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Robotic Locomotor Training Leads to Cardiovascular Changes in Individuals With Incomplete Spinal Cord Injury Over a 24-Week Rehabilitation Period: A Randomized Controlled Pilot Study

Published:April 08, 2021DOI:https://doi.org/10.1016/j.apmr.2021.03.018

      Abstract

      Objective

      To describe the effect of robotic locomotor training (RLT) and activity-based training (ABT) on cardiovascular indices during various physiological positions in individuals with spinal cord injury.

      Design

      Randomized controlled pilot study.

      Setting

      Private practice: Therapy & Beyond Centre - Walking with Brandon Foundation, Sports Science Institute of South Africa, Cape Town, South Africa.

      Participants

      Participants with chronic traumatic motor incomplete tetraplegia (N=16) who resided in the Western Cape, South Africa.

      Intervention

      Robotic locomotor training (Ekso GT) and activity-based training over a 24-week intervention.

      Main Outcome Measures

      Brachial and ankle blood pressure, heart rate, heart rate variability, and cardiovascular efficiency during 4 physiological positions.

      Results

      No differences between groups or over time were evident in resting systolic and diastolic blood pressure, ankle systolic pressure, ankle brachial pressure index, and heart rate variability. Standing heart rate at 24 weeks was significantly higher in the ABT group (95.58±12.61 beats/min) compared with the RLT group (75.14±14.96 beats/min) (P=.05). In the RLT group, no significant changes in heart rate variability (standard deviation R-R interval and root mean square of successive differences) was found between the standing and 6-minute walk test physiological positions throughout the intervention. Cardiovascular efficiency in the RLT group during the 6-minute walk test improved from 11.1±2.6 at baseline to 7.5±2.8 beats per meter walked at 6 weeks and was maintained from 6 to 24 weeks.

      Conclusions

      Large effect sizes and significant differences between groups found in this pilot study support the clinical effectiveness of RLT and ABT for changing cardiovascular indices as early as 6 weeks and up to 24 weeks of rehabilitation. RLT may be more effective than ABT in improving cardiac responses to orthostatic stress. Based on heart rate variability metrics, the stimulus of standing has comparable effects to RLT on the parasympathetic nervous system. Cardiovascular efficiency of exoskeleton walking improved, particularly over the first 6 weeks. Both the RLT and ABT interventions were limited in their effect on brachial and ankle blood pressure. A randomized controlled trial with a larger sample size is warranted to further examine these findings.

      Keywords

      List of abbreviations:

      6MAT (6-minute arm ergometry test), 6MWT (6-minute walk test), ABPI (ankle brachial pressure index), ABT (activity-based training), ANOVA (analysis of variance), CV (coefficient of variation), ES (effect size), HRV (heart rate variability), RCT (randomized controlled trial), RLT (robotic locomotor training), RMSSD (root mean square of successive differences), SCI (spinal cord injury), SD RR (standard deviation of the R-R interval), THBI (Total Heart Beat Index)
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