-regional theta connectivity, given their established role in attentional control during dual-task walking in PDFOG+.
Results:
Compared with PDFOG−, PDFOG+ exhibited significantly less DTC of gait velocity and greater DTC of ring performance. At the neural level, PDFOG+ demonstrated attenuated task-dependent modulations of increased theta-band power and decreased theta-band connectivity relative to PDFOG−.
Conclusions:
PDFOG+ exhibited an atypical pattern of dual-task interference characterized by preserved gait velocity at the expense of concurrent manual-task performance, together with diminished theta-band attentional modulation. These findings suggest limited flexibility in attentional resource allocation in PDFOG+ and highlight theta-band neural dynamics as a key mechanism underlying maladaptive task-task regulation during walking.
Trial Registration:
National Taiwan University Hospital Research Ethics Committee: No. NCT03298503.
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