High-Intensity, Dynamic-stability Gait Training in People With Multiple Sclerosis

Overview

The goal of this clinical trial is to improve walking speed, balance, and walking in the community for people with multiple sclerosis. This trial involves intense exercise combined with walking on a shaky treadmill. Walking on a shaky treadmill helps to practice balance and intense exercise promotes the ability to walk faster and farther. In this study, participants will train with a combination of high or low intensity, and with a stable or shaky treadmill. Walking speed and endurance, balance while walking and the number of steps taken in the community will be measured before, half way through the training (15 sessions), after training (30 sessions) and six months after training.

This phase I/II clinical trial examines the effects of exercise intensity and balance perturbations on treadmill training in people with multiple sclerosis (MS). People with mild to moderate MS will be assigned to one of four treadmill training groups. One group will conduct treadmill training at a high exercise intensity with balance perturbations applied to the treadmill, a second group will undergo the same training at a low exercise intensity, a third group will conduct treadmill training at a high intensity with no perturbations and the fourth group will train at low intensity with no perturbations. The fourth group resembles typical clinical treadmill training paradigms. Each participant will undergo an initial screening to measure impairment (based on EDSS) and ability to follow three step directions. Demographic information will also be collected on each participant. Twenty participants will be assigned to each treatment group, with group assignment conducted randomly, balanced by severity of MS symptoms so that the impairment across groups is similar. The target sample size for this study was based on extensive previous studies examining high-intensity treadmill training in people with stroke or spinal cord injury, which show large effects compared to conventional treadmill training. In addition, data from a pilot study in people with MS demonstrated that perturbations applied during treadmill training have a large effect on postural stability while walking. The investigators expect that training intensity will impact gait speed and endurance, the use of perturbations will improve balance while walking, and both intensity and perturbations will improve stepping in the community. The proposed training interventions will consist of up to 30 sessions of up to one hour of treadmill training over approximately 10 weeks. Each training session will consist of a warmup period and assessment of intensity, followed by four 10-minute intervals of treadmill stepping (as tolerated) with 2-3 minute rest intervals in between and a cool down at the end. In the groups receiving perturbations, movements will be applied to the treadmill every 7-20 seconds in random direction: right, left, forward or backward. Safety will be assured using a fall arrest harness, which is worn at all times. Perturbation size will be determined using a four-accelerometer system (right foot, left foot, sacrum and C7) to obtain an estimate of margin of stability for right/left perturbations and dynamic stability index for anterior/posterior directions. Training perturbation size will be increased until the stability reaches the stability threshold. This perturbation size will then be used for the training session. The intensity of the training will be controlled by monitoring heart rate. The target heart rate will be 70-80% of age-adjusted heart rate reserve for high intensity training and 30-40% of age-adjusted heart rate reserve for low intensity training. Care will be taken to maintain a cool environment, with monitoring of heart rate, rating of perceived exertion and step count. Depending on initial conditioning, participants may need to start with lower levels of exercise at the beginning of the training period and gradually increase until the target dose is achieved. Assessments of walking function will be made at four times. The first assessment (Baseline) will be made before training begins, a second assessment will be made after 15 training sessions (Mid-Training), a third assessment will be made after training (Post-Training) and a follow up assessment will be made six months after training (Follow-Up). Each assessment will take approximately one hour to complete a series of clinical function tests and laboratory measures of gait function. Specifically, each assessment will consist of measurements of self-selected gait speed, gait endurance, peak treadmill speed, cardiorespiratory fitness and balance confidence. In addition, dynamic balance during gait will be measured using the response to balance perturbations. These measurements will be made using full body motion capture during a set of perturbations in each of the four perturbation directions. Kinematics of the response to the treadmill perturbations will be quantified including measures of foot placement, center of mass movement, with calculations of margin of stability and dynamic gait stability. Additional details of trunk and joint kinematics will be made as secondary measurements. At Baseline, Post-Training and Follow-Up, the investigators will also measure community stepping by issuing each participant a step counter for a 14-day period. The step counter will record the timing of steps throughout the day. When the participant returns, the steps count data will be downloaded and analyzed. Falls will be assessed at Baseline using a survey and each participant will be provided a journal to document falls, with phone contact every 4 weeks through Follow-Up. The study staff making the assessments will be blinded to the treatment group. The training staff and participant will not be able to be blinded to the treatment, since intensity of training and treadmill perturbations cannot be hidden from them. The statistician will be unblinded, as they will assign the participants to the treatment groups and conduct the statistical analysis on the measurements provided by the study staff. The effects of training intensity will be assessed using measurements of gait speed and endurance. The investigators expect significant increases in these measurements with high-intensity compared to low-intensity training. Perturbation training is not expected to affect gait speed or endurance. Instead, the investigators expect that perturbation training will improve balance while walking. Training intensity is not expected to significantly affect balance. Both training intensity and perturbation training are expected to improve community mobility, measured by the number of steps per day. The investigators also expect secondary effects from high-intensity training to include improved cardiorespiratory fitness. Similarly, perturbation training is expected to have positive secondary effects on falls and balance confidence. All together, the investigators anticipate that improvements in community mobility provided by high-intensity perturbation treadmill training will improve quality of life in people with MS.