Nicola Theis1, Amir A Mohagheghi2, Thomas Korff3. 1. School of Sport, Health and Applied Science, St Mary׳s University, Strawberry Hill, Middlesex, TW12 4SX, UK. 2. Centre for Human Performance and Clinical Rehabilitation, Brunel University, Kingston Lane, Uxbridge, Middlesex, UB8 3PH, UK; University of Social Welfare and Rehabilitation Sciences, Tehran, Iran. 3. Centre for Human Performance and Clinical Rehabilitation, Brunel University, Kingston Lane, Uxbridge, Middlesex, UB8 3PH, UK. Electronic address: Thomas.korff@brunel.ac.uk.
Abstract
BACKGROUND: Children with spastic cerebral palsy (CP) experience secondary musculoskeletal adaptations, affecting the mechanical and material properties of muscles and tendons. CP-related changes in the spastic muscle are well documented whilst less is known about the tendon. From a clinical perspective, it is important to understand alterations in tendon properties in order to tailor interventions or interpret clinical tests more appropriately. The main purpose of this study was to compare the mechanical and material properties of the Achilles tendon in children with cerebral palsy to those of typically developing children. METHODS: Using a combination of ultrasonography and motion analysis, we determined tendon mechanical properties in ten children with spastic cerebral palsy and ten aged-matched typically developing children. Specifically, we quantified muscle and tendon stiffness, tendon slack length, tendon strain, cross-sectional area, Young׳s Modulus and the strain rate dependence of tendon stiffness. FINDINGS: Children with CP had a greater muscle to tendon stiffness ratio compared to typically developing children. Despite a smaller tendon cross-sectional area and greater tendon slack length, no group differences were observed in tendon stiffness or Young׳s Modulus. The slope describing the stiffness strain-rate response was steeper in children with cerebral palsy. INTERPRETATION: These results provide us with a more differentiated understanding of the muscle and tendon mechanical properties, which would be relevant for future research and paediatric clinicians.
BACKGROUND:Children with spastic cerebral palsy (CP) experience secondary musculoskeletal adaptations, affecting the mechanical and material properties of muscles and tendons. CP-related changes in the spastic muscle are well documented whilst less is known about the tendon. From a clinical perspective, it is important to understand alterations in tendon properties in order to tailor interventions or interpret clinical tests more appropriately. The main purpose of this study was to compare the mechanical and material properties of the Achilles tendon in children with cerebral palsy to those of typically developing children. METHODS: Using a combination of ultrasonography and motion analysis, we determined tendon mechanical properties in ten children with spastic cerebral palsy and ten aged-matched typically developing children. Specifically, we quantified muscle and tendon stiffness, tendon slack length, tendon strain, cross-sectional area, Young׳s Modulus and the strain rate dependence of tendon stiffness. FINDINGS:Children with CP had a greater muscle to tendon stiffness ratio compared to typically developing children. Despite a smaller tendon cross-sectional area and greater tendon slack length, no group differences were observed in tendon stiffness or Young׳s Modulus. The slope describing the stiffness strain-rate response was steeper in children with cerebral palsy. INTERPRETATION: These results provide us with a more differentiated understanding of the muscle and tendon mechanical properties, which would be relevant for future research and paediatric clinicians.
Authors: Jennifer M Ryan; Nicola Theis; Cherry Kilbride; Vasilios Baltzopoulos; Charlie Waugh; Adam Shortland; Grace Lavelle; Marika Noorkoiv; Wendy Levin; Thomas Korff Journal: BMJ Open Date: 2016-10-04 Impact factor: 2.692
Authors: Ruoli Wang; Shiyang Yan; Marius Schlippe; Olga Tarassova; Gaia Valentina Pennati; Frida Lindberg; Clara Körting; Antea Destro; Luming Yang; Bin Shi; Anton Arndt Journal: Biomed Res Int Date: 2021-02-09 Impact factor: 3.411