Deep white matter hyperintensities, microstructural integrity and dual task walking in older people

Abstract

To examine neural, physiological and cognitive influences on gait speed under single and dual-task conditions. Sixty-two community-dwelling older people (aged 80.0 آ± 4.2 years) participated in our study. Gait speed was assessed with a timed 20-meter walk under single and dual-task (reciting alternate letters of the alphabet) conditions. Participants also underwent tests to estimate physiological fall risk based on five measures of sensorimotor function, cognitive function across five domains, brain white matter (WM) hyperintensities and WM microstructural integrity by measuring fractional anisotropy (FA). Univariate linear regression analyses showed that global physiological and cognitive measures were associated with single (? = 0.594 and ?=-0.297, respectively) and dual-task gait speed (? = 0.306 and ?=-0.362, respectively). Deep WMHs were associated with dual-task gait speed only (? = 0.257). Multivariate mediational analyses showed that global and executive cognition reduced the strength of the association between deep WMHs and dual-task gait speed by 27% (? = 0.188) and 44% (? = 0.145) respectively. There was a significant linear association between single-task gait speed and mean FA values of the genu (?=-0.295) and splenium (?=-0.326) of the corpus callosum, and between dual-task gait speed and mean FA values of Superior Cerebellar Peduncle (?=-0.284), splenium of the Corpus Callosum (?=-0.286) and Cingulum (?=-0.351). Greater deep WMH volumes are associated with slower walking speed under dual-task conditions, and this relationship is mediated in part by global cognition and executive abilities specifically. Furthermore, both cerebellum and cingulum are related to dual-task walking due to their role in motor skill performance and attention, respectively. é 2017 Springer Science+Business Media, LLC