Machine learning for forecasting the biomechanical behavior of orthopedic bone plates fabricated by fused deposition modeling

IF 3.4 4区 工程技术 Q1 ENGINEERING, MECHANICAL
Shrutika Sharma, Vishal Gupta, D. Mudgal, Vishal Srivastava
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引用次数: 0

Abstract

Purpose Three-dimensional (3D) printing is highly dependent on printing process parameters for achieving high mechanical strength. It is a time-consuming and expensive operation to experiment with different printing settings. The current study aims to propose a regression-based machine learning model to predict the mechanical behavior of ulna bone plates. Design/methodology/approach The bone plates were formed using fused deposition modeling (FDM) technique, with printing attributes being varied. The machine learning models such as linear regression, AdaBoost regression, gradient boosting regression (GBR), random forest, decision trees and k-nearest neighbors were trained for predicting tensile strength and flexural strength. Model performance was assessed using root mean square error (RMSE), coefficient of determination (R2) and mean absolute error (MAE). Findings Traditional experimentation with various settings is both time-consuming and expensive, emphasizing the need for alternative approaches. Among the models tested, GBR model demonstrated the best performance in predicting both tensile and flexural strength and achieved the lowest RMSE, highest R2 and lowest MAE, which are 1.4778 ± 0.4336 MPa, 0.9213 ± 0.0589 and 1.2555 ± 0.3799 MPa, respectively, and 3.0337 ± 0.3725 MPa, 0.9269 ± 0.0293 and 2.3815 ± 0.2915 MPa, respectively. The findings open up opportunities for doctors and surgeons to use GBR as a reliable tool for fabricating patient-specific bone plates, without the need for extensive trial experiments. Research limitations/implications The current study is limited to the usage of a few models. Other machine learning-based models can be used for prediction-based study. Originality/value This study uses machine learning to predict the mechanical properties of FDM-based distal ulna bone plate, replacing traditional design of experiments methods with machine learning to streamline the production of orthopedic implants. It helps medical professionals, such as physicians and surgeons, make informed decisions when fabricating customized bone plates for their patients while reducing the need for time-consuming experimentation, thereby addressing a common limitation of 3D printing medical implants.
利用机器学习预测通过熔融沉积模型制造的矫形骨板的生物力学行为
目的 三维(3D)打印要达到较高的机械强度,在很大程度上取决于打印工艺参数。试验不同的打印设置既费时又费钱。本研究旨在提出一种基于回归的机器学习模型来预测尺骨骨板的机械性能。 设计/方法/途径 采用熔融沉积建模(FDM)技术制作骨板,并改变打印属性。训练了线性回归、AdaBoost 回归、梯度提升回归(GBR)、随机森林、决策树和 k 近邻等机器学习模型,用于预测抗拉强度和抗弯强度。使用均方根误差 (RMSE)、判定系数 (R2) 和平均绝对误差 (MAE) 评估模型性能。 研究结果 传统的各种设置实验既费时又费钱,因此需要采用替代方法。在所测试的模型中,GBR 模型在预测拉伸和弯曲强度方面表现最佳,实现了最低的 RMSE、最高的 R2 和最低的 MAE,分别为 1.4778 ± 0.4336 MPa、0.9213 ± 0.0589 和 1.2555 ± 0.3799 MPa,以及 3.0337 ± 0.3725 MPa、0.9269 ± 0.0293 和 2.3815 ± 0.2915 MPa。这些研究结果为医生和外科医生提供了使用 GBR 的机会,使其成为制作患者特异性骨板的可靠工具,而无需进行大量试验。 研究局限性/意义 目前的研究仅限于几个模型的使用。其他基于机器学习的模型也可用于基于预测的研究。 原创性/价值 本研究利用机器学习预测了基于 FDM 的尺骨远端骨板的机械性能,用机器学习取代了传统的实验设计方法,从而简化了骨科植入物的生产。它有助于内科医生和外科医生等医疗专业人士在为患者制作定制骨板时做出明智的决策,同时减少了耗时的实验,从而解决了 3D 打印医疗植入物的一个常见限制。
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来源期刊
Rapid Prototyping Journal
Rapid Prototyping Journal 工程技术-材料科学:综合
CiteScore
8.30
自引率
10.30%
发文量
137
审稿时长
4.6 months
期刊介绍: Rapid Prototyping Journal concentrates on development in a manufacturing environment but covers applications in other areas, such as medicine and construction. All papers published in this field are scattered over a wide range of international publications, none of which actually specializes in this particular discipline, this journal is a vital resource for anyone involved in additive manufacturing. It draws together important refereed papers on all aspects of AM from distinguished sources all over the world, to give a truly international perspective on this dynamic and exciting area. -Benchmarking – certification and qualification in AM- Mass customisation in AM- Design for AM- Materials aspects- Reviews of processes/applications- CAD and other software aspects- Enhancement of existing processes- Integration with design process- Management implications- New AM processes- Novel applications of AM parts- AM for tooling- Medical applications- Reverse engineering in relation to AM- Additive & Subtractive hybrid manufacturing- Industrialisation
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