利用机器学习在电化学传感器上对多种药物浓度进行加权平均值优化定量

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Tatsunori Matsumoto;Lin Du;Francesca Rodino;Yann Thoma;Chinthaka Premachandra;Sandro Carrara
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引用次数: 0

摘要

在治疗药物监测(TDM)和个性化治疗中,多种药物的定量分析具有重要意义和迫切需求。特别是,基于电化学传感器获得的循环伏安图(CVs),人工神经网络(ANNs)已被广泛应用于药物浓度的精确定量,从而促进了护理点和潜在的系统级可穿戴设备的开发。然而,大多数工作只考虑了预测值与实际值接近的准确性,而没有考虑预测的药物浓度是否被低估。在实际的药物定量分析中,由于定量估计不足而造成的过度暴露所带来的潜在毒性可能会危及患者的身体。因此,在现有定量模型的基础上避免低估药物浓度,需要在 ANN 的输出阶段优化传统的损失函数。本文提出了一种基于均方误差(MSE)的新型损失函数--WeightedMSE,以避免低估定量。它可以通过调整参数灵活改变,以适应与不同类型药物相对应的可接受的高估范围。使用依托泊苷和甲氨蝶呤的模拟数据集和真实数据集作为药物模型,证明所提出的方法在量化多种药物浓度时可避免预测值低估 98% 以上,对开发护理点和可穿戴监测系统具有显著效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimized Quantification of Multiple Drug Concentrations by WeightedMSE With Machine Learning on Electrochemical Sensor
Quantification of multiple drugs is of great importance and urgently needed in therapeutic drug monitoring (TDM) and personalized therapy. Especially, based on cyclic voltammograms (CVs) obtained by electrochemical sensors, the use of artificial neural networks (ANNs) has been widely attempted in the accurate quantification of drug concentrations, enabling the development of point-of-care and potentially system-level wearable devices. However, most of the work only considers the accuracy of how the predicted value is close to the actual value, which does not consider whether the predicted drug concentration is underestimated. In practical drug quantification, potential toxicity due to overexposure with underestimated quantification can lead to endangering the patient's body. Therefore, avoiding underestimating the concentration of drugs based on existing quantification models is required and necessary to optimize the conventional loss function at the output stage of ANN. In this letter, a novel loss function based on mean squared error (MSE), WeightedMSE, is proposed for avoiding underestimated quantification. It can be changed flexibly by adjusting parameters in order to adapt the acceptable overestimation range corresponding to the different types of drugs. A simulated dataset and a real dataset of etoposide and methotrexate are used as drug models, demonstrating that the proposed method can avoid underestimation in predicted values by over 98% in quantifying the concentration of multiple drugs and showing significant effectiveness for the development of point-of-care and wearable monitoring systems.
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来源期刊
IEEE Sensors Letters
IEEE Sensors Letters Engineering-Electrical and Electronic Engineering
CiteScore
3.50
自引率
7.10%
发文量
194
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