Influence of selected modeling and computational issues on muscle force estimates

Blajer, Wojciech; Czaplicki, Adam; Dziewiecki, Krzysztof; Mazur, Zenon

doi:10.1007/s11044-010-9216-9

Cited by 36 publications

(41 citation statements)

References 33 publications

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“…2.2, a similar model ( Fig. 1) as the one used in [1] was created in the AnyBody modeling system 4.1 (AnyBody Technology A/S, Aalborg, Denmark). This software uses non-conventional musculoskeletal inverse dynamics with static optimization, in which the muscle forces are solved directly from body motion and external forces [3].…”

Section: Numerical Verificationmentioning

confidence: 99%

“…Recently, Blajer et al [1] published an interesting article concerning the influence of selected modeling and computational issues on muscle force estimates. This topic is important for users of biomechanical simulations because it can serve as an aid in the development of "best practice".…”

Section: Introductionmentioning

confidence: 99%

“…This topic is important for users of biomechanical simulations because it can serve as an aid in the development of "best practice". Using a planar arm model (comprising 2 segments, 2 joints and 8 muscles) Blajer et al [1] estimated the muscle forces by inverse dynamics and static optimization. They compared results due to differences in coordinate systems, muscle paths, muscle decomposition and muscle recruitment optimization criteria.…”

Section: Introductionmentioning

confidence: 99%

“…This behavior has not been noted in our own simulation work. But we also note that Blajer et al [1] used a polynomial criteria while we normally use a minmax criteria, both described in [2].…”

Section: Introductionmentioning

confidence: 99%

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Muscle decomposition and recruitment criteria influence muscle force estimates

Holmberg

Klarbring

2011

Multibody Syst Dyn

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Section: Numerical Verificationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Muscle decomposition and recruitment criteria influence muscle force estimates

Holmberg

Klarbring

2011

Multibody Syst Dyn

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“…However, the human body system is far more complex than the great majority of the multibody systems. Its components have a complex behavior due to deformations associated with the soft tissues such as the muscles, tendons, and ligaments, and due to complexity of the anatomical articulations relative to the standard mechanical joints [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Modeling of the condyle elements within a biomechanical knee model

et al. 2011

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The development of a computational multibody knee model able to capture some of the fundamental properties of the human knee articulation is presented. This desideratum is reached by including the kinetics of the real knee articulation. The research question is whether an accurate modeling of the condyle contact in the knee will lead to reproduction of the complex combination of flexion/extension, abduction/adduction, and tibial rotation observed in the real knee. The model is composed by two anatomic segments, the tibia and the femur, whose characteristics are functions of the geometric and anatomic properties of the real bones. The biomechanical model characterization is developed under the framework of multibody systems methodologies using Cartesian coordinates. The type of approach used in the proposed knee model is the joint surface contact conditions between ellipsoids, representing the two femoral condyles, and points, representing the tibial plateau and the menisci. These elements are closely fitted to the actual knee geometry. This task is undertaken by considering a parameter optimization process to replicate experimental data published in the literature, namely that by Lafortune and his coworkers in 1992. Then kinematic data in the form of flexion/extension patterns are imposed on the model corresponding to the stance phase of the human gait. From the results obtained, by performing several computational simulations, it can be observed that the knee model approximates the average secondary motion patterns observed in the literature. Because the literature reports considerable inter-individual differences in the secondary motion patterns, the knee model presented here is also used to check whether it is possible to reproduce the observed differences with reasonable variations of bone shape parameters. This task is accomplished by a parameter study, in which the main variables that define the geometry of condyles are taken into account. It was observed that the data reveal a difference in secondary kinematics of the knee in flexion versus extension. The likely explanation for this fact is the elastic component of the secondary motions created by the combination of joint forces and soft tissue deformations. The proposed knee model is, therefore, used to investigate whether this observed behavior can be explained by reasonable elastic deformations of the points representing the menisci in the model.

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Probabilistic Evaluation of Predicted Force Sensitivity to Muscle Attachment and Glenohumeral Stability Uncertainty

2014

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A major benefit of computational modeling in biomechanics research is its ability to estimate internal muscular demands given limited input information. However, several assumptions regarding model parameters and constraints may influence model outputs. This research evaluated the influence of model parameter variability, specifically muscle attachment locations and glenohumeral stability thresholds, on predicted rotator cuff muscle force during internal and external axial humeral rotation tasks. Additionally, relative sensitivity factors assessed which parameters were more contributory to output variability. Modest model parameter variation resulted in considerable variability in predicted force, with origin-insertion locations being particularly influential. Specifically, the scapula attachment site of the subscapularis muscle was important for modulating predicted force, with sensitivity factors ranging from α=0.2 to 0.7 in a neutral position. The largest variability in predicted forces was present for the subscapularis muscle, with average differences of 33.0±9.6% of normalized muscle force (1-99% CI), and a maximal difference of 51% in neutral exertions. Infraspinatus and supraspinatus muscles elicited maximal differences of 15.0 and 20.6%, respectively, between confidence limits. Overall, origin and insertion locations were most influential and thus incorporating geometric variation in the prediction of rotator cuff muscle forces may provide more representative population estimates.

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Influence of selected modeling and computational issues on muscle force estimates

Cited by 36 publications

References 33 publications

Muscle decomposition and recruitment criteria influence muscle force estimates

Muscle decomposition and recruitment criteria influence muscle force estimates

Modeling of the condyle elements within a biomechanical knee model

Probabilistic Evaluation of Predicted Force Sensitivity to Muscle Attachment and Glenohumeral Stability Uncertainty

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