GNN-Based Concentration Prediction With Variable Input Flow Rates for Microfluidic Mixers

Weiqing Ji;Xingzhuo Guo;Shouan Pan;Fei Long;Tsung-Yi Ho;Ulf Schlichtmann;Hailong Yao
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Abstract

Recent years have witnessed significant advances brought by microfluidic biochips in automating biochemical protocols. Accurate preparation of fluid samples is an essential component of these protocols, where concentration prediction and generation are critical. Equipped with the advantages of convenient fabrication and control, microfluidic mixers demonstrate huge potential in sample preparation. Although finite element analysis (FEA) is the most commonly used simulation method for accurate concentration prediction of a given microfluidic mixer, it is time-consuming with poor scalability for large biochip sizes. Recently, machine learning models have been adopted in concentration prediction, with great potential in enhancing the efficiency over traditional FEA methods. However, the state-of-the-art machine learning-based method can only predict the concentration of mixers with fixed input flow rates and fixed sizes. In this paper, we propose a new concentration prediction method based on graph neural networks (GNNs), which can predict output concentrations for microfluidic mixters with variable input flow rates. Moreover, a transfer learning method is proposed to transfer the trained model to mixers of different sizes with reduced training data. Experimental results show that, for microfluidic mixers with fixed input flow rates, the proposed method obtains an average reduction of 88% in terms of prediction errors compared with the state-of-the-art method. For microfluidic mixers with variable input flow rates, the proposed method reduces the prediction error by 85% on average. Besides, the proposed transfer learning method reduces the training data by 84% for extending the pre-trained model for microfluidic mixers of different sizes with acceptable prediction error.
基于 GNN 的浓度预测与微流控混合器的可变输入流量。
近年来,微流控生物芯片在生化实验自动化方面取得了重大进展。准确制备液体样品是这些方案的重要组成部分,其中浓度预测和生成至关重要。微流控混合器具有方便制造和控制的优势,在样品制备方面展现出巨大的潜力。虽然有限元分析(FEA)是最常用的模拟方法,可准确预测特定微流控混合器的浓度,但这种方法耗时长,对大型生物芯片的可扩展性差。最近,机器学习模型被用于浓度预测,与传统的有限元分析方法相比,它在提高效率方面具有巨大潜力。然而,最先进的基于机器学习的方法只能预测具有固定输入流量和固定尺寸的混合器的浓度。在本文中,我们提出了一种基于图神经网络(GNN)的新浓度预测方法,它可以预测输入流量可变的微流控混合器的输出浓度。此外,我们还提出了一种迁移学习方法,可将训练好的模型迁移到不同尺寸的混合器上,并减少训练数据。实验结果表明,对于固定输入流速的微流控混合器,与最先进的方法相比,所提出的方法平均减少了 88% 的预测误差。对于输入流量可变的微流控混合器,所提出的方法平均减少了 85% 的预测误差。此外,对于不同尺寸的微流控混合器,建议的迁移学习方法在扩展预训练模型时减少了 84% 的训练数据,且预测误差可接受。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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