OBJECTIVE: To compare 3 different methods of measuring plantarflexor stiffness in children with spastic diplegia cerebral palsy (CP) and children without disability. DESIGN: Case-control study. SETTING: Human performance laboratory. PARTICIPANTS: A retrospective analysis was conducted with children with spastic diplegia (n=121; mean age, 8.4y) and children with typical development (TD) (n=48; mean age, 9.7y). INTERVENTIONS: Not applicable. MAIN OUTCOME MEASURES: An isokinetic dynamometer was used to measure ankle plantarflexor stiffness at 10°/s using 3 methods: (1) end-range method, which applied a linear slope to the end of the torque-angle curve; (2) set-range method, which applied a linear slope from 30° to 10° plantarflexion; and (3) a linear method, which applied a slope only to the linear portion of the curve. RESULTS: Two-way analysis of variance revealed significant main effects for group and stiffness method. The end-range method showed no significant difference between groups for plantarflexor stiffness (P=.62), the set-range method showed the CP group with 120% greater stiffness than the TD group (P<.046), and the linear method showed the CP group with 35% greater stiffness than the TD group (P<.001). CONCLUSIONS: The linear method appeared to resolve the issues with the previous methods; applying a linear slope to a nonlinear curve or applying a linear slope to the same range of motion for each child regardless of their range limitations. It is clear that children with CP have limited range of motion; therefore, stiffness occurs earlier in the range than would be expected for a typically developing child. Using the linear method, children with CP were 35% stiffer in the ankle plantarflexors than typically developing peers.
OBJECTIVE: To compare 3 different methods of measuring plantarflexor stiffness in children with spastic diplegia cerebral palsy (CP) and children without disability. DESIGN: Case-control study. SETTING:Human performance laboratory. PARTICIPANTS: A retrospective analysis was conducted with children with spastic diplegia (n=121; mean age, 8.4y) and children with typical development (TD) (n=48; mean age, 9.7y). INTERVENTIONS: Not applicable. MAIN OUTCOME MEASURES: An isokinetic dynamometer was used to measure ankle plantarflexor stiffness at 10°/s using 3 methods: (1) end-range method, which applied a linear slope to the end of the torque-angle curve; (2) set-range method, which applied a linear slope from 30° to 10° plantarflexion; and (3) a linear method, which applied a slope only to the linear portion of the curve. RESULTS: Two-way analysis of variance revealed significant main effects for group and stiffness method. The end-range method showed no significant difference between groups for plantarflexor stiffness (P=.62), the set-range method showed the CP group with 120% greater stiffness than the TD group (P<.046), and the linear method showed the CP group with 35% greater stiffness than the TD group (P<.001). CONCLUSIONS: The linear method appeared to resolve the issues with the previous methods; applying a linear slope to a nonlinear curve or applying a linear slope to the same range of motion for each child regardless of their range limitations. It is clear that children with CP have limited range of motion; therefore, stiffness occurs earlier in the range than would be expected for a typically developing child. Using the linear method, children with CP were 35% stiffer in the ankle plantarflexors than typically developing peers.
Authors: Jared R H Foran; Suzanne Steinman; Ilona Barash; Henry G Chambers; Richard L Lieber Journal: Dev Med Child Neurol Date: 2005-10 Impact factor: 5.449
Authors: Mark J C Smeulders; Michiel Kreulen; J Joris Hage; Peter A Huijing; Chantal M A M van der Horst Journal: J Orthop Res Date: 2004-11 Impact factor: 3.494
Authors: Ferdinand von Walden; Kian Jalaleddini; Björn Evertsson; Johanna Friberg; Francisco J Valero-Cuevas; Eva Pontén Journal: Front Comput Neurosci Date: 2017-04-25 Impact factor: 2.380