Machine Learning Enabled Design and Optimization for 3D‐Printing of High‐Fidelity Presurgical Organ Models

Eric S. Chen, Alaleh Ahmadianshalchi, Sonja S. Sparks, Chuchu Chen, Aryan Deshwal, Janardhan R. Doppa, Kaiyan Qiu
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Abstract

The development of a general‐purpose machine learning algorithm capable of quickly identifying optimal 3D‐printing settings can save manufacturing time and cost, reduce labor intensity, and improve the quality of 3D‐printed objects. Existing methods have limitations which focus on overall performance or one specific aspect of 3D‐printing quality. Here, for addressing the limitations, a multi‐objective Bayesian Optimization (BO) approach which uses a general‐purpose algorithm to optimize the black‐box functions is demonstrated and identifies the optimal input parameters of direct ink writing for 3D‐printing different presurgical organ models with intricate geometry. The BO approach enhances the 3D‐printing efficiency to achieve the best possible printed object quality while simultaneously addressing the inherent trade‐offs from the process of pursuing ideal outcomes relevant to requirements from practitioners. The BO approach also enables us to effectively explore 3D‐printing inputs inclusive of layer height, nozzle travel speed, and dispensing pressure, as well as visualize the trade‐offs between each set of 3D‐printing inputs in terms of the output objectives which consist of time, porosity, and geometry precisions through the Pareto front.

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机器学习支持高保真术前器官模型 3D 打印的设计与优化
开发一种能够快速确定最佳三维打印设置的通用机器学习算法,可以节省制造时间和成本,降低劳动强度,并提高三维打印对象的质量。现有的方法存在局限性,主要集中在整体性能或三维打印质量的一个特定方面。为了解决这些局限性,本文展示了一种多目标贝叶斯优化(BO)方法,该方法使用通用算法来优化黑盒函数,并确定了直接写墨的最佳输入参数,用于三维打印具有复杂几何形状的不同术前器官模型。BO方法提高了三维打印效率,实现了最佳打印对象质量,同时解决了在追求与从业人员要求相关的理想结果过程中固有的权衡问题。BO方法还使我们能够有效地探索包括层高、喷嘴移动速度和点胶压力在内的三维打印输入,并通过帕累托前沿可视化每组三维打印输入在时间、孔隙率和几何精度等输出目标方面的权衡。
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