Abstract
Cerebral palsy results from an upper motor neuron lesion and significantly affects skeletal muscle stiffness. The increased stiffness that occurs is partly a result of changes in the microstructural components of muscle. In particular, alterations in extracellular matrix, sarcomere length, fibre diameter, and fat content have been reported; however, experimental studies have shown wide variability in the degree of alteration. Many studies have reported changes in the extracellular matrix, while others have reported no differences. A consistent finding is increased sarcomere length in cerebral palsy affected muscle. Often many components are altered simultaneously, making it difficult to determine the individual effects on muscle stiffness. In this study, we use a three dimensional modelling approach to isolate individual effects of microstructural alterations typically occurring due to cerebral palsy on whole muscle behaviour; in particular, the effects of extracellular matrix volume fraction, stiffness, and sarcomere length. Causation between the changes to the microstructure and the overall muscle response is difficult to determine experimentally, since components of muscle cannot be manipulated individually; however, utilising a modelling approach allows greater control over each factor. We find that extracellular matrix volume fraction has the largest effect on whole muscle stiffness and mitigates effects from sarcomere length.
Highlights
Cerebral palsy (CP) results from an upper motor neuron lesion and has a significant effect on the musculoskeletal system
We found that the volume fraction of the extracellular matrix (ECM) had a larger influence on whole muscle stiffness compared to ECM stiffness and sarcomere length
The purpose of this study was to determine the effects of the microstructural changes that are normally observed during experimental studies of CP muscle, including variation in ECM volume fraction, stiffness, and sarcomere length, on whole muscle stiffness
Summary
Cerebral palsy (CP) results from an upper motor neuron lesion and has a significant effect on the musculoskeletal system. Contracture results in muscle that cannot be stretched through its typical range of motion due to an increase in stiffness, and this has substantial effects on the ability of muscle to generate force and reduces daily functioning This is observed in the upper and lower limb flexor muscles. CP will affect individuals differently, and the changes that can occur will vary depending on the location of the muscle and disease severity (de Bruin et al, 2014; Handsfield et al, 2016; Lieber and Fridén, 2019) This variability increases the difficulty in quantifying the amount and types of changes that occur as a result of CP. Despite the variability, alterations in the microstructural properties of Muscle Stiffness in Cerebral Palsy skeletal muscle are commonly observed (Tisha et al, 2019), which will have a significant effect on whole muscle behaviour, including force production and movement
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