Enhancing Neuroplasticity in the Chronic Phase After Stroke: Effects of a Soft Robotic Exosuit on Training Intensity and Brain-Derived Neurotrophic Factor
Anna V. Roto Cataldo, Ashley N. Collimore, Johanna Spangler, Lillian Ribeirinha-Braga, Karen J. Hutchinson, Qing Mei Wang, LaDora V. Thompson, Louis N. Awad
- 发表年份
- 2023
- 引用次数
- 4
- 访问权限
- 开放获取
摘要
: High intensity training may enhance neuroplasticity after stroke; however, gait deficits limit the ability to achieve and sustain high walking training intensities. We hypothesize that soft robotic exosuits can facilitate speed-based gait training at higher intensities and longer durations, resulting in a corresponding increase in circulating brain-derived neurotrophic factor (BDNF). Results: Eleven individuals >6-mo poststroke completed a two-session, pilot randomized crossover trial (NCT05138016). Maximum training speed (Δ: 0.07±0.03 m/s), duration (Δ: 2.07±0.88 min), and intensity (VO2 peak, Δ: 1.75±0.60 ml-O2/kg/min) significantly increased (p<0.05) during exosuit-augmented training compared to no-exosuit training. Post-session increases in BDNF (Δ: 5.96±2.27 ng/ml, p=0.03) were observed only after exosuit-augmented training. Biomechanical changes were not observed after exosuit-augmented training; however, a deterioration in gait propulsion symmetry (%Δ: -5±2 %) and an increase in nonparetic propulsion (Δ: 0.9±0.3 %bw) were observed (p<0.05) after no-exosuit training. Conclusion: Soft robotic exosuits facilitate faster, longer duration, and higher intensity walking training associated with enhanced neuroplasticity.
关键词
相关论文
The Organization of Behavior
D. O. Hebb
2005
The spread of true and false news online
Soroush Vosoughi, Deb Roy, Sinan Aral
2018
On seeing human: A three-factor theory of anthropomorphism.
Nicholas Epley, Adam Waytz, John T. Cacioppo
2007
Robots and Jobs: Evidence from US Labor Markets
Daron Acemoğlu, Pascual Restrepo
2019