Gaussian Process Regression and Monte Carlo Simulation to Determine VOC Biomarker Concentrations Via Chemiresistive Gas Nanosensors

2021 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS) Pub Date : 2021-06-07 DOI:10.1109/DTS52014.2021.9498219

Paula Angarita Rivera, Mark D. Woollam, Amanda P. Siegel, Mangilal Agarwal

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引用次数: 3

Abstract

Utilizing chemiresistive gas sensors for volatile organic compound (VOC) detection has been a growing area of investigation in the last decade. VOCs have been extensively studied as potential biomarkers for biomedical applications as they are byproducts of metabolic pathways which are dysregulated by disease. Therefore, sensor arrays have been fabricated in previous studies to detect VOC biomarkers. In the process of testing these sensors, it is highly advantageous to quantify the concentration of the VOC biomarkers with high accuracy to diagnose the disease with high sensitivity and specificity. To investigate, analyze, and understand the relation between the concentrations of the VOC to the sensor resistance response, Gaussian Process (GP) models were implemented to predict the behavior of the data with respect to the resistance when the sensor is exposed to a range of concentrations of VOCs. Additionally, the relation between the concentration and resistance of the sensor was studied to predict the concentration of the VOC when a resistance is obtained. Monte Carlo Simulation Sampling from the GP model was utilized to generate data to further understand the trend. The results demonstrated that the relation between the concentration and resistance is linear. The model was tested with sampling data and its accuracy was evaluated.

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通过化学阻性气体纳米传感器测定VOC生物标志物浓度的高斯过程回归和蒙特卡罗模拟

在过去十年中，利用化学气体传感器检测挥发性有机化合物(VOC)已成为一个日益发展的研究领域。挥发性有机化合物作为生物医学应用的潜在生物标志物已被广泛研究，因为它们是疾病失调代谢途径的副产物。因此，在以前的研究中已经制造了传感器阵列来检测VOC生物标志物。在对这些传感器进行检测的过程中，对VOC生物标志物的浓度进行高精度的量化，对疾病的诊断具有很高的敏感性和特异性，是非常有利的。为了调查、分析和理解VOC浓度与传感器电阻响应之间的关系，采用高斯过程(GP)模型来预测当传感器暴露于一定浓度的VOC时，数据与电阻的关系。此外，还研究了传感器的浓度与电阻之间的关系，以便在获得电阻时预测VOC的浓度。利用GP模型的采样来生成数据，进一步了解趋势。结果表明，浓度与阻力呈线性关系。用抽样数据对模型进行了检验，并对模型的精度进行了评价。

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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2021 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS)

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