Using artificial neural networks to predict impingement and dislocation in total hip arthroplasty

Alastruey-López, Diego; Ezquerra, Laura; Seral, B.; Pérez, M.Á.

doi:10.1080/10255842.2020.1757661

Cited by 6 publications

(6 citation statements)

References 40 publications

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“…Villamor et al [ 28 ] made comparisons between Support Vector Machine (SVM), Logistic Regression, Shallow Neural Networks, and Random Forest ML methods to determine the best-performing model to predict osteoporotic hip fracture in postmenopausal women based on FE analyses. Alastruey-López et al [ 29 ] used Artificial Neural Networks (ANN) and a parametric FE simulation to predict impingement and dislocation in total hip arthroplasty. Their efforts were aimed at identifying the optimal prosthesis design to reduce the probability of dislocation.…”

Section: Introductionmentioning

confidence: 99%

A Machine-Learning-Based Approach for Predicting Mechanical Performance of Semi-Porous Hip Stems

Akkad

Mehboob

Alyamani

et al. 2023

JFB

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Novel designs of porous and semi-porous hip stems attempt to alleviate complications such as aseptic loosening, stress shielding, and eventual implant failure. Various designs of hip stems are modeled to simulate biomechanical performance using finite element analysis; however, these models are computationally expensive. Therefore, the machine learning approach is incorporated with simulated data to predict the new biomechanical performance of new designs of hip stems. Six types of algorithms based on machine learning were employed to validate the simulated results of finite element analysis. Afterwards, new designs of semi-porous stems with outer dense layers of 2.5 and 3 mm and porosities of 10–80% were used to predict the stiffness of the stems, stresses in outer dense layers, stresses in porous sections, and factor of safety under physiological loads using machine learning algorithms. It was determined that decision tree regression is the top-performing machine learning algorithm as per the used simulation data in terms of the validation mean absolute percentage error which equals 19.62%. It was also found that ridge regression produces the most consistent test set trend as compared with the original simulated finite element analysis results despite relying on a relatively small data set. These predicted results employing trained algorithms provided the understanding that changing the design parameters of semi-porous stems affects the biomechanical performance without carrying out finite element analysis.

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Section: Introductionmentioning

confidence: 99%

A Machine-Learning-Based Approach for Predicting Mechanical Performance of Semi-Porous Hip Stems

Akkad

Mehboob

Alyamani

et al. 2023

JFB

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“…Impingement, and a corresponding increased risk of joint subluxation, is a further potential cause of implant failure heavily influenced by joint kinematics. Geometry based models, or 3D parametric finite element models, of the implant and bone have been used to evaluate the impingement-free range of motion (ROM) of THA ( Alastruey-Lopez et al, 2020 ; Pryce et al, 2022 ). Such simulations have provided ROM-to-impingement curves for challenging high flexion and pivot activities ( McCarthy et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Moving fluoroscopy-based analysis of THA kinematics during unrestricted activities of daily living

D'Isidoro

Brockmann

Friesenbichler

et al. 2023

Front. Bioeng. Biotechnol.

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Introduction: Knowledge of the accurate in-vivo kinematics of total hip arthroplasty (THA) during activities of daily living can potentially improve the in-vitro or computational wear and impingement prediction of hip implants. Fluoroscopy- based techniques provide more accurate kinematics compared to skin marker-based motion capture, which is affected by the soft tissue artefact. To date, stationary fluoroscopic machines allowed the measurement of only restricted movements, or only a portion of the whole motion cycle.Methods: In this study, a moving fluoroscopic robot was used to measure the hip joint motion of 15 THA subjects during whole cycles of unrestricted activities of daily living, i.e., overground gait, stair descent, chair rise and putting on socks.Results: The retrieved hip joint motions differed from the standard patterns applied for wear testing, demonstrating that current pre-clinical wear testing procedures do not reflect the experienced in-vivo daily motions of THA.Discussion: The measured patient-specific kinematics may be used as input to in vitro and computational simulations, in order to investigate how individual motion patterns affect the predicted wear or impingement.

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“…In order to personalise the positioning of implants regarding both the patient's anatomy and pelvic kinematics, several authors have proposed biomechanical models or finite element studies, based on Computerised Tomography (CT) and X‐ray images 16–19 . Nonetheless, all these methods require a significant amount of computation and engineering work for modelling and simulations, and are not therefore easy to integrate in the clinical routine.…”

Section: Introductionmentioning

confidence: 99%

“…15 In order to personalise the positioning of implants regarding both the patient's anatomy and pelvic kinematics, several authors have proposed biomechanical models or finite element studies, based on Computerised Tomography (CT) and X-ray images. [16][17][18][19] Nonetheless,…”

Section: Introductionmentioning

confidence: 99%

Functional safe zone for THA considering the patient‐specific pelvic tilts: An ultrasound‐based approach

Guezou-Philippe

Clavé

Marchadour

et al. 2022

Robotics Computer Surgery

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The usual Lewinnek orientation for cup positioning in total hip arthroplasty is not suitable for all patients as it does not consider the patient mobility. We propose an ultrasound‐based approach to compute a Functional Safe Zone (FSZ) considering daily positions. Our goal was to validate it, and to evaluate how the input parameters impact the FSZ size and barycentre. The accuracy of the FSZ was first assessed by comparing the FSZ computed by the proposed approach and the true FSZ determined by 3D modelling. Then, the input parameters' impact on the FSZ was studied using a principal component analysis. The FSZ was estimated with errors below 0.5° for mean anteversion, mean inclination, and at edges. The pelvic tilts and the neck orientation were found correlated to the FSZ mean orientation, and the target ROM and the prosthesis dimensions to the FSZ size. Integrated into the clinical workflow, this non‐ionising approach can be used to easily determine an optimal patient‐specific cup orientation minimising the risks of dislocation.

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Using artificial neural networks to predict impingement and dislocation in total hip arthroplasty

Cited by 6 publications

References 40 publications

A Machine-Learning-Based Approach for Predicting Mechanical Performance of Semi-Porous Hip Stems

A Machine-Learning-Based Approach for Predicting Mechanical Performance of Semi-Porous Hip Stems

Moving fluoroscopy-based analysis of THA kinematics during unrestricted activities of daily living

Functional safe zone for THA considering the patient‐specific pelvic tilts: An ultrasound‐based approach

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