Increased Femoral Anteversion Does Not Lead to Increased Joint Forces During Gait in a Cohort of Adolescent Patients

Alexander, Nathalie; Brunner, Reinald; Cip, Johannes; Viehweger, Elke; Pieri, Enrico De

doi:10.3389/fbioe.2022.914990

Cited by 10 publications

(13 citation statements)

References 77 publications

(104 reference statements)

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“…Heller et al [25] showed that increasing the AVA increases hip joint contact forces when tracking the same, subject-speci c motion capture data of four patients with a total hip arthroplasty, which was con rmed by recent simulation studies [26][27][28]. Increased hip and patellofemoral loading was found in children with increased AVA and normal foot progression angle [29], whereas decreased hip and knee loads were observed in children with increased AVA and internal foot progression angle compared to healthy control participants [30]. In summary, previous studies showed that increased AVA alters the moment arms of certain muscles and leads to increased hip and knee joint loads, which can be compensated with an altered gait pattern.…”

Section: Introductionmentioning

confidence: 76%

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Influence of femoral anteversion angle and neck-shaft angle on muscle forces and joint loading during walking

Kainz

Mindler

Kranzl

2023

Preprint

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Femoral deformities, e.g. increased or decreased femoral anteversion (AVA) and neck-shaft angle (NSA), can lead to pathological gait patterns, altered joint loads, and degenerative joint diseases. The mechanism how femoral geometry influences muscle forces and joint load during walking is still not fully understood. Hence, we conducted a comprehensive musculoskeletal modelling study to investigate the influence of femoral AVA and NSA on muscle forces and joint loads during walking. We created 25 musculoskeletal models with a variety of NSA and AVA. For each model we calculated moment arms, muscle forces, muscle moments, and joint loads based on motion capture data of a healthy person with a typical gait pattern. We found a significant increase in co-contraction of hip and knee joint spanning muscles in models with increasing AVA and NSA, which led to a substantial increase in hip and knee joint contact forces. Decreased AVA and NSA had a minor impact on muscle and joint contact forces. Neglecting an individual’s femoral geometry when estimating joint contact forces can lead to errors above five times body weight. Knowing the influence of femoral geometry on muscle forces and joint loads can help clinicians to improve treatment strategies in patients with femoral deformities.

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Section: Introductionmentioning

confidence: 76%

“…Neglecting the NSA or AVA, as previously done in some studies [27,30], might lead to errors up to a magnitude of ve times body weight and therefore could lead to mis-leading interpretations.…”

Section: Discussionmentioning

confidence: 99%

Influence of femoral anteversion angle and neck-shaft angle on muscle forces and joint loading during walking

Kainz

Mindler

Kranzl

2023

Preprint

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“…Deviations in sagittal knee moments in patients compared to controls can be used in CGA to infer quadriceps weaknesses, patellar pain, or quadriceps overload ( Armand et al, 2016 ; De Pieri et al, 2022c ). Furthermore, the knee adduction moment is often used as a surrogate measure for the load distribution between the medial and lateral compartments of the knee ( Holder et al, 2020 ; De Pieri et al, 2022b ), while reduced hip abduction moment in patients can be associated with a functional deficit of the hip abductors in the presence of altered femeral morphologies ( Thielen et al, 2019 ; Alexander et al, 2022 ; De Pieri et al, 2022a ). However, significant differences between the two methods in the computed sagittal and frontal moments for both knee and hip between the two methods suggest that this these metrics should be interpreted carefully while predicting GRF&Ms.…”

Section: Discussionmentioning

confidence: 99%

“…Personalized models for each subject were created from a detailed generic model of the lower limb ( De Pieri et al, 2018 ) based on a reference cadaveric dataset ( Carbone et al, 2015 ) and scaled to match the overall anthropometrics and marker data collected during the static standing reference trial ( Lund et al, 2015 ; Figure 1 ). The geometry of the femur was linearly morphed to include a transversal rotation between the proximal and distal sections, matching the subject’s femoral anteversion obtained from the clinical assessment ( De Pieri et al, 2021 ; Alexander et al, 2022 ). The hip joints were modeled as 3 degrees-of-freedom (DoFs) ball-and-socket joints, while the knee, talocrural, and subtalar joints were modeled as 1-DoF hinges.…”

Section: Methodsmentioning

confidence: 99%

Prediction of ground reaction forces and moments during walking in children with cerebral palsy

Kloeckner

Visscher

Taylor

et al. 2023

Front. Hum. Neurosci.

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IntroductionGait analysis is increasingly used to support clinical decision-making regarding diagnosis and treatment planning for movement disorders. As a key part of gait analysis, inverse dynamics can be applied to estimate internal loading conditions during movement, which is essential for understanding pathological gait patterns. The inverse dynamics calculation uses external kinetic information, normally collected using force plates. However, collection of external ground reaction forces (GRFs) and moments (GRMs) can be challenging, especially in subjects with movement disorders. In recent years, a musculoskeletal modeling-based approach has been developed to predict external kinetics from kinematic data, but its performance has not yet been evaluated for altered locomotor patterns such as toe-walking. Therefore, the goal of this study was to investigate how well this prediction method performs for gait in children with cerebral palsy.MethodsThe method was applied to 25 subjects with various forms of hemiplegic spastic locomotor patterns. Predicted GRFs and GRMs, in addition to associated joint kinetics derived using inverse dynamics, were statistically compared against those based on force plate measurements.ResultsThe results showed that the performance of the predictive method was similar for the affected and unaffected limbs, with Pearson correlation coefficients between predicted and measured GRFs of 0.71–0.96, similar to those previously reported for healthy adults, despite the motor pathology and the inclusion of toes-walkers within our cohort. However, errors were amplified when calculating the resulting joint moments to an extent that could influence clinical interpretation.ConclusionTo conclude, the musculoskeletal modeling-based approach for estimating external kinetics is promising for pathological gait, offering the possibility of estimating GRFs and GRMs without the need for force plate data. However, further development is needed before implementation within clinical settings becomes possible.

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“…Interestingly, these evaluations pertain to static, unloaded situations -which poorly correlate with gait parameters (3)while pain complaints often occur during dynamic activities. 3D gait analysis can likely provide relevant insights into aberrant lower extremity biomechanics and identify relevant compensations during walking, but these analyses have been limited to research settings (2)(3)(4)(5)(6)(7)(8)(9).…”

Section: Introductionmentioning

confidence: 99%

The effect of functional calibration methods on gait kinematics in adolescents with idiopathic rotational deformity of the femur

Boekesteijn¹,

Ven²,

Wilders³

et al. 2023

Preprint

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Background: Due to anatomical deviations, assumptions of the conventional calibration method for gait analysis may be violated in individuals with rotational deformities of the femur. We compared functional calibration methods with conventional methods in this group for 1) localization of the hip joint center (HJC) and knee axis orientation, and 2) gait kinematics. Methods: Twenty-four adolescents with idiopathic rotational deformity of the femur underwent gait analysis and a CT scan. During standing, distance between HJCs and knee axis orientation were compared between calibration methods, with CT serving as reference for HJC estimation. Gait kinematics were compared using statistical parameter mapping (SPM). Findings: Functional calibration methods estimated the HJC closer to the CT reference (26±21mm more lateral) than the conventional method (38±21mm more medial). In the full sample, orientation of the knee joint axis was not different between calibration methods, but in adolescents with increased femoral anteversion, the knee was more internally rotated with the functional method (3.3±6.2°). During gait, SPM revealed significantly more hip flexion, more internal hip rotation during the stance phase, less knee varus-valgus motion, and larger knee flexion angles when applying the functional calibration method. Interpretation: Functional calibration methods better approximated the HJC, and showed a knee axis orientation that was more towards the direction of the deformity. This resulted in less knee joint angle crosstalk during gait. Although differences between calibration methods on gait kinematics were within clinically acceptable limits for the sagittal plane, relatively larger differences on transversal hip kinematics may hold clinical importance.

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Increased Femoral Anteversion Does Not Lead to Increased Joint Forces During Gait in a Cohort of Adolescent Patients

Cited by 10 publications

References 77 publications

Influence of femoral anteversion angle and neck-shaft angle on muscle forces and joint loading during walking

Influence of femoral anteversion angle and neck-shaft angle on muscle forces and joint loading during walking

Prediction of ground reaction forces and moments during walking in children with cerebral palsy

The effect of functional calibration methods on gait kinematics in adolescents with idiopathic rotational deformity of the femur

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