Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system

Ji-Eun  Chang; Dae-Sik  Lee; Sang-Woo  Ban; Jaeho  Oh; Moon Youn  Jung; Seung-Hwan  Kim; SungJoon  Park; Krishna Persaud; Sanghoon  Jheon

doi:10.1016/j.snb.2017.08.057

Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system

Ji-Eun Chang, Dae-Sik Lee, Sang-Woo Ban, Jaeho Oh, Moon Youn Jung, Seung-Hwan Kim, SungJoon Park, Krishna Persaud, Sanghoon Jheon

Research output: Contribution to journal › Article › peer-review

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Abstract

Lung cancer is the leading cause of cancer deaths in worldwide. There are many challenges to detect early stage lung cancer in accurate, inexpensive, and non-invasive ways. In this study, we have designed, fabricated, and characterized a sensor system as a novel lung cancer diagnosis tool. In order to investigate the clinical feasibility of the system to detect early stage lung cancer, exhaled breath was collected from 37 patients with non-small cell lung cancer (81.1% of stage I and II) and 48 healthy controls. Three types of samples were collected from each patient; 1) before lung cancer surgery, 2) the first outpatient clinic visit after surgery, and 3) the second outpatient clinic visit after surgery. The sampling schedule from the healthy controls matched that of the lung cancer patients. The volatile organic compounds (VOCs) in the exhaled breath were analyzed by the sensor system. The sensor system consisted of an array of seven metal oxide gas sensors, a gas flow controlling module, heating module, gas adsorption-desorption module and classifiers for data analysis. The result obtained for the first set of samples, using a multilayer perceptron (MLP) for classification indicated a total accuracy of 75.0% with 79.0% of sensitivity and 72.0% of specificity. 93.5% of healthy controls showed nearly unchanged data from the first to the third samples, while 45.2% of lung cancer patients showed definitely changed data from the first to the third samples when analyzed the projection results of original data onto the selected principal components (PCs) obtained from principal component analysis (PCA). The study showed that VOCs in exhaled breath potentially discriminated mostly early stage lung cancer patients before the surgery from healthy volunteers with our sensor system. Furthermore, the prognosis of the lung cancer patients after surgery would be predicted by this system. These results suggest that breath analysis may develop as a novel diagnostic tool for early lung cancer.

Original language	English
Pages (from-to)	800-807
Journal	Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers
Volume	255
Issue number	1
Early online date	9 Aug 2017
DOIs	https://doi.org/10.1016/j.snb.2017.08.057
Publication status	Published - 9 Aug 2017

Keywords

Lung cancer
Breath gas
Volatile organic compounds
Chemo-resistive sensors

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.snb.2017.08.057

1-s2.0-S092540051731479X-main Chang et alAccepted author manuscript, 454 KB

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Chang, J.-E., Lee, D.-S., Ban, S.-W., Oh, J., Jung, M. Y., Kim, S.-H., Park, S., Persaud, K., & Jheon, S. (2017). Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system. Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers, 255(1), 800-807. https://doi.org/10.1016/j.snb.2017.08.057

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abstract = "Lung cancer is the leading cause of cancer deaths in worldwide. There are many challenges to detect early stage lung cancer in accurate, inexpensive, and non-invasive ways. In this study, we have designed, fabricated, and characterized a sensor system as a novel lung cancer diagnosis tool. In order to investigate the clinical feasibility of the system to detect early stage lung cancer, exhaled breath was collected from 37 patients with non-small cell lung cancer (81.1% of stage I and II) and 48 healthy controls. Three types of samples were collected from each patient; 1) before lung cancer surgery, 2) the first outpatient clinic visit after surgery, and 3) the second outpatient clinic visit after surgery. The sampling schedule from the healthy controls matched that of the lung cancer patients. The volatile organic compounds (VOCs) in the exhaled breath were analyzed by the sensor system. The sensor system consisted of an array of seven metal oxide gas sensors, a gas flow controlling module, heating module, gas adsorption-desorption module and classifiers for data analysis. The result obtained for the first set of samples, using a multilayer perceptron (MLP) for classification indicated a total accuracy of 75.0% with 79.0% of sensitivity and 72.0% of specificity. 93.5% of healthy controls showed nearly unchanged data from the first to the third samples, while 45.2% of lung cancer patients showed definitely changed data from the first to the third samples when analyzed the projection results of original data onto the selected principal components (PCs) obtained from principal component analysis (PCA). The study showed that VOCs in exhaled breath potentially discriminated mostly early stage lung cancer patients before the surgery from healthy volunteers with our sensor system. Furthermore, the prognosis of the lung cancer patients after surgery would be predicted by this system. These results suggest that breath analysis may develop as a novel diagnostic tool for early lung cancer.",

keywords = "Lung cancer , Breath gas , Volatile organic compounds , Chemo-resistive sensors ",

author = "Ji-Eun Chang and Dae-Sik Lee and Sang-Woo Ban and Jaeho Oh and Jung, {Moon Youn} and Seung-Hwan Kim and SungJoon Park and Krishna Persaud and Sanghoon Jheon",

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Chang, J-E, Lee, D-S, Ban, S-W, Oh, J, Jung, MY, Kim, S-H, Park, S, Persaud, K & Jheon, S 2017, 'Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system', Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers, vol. 255, no. 1, pp. 800-807. https://doi.org/10.1016/j.snb.2017.08.057

Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system. / Chang, Ji-Eun ; Lee, Dae-Sik ; Ban, Sang-Woo et al.
In: Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers, Vol. 255, No. 1, 09.08.2017, p. 800-807.

Research output: Contribution to journal › Article › peer-review

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T1 - Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system

AU - Chang, Ji-Eun

AU - Lee, Dae-Sik

AU - Ban, Sang-Woo

AU - Oh, Jaeho

AU - Jung, Moon Youn

AU - Kim, Seung-Hwan

AU - Park, SungJoon

AU - Persaud, Krishna

AU - Jheon, Sanghoon

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N2 - Lung cancer is the leading cause of cancer deaths in worldwide. There are many challenges to detect early stage lung cancer in accurate, inexpensive, and non-invasive ways. In this study, we have designed, fabricated, and characterized a sensor system as a novel lung cancer diagnosis tool. In order to investigate the clinical feasibility of the system to detect early stage lung cancer, exhaled breath was collected from 37 patients with non-small cell lung cancer (81.1% of stage I and II) and 48 healthy controls. Three types of samples were collected from each patient; 1) before lung cancer surgery, 2) the first outpatient clinic visit after surgery, and 3) the second outpatient clinic visit after surgery. The sampling schedule from the healthy controls matched that of the lung cancer patients. The volatile organic compounds (VOCs) in the exhaled breath were analyzed by the sensor system. The sensor system consisted of an array of seven metal oxide gas sensors, a gas flow controlling module, heating module, gas adsorption-desorption module and classifiers for data analysis. The result obtained for the first set of samples, using a multilayer perceptron (MLP) for classification indicated a total accuracy of 75.0% with 79.0% of sensitivity and 72.0% of specificity. 93.5% of healthy controls showed nearly unchanged data from the first to the third samples, while 45.2% of lung cancer patients showed definitely changed data from the first to the third samples when analyzed the projection results of original data onto the selected principal components (PCs) obtained from principal component analysis (PCA). The study showed that VOCs in exhaled breath potentially discriminated mostly early stage lung cancer patients before the surgery from healthy volunteers with our sensor system. Furthermore, the prognosis of the lung cancer patients after surgery would be predicted by this system. These results suggest that breath analysis may develop as a novel diagnostic tool for early lung cancer.

AB - Lung cancer is the leading cause of cancer deaths in worldwide. There are many challenges to detect early stage lung cancer in accurate, inexpensive, and non-invasive ways. In this study, we have designed, fabricated, and characterized a sensor system as a novel lung cancer diagnosis tool. In order to investigate the clinical feasibility of the system to detect early stage lung cancer, exhaled breath was collected from 37 patients with non-small cell lung cancer (81.1% of stage I and II) and 48 healthy controls. Three types of samples were collected from each patient; 1) before lung cancer surgery, 2) the first outpatient clinic visit after surgery, and 3) the second outpatient clinic visit after surgery. The sampling schedule from the healthy controls matched that of the lung cancer patients. The volatile organic compounds (VOCs) in the exhaled breath were analyzed by the sensor system. The sensor system consisted of an array of seven metal oxide gas sensors, a gas flow controlling module, heating module, gas adsorption-desorption module and classifiers for data analysis. The result obtained for the first set of samples, using a multilayer perceptron (MLP) for classification indicated a total accuracy of 75.0% with 79.0% of sensitivity and 72.0% of specificity. 93.5% of healthy controls showed nearly unchanged data from the first to the third samples, while 45.2% of lung cancer patients showed definitely changed data from the first to the third samples when analyzed the projection results of original data onto the selected principal components (PCs) obtained from principal component analysis (PCA). The study showed that VOCs in exhaled breath potentially discriminated mostly early stage lung cancer patients before the surgery from healthy volunteers with our sensor system. Furthermore, the prognosis of the lung cancer patients after surgery would be predicted by this system. These results suggest that breath analysis may develop as a novel diagnostic tool for early lung cancer.

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KW - Breath gas

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KW - Chemo-resistive sensors

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JF - Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers

IS - 1

ER -

Analysis of volatile organic compounds in exhaled breath for lung cancer diagnosis using a sensor system

Abstract

Keywords

UN SDGs

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