Task Complexity and Limb Dominance Modulate the Effects of Ageing on Neuromuscular Function

Aim: This study aimed to investigate age-related and limb-specific differences in neuromuscular function of vastus lateralis. While muscle strength is critical for functional independence in ageing, asymmetries between the dominant and non-dominant limbs, which can arise from central or peripheral mechanisms, are not well understood. We specifically examined whether bilateral differences exist in neuromuscular function and motor unit (MU) firing behaviours in young and older people, and whether these differences vary with task complexity. Methods: Twenty-one healthy young adults (22 (4) years; 15M, 6F) and seventeen healthy older adults (74 (5) years; 12M, 5F) were recruited. High-density surface electromyography signals were collected bilaterally from the vastus lateralis during constant and variable load contractions normalised to maximal voluntary isometric contraction (MVC) and decomposed into individual MU spike trains. Muscle strength and force control as well as MU firing properties were compared bilaterally using multilevel mixed-effects linear regression models. Statistical significance was accepted at p<0.05. Results: Older adults showed reduced maximal voluntary force, increased force tracking error, and lower MU firing rates (MUFR), particularly during sinusoidal contractions. Force steadiness and MUFR variability revealed distinct Leg x AgeGroup interactions: older adults had greater variability in non-dominant legs, while younger adults showed the opposite. MU firing properties differed between contraction types, with age-related impairments most evident during dynamic tasks. Conclusion: These findings highlight that neuromuscular ageing is not uniformly bilateral but involves asymmetric adaptations, especially under dynamic force demands. Despite symmetrical limb use, leg dominance effects become more pronounced with age, potentially reflecting compensatory neuromuscular strategies. Task complexity amplifies these asymmetries, underscoring the need to consider limb-specific neural control when addressing age-related motor decline.