基于反向传播神经网络的管状组织三维生物打印墨水流动预测

IF 0.5 Q4 ENGINEERING, MULTIDISCIPLINARY

Journal of Computational Methods in Sciences and Engineering Pub Date : 2023-12-15 DOI:10.3233/jcm-226991

Xiaoyan Wu, Shu Wang

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引用次数: 0

摘要

在开发三维血管打印机的基础上，研究了墨水从喷嘴到旋转杆的成型过程。在本研究中，为了在线检测管状组织三维生物打印过程中从喷嘴流出的墨水，我们根据管状组织三维打印墨水流动图片的感兴趣区（ROI）建立了一个几何模型，选择了墨水轮廓的描述特征，并研究了如何选择特征的数学表达式。我们使用主成分分析法（PCA）将图像特征简化为 15 个特征。我们使用反向传播（BP）神经网络预测印刷油墨流量。结果表明，实际油墨流量与基于 BP 神经网络的流量之间的误差在 5%以内。BP 神经网络可用于实时监控打印目标的质量状态，在线评估三维生物打印质量，并预测打印墨水流量，从而提高管状组织的三维生物打印精度。

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Prediction of ink flow for 3D bioprinting of tubular tissue based on a back propagation neural network

Based on the development of the 3D vascular printer, the forming process of ink from the nozzle to the rotating rod was studied. In this study, to online detect the ink flow from the nozzle during 3D bioprinting of tubular tissue, we established a geometric model according to the region of interest (ROI) of the ink flow picture of 3D printing of tubular tissue, selected description features of the ink contour, and studied how to select mathematical expressions of the features. Principal component analysis (PCA) was used to simplify the image features into 15 features. We used a back propagation (BP) neural network to predict the printing ink flow. The results show that the error between the actual ink flow rate and the flow rate based on the BP neural network is within 5%. The BP neural network can be used to monitor the quality status of the printing target in real time, evaluate the 3D bioprinting quality online, and predict the printing ink flow for the subsequent improvement of the 3D bioprinting accuracy of tubular tissue.

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来源期刊

Journal of Computational Methods in Sciences and Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

0.80

自引率

0.00%

发文量

152

期刊介绍： The major goal of the Journal of Computational Methods in Sciences and Engineering (JCMSE) is the publication of new research results on computational methods in sciences and engineering. Common experience had taught us that computational methods originally developed in a given basic science, e.g. physics, can be of paramount importance to other neighboring sciences, e.g. chemistry, as well as to engineering or technology and, in turn, to society as a whole. This undoubtedly beneficial practice of interdisciplinary interactions will be continuously and systematically encouraged by the JCMSE.