MStep: The Role of Exercise in Modifying Outcomes for People With Multiple Sclerosis

Study Description

Brief Summary

Despite the benefits of exercise and physical activity people with Multiple Sclerosis (MS) are relatively inactive. Physical activity is important for persons with disabilities to maintain physical function. A lack of physical activity can contribute to heart disease, osteoporosis, obesity, and diabetes. At the moment, the best way for people with MS to exercise and be physical activity is unknown. People with MS report not knowing what to do. This is a barrier to exercise.

The global aim of this study is to contribute evidence for the role of targeted exercise in altering MS outcomes over time. The design is a randomized controlled trial (RCT). The primary research question is to what extent does an MS Tailored Exercise Program (MSTEP) result in greater improvements in exercise capacity and related outcomes in comparison to a program based on general guidelines for exercise among people with MS who are sedentary and wish to engage in exercise as part of MS self-management. The primary outcome for this question is exercise capacity measured using cycle ergometry. However exercise efficiency, functional ambulation, strength, components of quality of life including frequency and intensity of fatigue symptoms, mood, global physical function, health perception, and illness intrusiveness, will also be measured as components of a global response outcome. The first confirmatory hypothesis is that MSTEP will result in a greater proportion of people making clinically relevant gains (at least 10% change) in exercise capacity than with general guidelines after 12 months of intervention; a secondary hypothesis is that, while there may be some decline in exercise capacity among individuals from end of intervention to follow-up one year later, the decline will be greater in the general guideline group augmenting the difference between groups in the proportion making 10% change from study entry to 24 months. In other words, gains will be maintained more for the MSTEP group over the general guideline group.

An exploratory hypothesis is that more of the targeted outcomes will improve with the MSTEP program than the general guideline approach. An explanatory hypothesis is that these gains will be accompanied by reports of greater exercise enjoyment and exercise self-efficacy (confidence) with the MSTEP program than with the general guideline program leading to more consistent exercise engagement and improved long-term adherence.

Detailed Description

The proposal is for an assessor-blind, parallel-group, stratified, randomized controlled trial. Potential participants will be identified from the population of persons enrolled in 3 MS clinics in the Montreal area and in 3 clinics in Toronto. All persons who are known to be ambulatory and not to have co-morbidity preventing exercise engagement or capacity to consent will be informed of the study in writing and will be invited for an assessment to determine eligibility for entry into the trial. Those consenting will be randomly assigned to either the MSTEP program or the general exercise guideline program. The intervention period will be one year with follow-up to a second year.

The investigators are targeting a sample size of 120 per group (total 240), which would be sufficient to detect RR of > 1.5 with 80% power. Sample size estimated using pc-size software. The sample size takes into account that drop-outs will inflate the variance of outcomes as multiple imputation will be used to deal with missing data.

The main analysis will be logistic regression to test the main hypothesis related to the superiority of the MSTEP program based on a greater proportion of people making a clinically relevant gain in exercise capacity at 1 year. A secondary outcome will be the differences in proportions at 2 years also using logistic regression. The analysis will be based on intention-to-treat and all persons will be analysed in the groups to which they were randomized.

A secondary analysis will estimate the impact of exercise on the other relevant outcomes. For this approach, each outcome will be converted to a binary response variable based on published clinically meaningful changes and generalized estimating equations (GEE) will be used to test the rate of response in the MSTEP program to the rate of response in the general guideline approach. Multiple outcomes improves the efficiency of the study as the total number of data points is equivalent to the total n multiplied by the number of tests and reduced by the extent to which the outcomes are correlated. Highly correlated outcomes will make the effective sample size smaller than less strongly correlated outcomes. If there is a statistically significant effect of the intervention, then and only then, can the effects of the separate outcomes be interpreted as real.

The results of the trial will be used to develop guidelines for exercise for MS. The investigators are in the process of copyrighting the name of the program (MSTEP). Upon publication of the findings, the description of content will be made available at no cost. If proven effective, a training guide for professionals and patients will be produced most likely taking advantage of the end-of-grant Knowledge Translation (KT) Supplement. Note: The investigators have been funded by the KT supplement to produce a general guide for people with MS, entitled: Getting on with Your Life with MS. The knowledge generated can be used by people with MS and health professional to promote exercise engagement.

Study Design

Outcome Measures

Primary Outcome Measures

1. oxygen consumption [3 timepoints: baseline, at 12 monts, at 24 months]

   VO2peak will be determined using an incremental graded cycle ergometer test. Greater oxygen consumption implies in better exercise capacity

Secondary Outcome Measures

1. muscle strength measured with Biodex [3 timepoints: Baseline, at 12 months, at 24 months]

   Greater values imply greater muscle strength

2. 6 Minute Walk test (6MWT) [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   Distance walked will be measured with the 6-Minute Walk Test. Greater values imply that a longer distance was covered within 6 minutes

3. Anaerobic leg power [1 timepoint: baseline]

   Greater value indicate greater anaerobic leg power

4. Patient Determined Disease Steps (PDDS) [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   Patient Determined Disease Steps (PDDS) is a scale focusing mainly on how well someone walk. It ranges from mild symptoms that do not affect physical activity to inability to sit in a wheel chair for more than 1 hour.

5. Change in fatigue levels [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   Fatigue will be measured with a single item question asking them the number of days that they felt certain levels of fatigue.

6. Rand 36 [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   Health status will be measured with the Rand36 Health Status Survey. The Rand36 consists of eight scaled scores, which are the weighted sums of the questions in their section. Each scale is directly transformed into a 0-100 scale on the assumption that each question carries equal weight.

7. EQ-5D [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   The respondent is asked to indicate his/her health state in each of 5 dimensions. The digits for 5 dimensions can be combined in a 5-digit number describing the respondent's health state.The EQ VAS records the respondent's self-rated health on a 20 cm vertical, visual analogue scale with endpoints labelled 'the best health you can imagine' and 'the worst health you can imagine'. This information can be used as a quantitative measure of health as judged by the individual respondents

8. Patient generated Index [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   Participants will be asked to identify 5 most important areas of their life that are affected by multiple sclerosis. A second step will be to score how much affected these identified areas were over the past MONTH, in a scale from 1 to 10.

9. Exercise Self-Efficacy Scale [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

   This will be measured by the Exercise Self-Efficacy Scale, in which participants are asked how certain they are that they can get to perform an exercise routine regularly (three or more times a week). The scale ranges from 0 (not confident) to 100 (highly confident).

10. Change in perception about exercise benefits and exercise barrier [5 timepoints: at baseline, at 6 months, at 12 months, at 18 months, at 24 months]

    It will be measured with a self-reported questionnaire. For the exercise benefits, the scale range as "strongly disagree, disagree, agree, strongly agree". For the exercise barriers the scale range as "sometimes a barrier", "often a barrier"

11. Modified Canadian Aerobic Fitness test [3 timepoints: 3 month, 6 month and 18 month]

    mCAFT is a graded step test and can predict VO2peak using a regression equation recently published. Thus, we are confident that we will get usable data for each person and as we are looking for a proportion of people who change over time, persons who do not achieve a peak and have low values on the mCAFT will have a very low value for exercise capacity. Greater steps cadence imply on greater oxygen cost

Eligibility Criteria

Criteria

Inclusion Criteria:

• be community dwelling individuals aged 19 -65 who have been diagnosed after 1994 with MS or CIS;

• be able to speak and read English or French;

• be capable of walking 100 meters without a walking aid (EDSS ≤ 5.5), even if they do use an aid for daily activities.

Exclusion Criteria:

• have an additional illness that restricts their function; and/or

• had suffered at least one relapse during the past 30 days (as defined by Polman) as this may affect physical activity/exercise participation.

Contacts and Locations

Locations

Sponsors and Collaborators

• McGill University

Investigators

• Principal Investigator: Nancy E Mayo, PhD, McGill University

Study Documents (Full-Text)

More Information

Additional Information:

• Multiple Sclerosis Society of Canada

Publications

• Asano M, Dawes DJ, Arafah A, Moriello C, Mayo NE. What does a structured review of the effectiveness of exercise interventions for persons with multiple sclerosis tell us about the challenges of designing trials? Mult Scler. 2009 Apr;15(4):412-21. doi: 10.1177/1352458508101877. Review. Erratum in: Mult Scler. 2016 Oct;22(11):NP4.
• Dalgas U, Stenager E, Ingemann-Hansen T. Multiple sclerosis and physical exercise: recommendations for the application of resistance-, endurance- and combined training. Mult Scler. 2008 Jan;14(1):35-53. Epub 2007 Sep 19. Review.
• Dalgas U, Stenager E, Jakobsen J, Petersen T, Hansen HJ, Knudsen C, Overgaard K, Ingemann-Hansen T. Resistance training improves muscle strength and functional capacity in multiple sclerosis. Neurology. 2009 Nov 3;73(18):1478-84. doi: 10.1212/WNL.0b013e3181bf98b4.
• Hayes HA, Gappmaier E, LaStayo PC. Effects of high-intensity resistance training on strength, mobility, balance, and fatigue in individuals with multiple sclerosis: a randomized controlled trial. J Neurol Phys Ther. 2011 Mar;35(1):2-10. doi: 10.1097/NPT.0b013e31820b5a9d.
• Mayo N. Setting the agenda for multiple sclerosis rehabilitation research. Mult Scler. 2008 Nov;14(9):1154-6. doi: 10.1177/1352458508096567.
• Motl RW, McAuley E, Snook EM. Physical activity and multiple sclerosis: a meta-analysis. Mult Scler. 2005 Aug;11(4):459-63.
• Motl RW, Snook EM, McAuley E, Gliottoni RC. Symptoms, self-efficacy, and physical activity among individuals with multiple sclerosis. Res Nurs Health. 2006 Dec;29(6):597-606.
• Poppe AY, Wolfson C, Zhu B. Prevalence of multiple sclerosis in Canada: a systematic review. Can J Neurol Sci. 2008 Nov;35(5):593-601.
• Rietberg MB, Brooks D, Uitdehaag BM, Kwakkel G. Exercise therapy for multiple sclerosis. Cochrane Database Syst Rev. 2005 Jan 25;(1):CD003980. Review.
• Turner AP, Kivlahan DR, Haselkorn JK. Exercise and quality of life among people with multiple sclerosis: looking beyond physical functioning to mental health and participation in life. Arch Phys Med Rehabil. 2009 Mar;90(3):420-8. doi: 10.1016/j.apmr.2008.09.558.
• Warren S, Warren KG, Svenson LW, Schopflocher DP, Jones A. Geographic and temporal distribution of mortality rates for multiple sclerosis in Canada, 1965-1994. Neuroepidemiology. 2003 Jan-Feb;22(1):75-81.
• Warren S, Warren KG. Prevalence, incidence, and characteristics of multiple sclerosis in Westlock County, Alberta, Canada. Neurology. 1993 Sep;43(9):1760-3.
• White LJ, Castellano V. Exercise and brain health--implications for multiple sclerosis: Part 1--neuronal growth factors. Sports Med. 2008;38(2):91-100. Review.
• White LJ, Castellano V. Exercise and brain health--implications for multiple sclerosis: Part II--immune factors and stress hormones. Sports Med. 2008;38(3):179-86. Review.