An Anatomical-Based Subject-Specific Model of In-Vivo Knee Joint 3D Kinematics From Medical Imaging

Nardini, Fabrizio; Belvedere, Claudio; Sancisi, Nicola; Conconi, Michele; Leardini, Alberto; Durante, Stefano; Parenti‐Castelli, Vincenzo

doi:10.3390/app10062100

Cited by 27 publications

(26 citation statements)

References 43 publications

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“…However, such subject‐specific models are currently much more expensive and time‐consuming to produce relative to generic‐based or ‘averaged’ models and as such have rarely been used to this extent in any species. However, research into the validity of subject‐specific models of the human musculoskeletal system is becoming more widespread, as it is thought that such models may be more accurate for certain tasks than the often used generic or scaled generic models (Lenaerts et al ., 2008; Scheys et al ., 2008; Scheys et al ., 2009; Scheys et al ., 2011; Valente et al ., 2014; Navacchia et al ., 2016; Prinold et al ., 2016; Dejtiar et al ., 2020; Gu and Pandy, 2020; Modenese and Kohout, 2020; Nardini et al ., 2020). For example, models with subject‐specific musculoskeletal geometry have been shown to be more effective for predicting muscle moment arms and joint contact forces, with respective differences of 36% (Scheys et al ., 2008) and 0.61 xBW (Lenaerts et al ., 2008) relative to generic models.…”

Section: Introductionmentioning

confidence: 99%

Subject‐specific muscle properties from diffusion tensor imaging significantly improve the accuracy of musculoskeletal models

et al. 2020

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Musculoskeletal modelling is an important platform on which to study the biomechanics of morphological structures in vertebrates and is widely used in clinical, zoological and palaeontological fields. The popularity of this approach stems from the potential to non-invasively quantify biologically important but difficult-to-measure functional parameters. However, while it is known that model predictions are highly sensitive to input values, it is standard practice to build models by combining musculoskeletal data from different sources resulting in 'generic' models for a given species. At present, there are little quantitative data on how merging disparate anatomical

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Section: Introductionmentioning

confidence: 99%

Subject‐specific muscle properties from diffusion tensor imaging significantly improve the accuracy of musculoskeletal models

et al. 2020

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“…The approach was featured by its direct connection with anatomical structures (i.e., the ligaments and articular contacts) and capability to customize to individual subjects and replicate joint passive motion [15]. Recent studies have shown that the knee model based on a spatial parallel mechanism can be personalized by using personal medical images and 3D kinematics data [16,17]. Accurate representation of knee articular features has shown its potential to drive accurate 3D knee joint kinematics during non-weight-bearing knee flexion and extension motions with submillimeter and subdegree errors [17].…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of Three-Dimensional Tibiofemoral Kinematics Using Single-Plane Fluoroscopy and a Personalized Kinematic Model

Lin

et al. 2021

Applied Sciences

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Model-based 3D/2D image registration using single-plane fluoroscopy is a common setup to determine knee joint kinematics, owing to its markerless aspect. However, the approach was subjected to lower accuracies in the determination of out-of-plane motion components. Introducing additional kinematic constraints with an appropriate anatomical representation may help ameliorate the reduced accuracy of single-plane image registration. Therefore, this study aimed to develop and evaluate a multibody model-based tracking (MbMBT) scheme, embedding a personalized kinematic model of the tibiofemoral joint for the measurement of tibiofemoral kinematics. The kinematic model was consisted of three ligaments and an articular contact mechanism. The knee joint activities in six volunteers during isolated knee flexion, lunging, and sit-to-stand motions were recorded with a biplane X-ray imaging system. The tibiofemoral kinematics determined with the MbMBT and mediolateral view fluoroscopic images were compared against those determined using biplane fluoroscopic images. The MbMBT was demonstrated to yield tibiofemoral kinematics with precision values in the range from 0.1 mm to 1.1 mm for translations and from 0.2° to 1.3° for rotations. The constraints provided by the kinematic model were shown to effectively amend the nonphysiological tibiofemoral motion and not compromise the image registration accuracy with the proposed MbMBT scheme.

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“…However, regardless of the joint constraints imposed, generic (unpersonalized) model-derived kinematics were shown inaccurate (knee kinematic error up to 17° and 8 mm) as these models could not adapt to patient-specific geometry, particularly in pathological conditions (Clément et al, 2017). On the other hand, personalization of model geometry based on medical images was shown promising in improving joint kinematics accuracy (Assi et al, 2016; Clément et al, 2015; Nardini et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Development and evaluation of a new methodology for Soft Tissue Artifact compensation in the lower limb

Lahkar

Rohan

Assi

et al. 2021

Preprint

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Skin Marker (SM) based motion capture is the most widespread technique used for motion analysis. Yet, the accuracy is often hindered by Soft Tissue Artifact (STA). This is a major issue in clinical gait analysis where kinematic results are used for decision-making. It also has a considerable influence on the results of rigid body and Finite Element (FE) musculoskeletal models that rely on SM-based kinematics to estimate muscle, contact and ligament forces. Current techniques designed to compensate for STA, in particular multi-body optimization methods, assume anatomical simplifications to define joint constraints. These methods, however, cannot adapt to subjects bone morphology, particularly for patients with joint lesions, nor easily can account for subject- and location-dependent STA. In this perspective, we propose to develop a conceptual FE based model of the lower limb for STA compensation and evaluate it for 66 healthy subjects under level walking motor task. Both hip and knee joint kinematics were analyzed, considering both rotational and translational joint motion. Results showed that STA caused underestimation of the hip joint kinematics (up to 2.2 degree) for all rotational DoF, and overestimation of knee joint kinematics (up to 12 degree) except in flexion/extension. Joint kinematics, in particular the knee joint, appeared to be sensitive to soft tissue stiffness parameters (rotational and translational mean difference up to 1.5 degree and 3.4 mm). Analysis of the results using alternative joint representations highlighted the versatility of the proposed modeling approach. This work paves the way for using personalized models to compensate for STA in healthy subjects and different activities.

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An Anatomical-Based Subject-Specific Model of In-Vivo Knee Joint 3D Kinematics From Medical Imaging

Cited by 27 publications

References 43 publications

Subject‐specific muscle properties from diffusion tensor imaging significantly improve the accuracy of musculoskeletal models

Subject‐specific muscle properties from diffusion tensor imaging significantly improve the accuracy of musculoskeletal models

Reconstruction of Three-Dimensional Tibiofemoral Kinematics Using Single-Plane Fluoroscopy and a Personalized Kinematic Model

Development and evaluation of a new methodology for Soft Tissue Artifact compensation in the lower limb

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