Dmitrijs Celinskis1, Mark D Grabiner2, Claire F Honeycutt3. 1. School of Biological and Health Systems Engineering, Arizona State University, USA. 2. Department of Kinesiology and Nutrition, University of Illinois at Chicago, USA. 3. School of Biological and Health Systems Engineering, Arizona State University, USA. Electronic address: Claire.Honeycutt@asu.edu.
Abstract
OBJECTIVE: Falls are the most common and expensive medical complication following stroke. Hypermetric reflexes have been suggested to impact post-stroke balance but no study has evaluated reflex amplitudes under real conditions of falls in this population. Our objective was to quantify the early reflexive responses during falls induced in the laboratory. METHODS: Sixteen stroke survivors were exposed to posteriorly directed treadmill perturbations that required a forward step to maintain a balance. Perturbations differed in terms of treadmill translation displacement, velocity, and acceleration. EMG amplitudes were compared between Fall/Recovery trials, as well as Fallers/Non-Fallers at two different time windows: 50-75 and 75-100 ms. RESULTS: Sixteen of 86 trials resulted in falls by nine subjects (Fallers). While no differences were found between 50 and 75 ms, EMG amplitude in the paretic rectus femoris muscle was larger between 75 and 100 ms during Fall trials. Further, a bilateral increase in RF activity was seen in Fallers but not Non-Fallers. Interestingly, the bilateral increase was related to perturbation intensity (larger EMG activity with larger perturbations) in Fallers, but again not in Non-Fallers. CONCLUSIONS: Heightened early recovery hip flexor activity between 75 and 100 ms is associated with falls and Fallers post-stroke. SIGNIFICANCE: Though requiring replication and expanded subject pools, these preliminary results reflect a possible clinically meaningful relationship between heightened reflexive responses and fall risk. Future work should evaluate the underlying mechanisms driving these heightened reflexes (e.g. stretch, startle) such that future rehabilitation techniques can address this abnormal response.
OBJECTIVE: Falls are the most common and expensive medical complication following stroke. Hypermetric reflexes have been suggested to impact post-stroke balance but no study has evaluated reflex amplitudes under real conditions of falls in this population. Our objective was to quantify the early reflexive responses during falls induced in the laboratory. METHODS: Sixteen stroke survivors were exposed to posteriorly directed treadmill perturbations that required a forward step to maintain a balance. Perturbations differed in terms of treadmill translation displacement, velocity, and acceleration. EMG amplitudes were compared between Fall/Recovery trials, as well as Fallers/Non-Fallers at two different time windows: 50-75 and 75-100 ms. RESULTS: Sixteen of 86 trials resulted in falls by nine subjects (Fallers). While no differences were found between 50 and 75 ms, EMG amplitude in the paretic rectus femoris muscle was larger between 75 and 100 ms during Fall trials. Further, a bilateral increase in RF activity was seen in Fallers but not Non-Fallers. Interestingly, the bilateral increase was related to perturbation intensity (larger EMG activity with larger perturbations) in Fallers, but again not in Non-Fallers. CONCLUSIONS: Heightened early recovery hip flexor activity between 75 and 100 ms is associated with falls and Fallers post-stroke. SIGNIFICANCE: Though requiring replication and expanded subject pools, these preliminary results reflect a possible clinically meaningful relationship between heightened reflexive responses and fall risk. Future work should evaluate the underlying mechanisms driving these heightened reflexes (e.g. stretch, startle) such that future rehabilitation techniques can address this abnormal response.
Authors: Disa K Sommerfeld; Elsy U-B Eek; Anna-Karin Svensson; Lotta Widén Holmqvist; Magnus H von Arbin Journal: Stroke Date: 2003-12-18 Impact factor: 7.914
Authors: Jamie Pigman; Darcy S Reisman; Ryan T Pohlig; John J Jeka; Tamara R Wright; Benjamin C Conner; Drew A Petersen; Michael S Christensen; Jeremy R Crenshaw Journal: Clin Biomech (Bristol, Avon) Date: 2020-12-23 Impact factor: 2.063