Motor-cognitive dual-task training improves local dynamic stability of normal walking in older individuals.

BACKGROUND: Extreme levels of gait variability and local dynamic stability of walking are associated with risk of falling and reduced executive functions. However, it is not sufficiently investigated how gait variability and local dynamic stability of human walking develop in the course of a motor-cognitive intervention. As dancing implies high demands on (and therewith trains) executive functioning and motor control, it might increase local dynamic stability or reduce gait variability.

METHODS: 32 older healthy participants were randomly assigned to either a health-related exercise group (age: mean=68.33 years, standard deviation=3.17 years; BMI: mean=27.46, standard deviation=2.94; female/male: 10/6) or a dancing group (age: mean=66.73 years, standard deviation=3.33 years; BMI: mean=26.02, standard deviation=3.55; female/male: 11/5). Based on angular velocity data of trunk kinematics, local dynamic stability and stride-to-stride variability in level overground walking were assessed prior to and after the specific intervention. The data were analysed by a blinded observer using two-way repeated measures ANOVAs. Based on one-way ANOVAs, time and group effects were determined.

FINDINGS: Regarding the variability of trunk movements, no interaction effect was observed (F 1,30=0.506, P=.482; η2=0.017). For local dynamic stability of trunk movements, an interaction effect in favour of the dancing group was observed (F 1,30=5,436; P=.026; η2=0.146).

INTERPRETATION: Our data indicate that a dancing programme (which combines cognitive and motor efforts) might increase local dynamic stability in older people.