Motor Flexibility in Multidirectional Balance Control

Falls are the leading cause of injury-related fatalities in people aged 65 and above, often triggered by unexpected disruptions like slips or trips during walking. Such events necessitate rapid and adaptable motor responses to regain balance, a mechanism referred to as "reactive balance control." Within this complex interplay, "motor flexibility," or the ability to modulate one's movements in real-time based on sensory feedback, becomes critical. However, there exists a trade-off: increased flexibility requires more complex sensory processing, potentially delaying the initiation of corrective actions-a delay that can prove perilous in the context of a fall. This study seeks to explore the role of motor flexibility in reactive balance control, particularly in older adults, with a focus on understanding how individuals adapt stepping patterns in response to diverse and unpredictable balance disturbances. State-of-the-art technology will be employed including a Computer-Assisted Rehabilitation Environment (CAREN), to simulate various types of walking surface disruptions. By studying younger and older adults and introducing different types of perturbations, the study aims to understand the trade-offs between the speed of motor response and the flexibility to adapt to different fall scenarios. Additionally, the extent to which training can improve this balance control flexibility is investigated. The central hypothesis is that motor flexibility is a modifiable feature of reactive balance control and is positively correlated with the ability to recover from multi-directional disturbances. The study will quantify this relationship and assess the potential for improvement through targeted interventions. Aim 1 of the research is designed to measure these trade-offs in older adults by introducing controlled perturbations to a walking platform, thereby providing critical data on how speed and flexibility interact in real-world fall scenarios. Computational models will be used to evaluate how these variables contribute to an individual's ability to resist falls from varying directions and magnitudes. Aim 2 will explore the potential for improving balance control flexibility through targeted training, studying both younger and older adults to gauge the effects of age on the adaptability of motor control. Improvements in balance flexibility and determine how these changes interact with other physiological factors like body mass index and rate of force development. The results of this study will provide foundational data that can be used to develop more effective fall-prevention strategies for older adults. This research bridges biomechanics and computational modeling, offering an interdisciplinary lens through which to view a problem of substantial public health significance. By understanding the nuances of how motor flexibility and reaction speed interact in the context of unexpected balance disturbances, we aim to make strides in mitigating the risks and consequences of falls in older adults.