James B Tracy1, Drew A Petersen2, Jamie Pigman1, Benjamin C Conner3, Henry G Wright1, Christopher M Modlesky4, Freeman Miller5, Curtis L Johnson6, Jeremy R Crenshaw7. 1. 540 S College Ave, Department of Kinesiology and Applied Physiology, University of Delaware, Newark, DE, USA. 2. 245 North 15th Street, MS 502, Department of Physical Therapy, Drexel University, Philadelphia, PA, USA. 3. 550 E Van Buren St, College of Medicine - Phoenix, University of Arizona, Phoenix, AZ, USA. 4. 330 River Rd, Department of Kinesiology, University of Georgia, Athens, GA, USA. 5. 540 S College Ave, Department of Kinesiology and Applied Physiology, University of Delaware, Newark, DE, USA; 1600 Rockland Rd, Department of Orthopedics, Nemours A.I. DuPont Hospital for Children, Wilmington, DE, USA. 6. 150 Academy Street, Department of Biomedical Engineering, University of Delaware, Newark, DE, USA. 7. 540 S College Ave, Department of Kinesiology and Applied Physiology, University of Delaware, Newark, DE, USA. Electronic address: crenshaw@udel.edu.
Abstract
BACKGROUND: Cerebral palsy (CP) is associated with a high risk of falling during walking. Many gait abnormalities associated with CP likely alter foot placement and center of mass (CoM) movement in a way that affects anterior or lateral dynamic stability, in turn influencing fall risk. RESEARCH QUESTION: Do children with CP demonstrate altered anterior or lateral dynamic stability compared to typically-developing (TD) children? METHODS: In this case-control, observational study, we measured gait kinematics of two groups of children (15 CP, 11 GMFCS level I, 4 GMFCS level II; 14 TD; age 5-12) in walking conditions of a preferred speed, a fast speed, and a preferred speed while completing a cognitive task. For dominant and non-dominant limbs, the margin of stability (MoS), a spatial measure of dynamic stability, was calculated as the distance between the edge of the base of support and the CoM position after accounting for scaled velocity. Statistical comparisons of were made using mixed factorial ANOVAs. Post hoc comparisons were Sidak adjusted. RESULTS: The anterior MoS before foot strike and at mid-swing differed between each condition but not between groups. Based on the minimum lateral MoS, children with CP had more stability when bearing weight on their non-dominant limb compared to TD children. These differences were not apparent when on the dominant limb. SIGNIFICANCE: This high-functioning group of children with CP exhibited a more conservative lateral stability strategy during walking when bearing weight with the non-dominant limb. This strategy may be protective against lateral falls. We observed no between-group differences in anterior stability. Because CP has been previously associated with impaired anterior balance reactions, and there was no observed compensation in anterior gait stability, this lack of group differences could contribute to a higher risk of falling in that direction.
BACKGROUND:Cerebral palsy (CP) is associated with a high risk of falling during walking. Many gait abnormalities associated with CP likely alter foot placement and center of mass (CoM) movement in a way that affects anterior or lateral dynamic stability, in turn influencing fall risk. RESEARCH QUESTION: Do children with CP demonstrate altered anterior or lateral dynamic stability compared to typically-developing (TD) children? METHODS: In this case-control, observational study, we measured gait kinematics of two groups of children (15 CP, 11 GMFCS level I, 4 GMFCS level II; 14 TD; age 5-12) in walking conditions of a preferred speed, a fast speed, and a preferred speed while completing a cognitive task. For dominant and non-dominant limbs, the margin of stability (MoS), a spatial measure of dynamic stability, was calculated as the distance between the edge of the base of support and the CoM position after accounting for scaled velocity. Statistical comparisons of were made using mixed factorial ANOVAs. Post hoc comparisons were Sidak adjusted. RESULTS: The anterior MoS before foot strike and at mid-swing differed between each condition but not between groups. Based on the minimum lateral MoS, children with CP had more stability when bearing weight on their non-dominant limb compared to TD children. These differences were not apparent when on the dominant limb. SIGNIFICANCE: This high-functioning group of children with CP exhibited a more conservative lateral stability strategy during walking when bearing weight with the non-dominant limb. This strategy may be protective against lateral falls. We observed no between-group differences in anterior stability. Because CP has been previously associated with impaired anterior balance reactions, and there was no observed compensation in anterior gait stability, this lack of group differences could contribute to a higher risk of falling in that direction.
Authors: Prudence Plummer-D'Amato; Lori J P Altmann; Dawn Saracino; Emily Fox; Andrea L Behrman; Michael Marsiske Journal: Gait Posture Date: 2007-10-22 Impact factor: 2.840
Authors: Jeremy R Crenshaw; Drew A Petersen; Benjamin C Conner; James B Tracy; Jamie Pigman; Henry G Wright; Freeman Miller; Curtis L Johnson; Christopher M Modlesky Journal: Dev Med Child Neurol Date: 2020-03-02 Impact factor: 5.449
Authors: James B Tracy; Drew A Petersen; Benjamin C Conner; Justus G Matteson; De'Shjuan G Triplett; Henry G Wright; Christopher M Modlesky; Freeman Miller; Curtis L Johnson; Jeremy R Crenshaw Journal: Gait Posture Date: 2021-01-07 Impact factor: 2.840
Authors: Sophie Wist; Lena Carcreff; Sjoerd M Bruijn; Gilles Allali; Christopher J Newman; Joel Fluss; Stéphane Armand Journal: PLoS One Date: 2022-06-22 Impact factor: 3.752