Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning

F Song; CY Gong; XY Feng; GP Xu; QK Meng; XY You; JS Wang; LX Zhang; C Yang; QX Li; JW Liu; FY Ning; NL Zhai; Q Jing; SS Han; Bo Liu

doi:10.1021/acssensors.5c02692

Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning

F Song
, CY Gong
, XY Feng
, GP Xu
, QK Meng
, XY You
, JS Wang
, LX Zhang
, C Yang
, QX Li
, JW Liu
, FY Ning
, NL Zhai
, Q Jing^*
, SS Han^*
, Bo Liu^*

^*Corresponding author for this work

Department of Physics

Shandong University of Technology
Binzhou Medical University Hospital

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

Abstract

Lung cancer is often diagnosed at an advanced stage due to its
subtle and imperceptible early symptoms. Therefore, the development of a
convenient and reliable method or device for early screening and diagnosis
of lung cancer is urgently needed. Benzene derivatives and alkanes have been
identified as key breath biomarkers for lung cancer. In this study, we fabricated
an ultrasensitive and cross-selective gas sensor based on Pd/PdO
co-doped SnO2, specifically designed to detect benzene derivatives. The sensor
demonstrates detection limits at the ppb level for several key lung cancer
breath biomarkers, including toluene (40 ppb), 1-methyl-4-(1-methylethyl)-
benzene (100 ppb), o-xylene (90 ppb), styrene (500 ppb), ethylbenzene
(100 ppb), 2-methylhexane (500 ppb), and ethyl alcohol (150 ppb).
Clinically, exhaled breath samples from 50 lung cancer patients and 60 healthy
control subjects were analyzed using the sensor. Two machine learning
approaches were employed to distinguish between the two groups: (1) manual feature extraction, followed by principal component
analysis (PCA), and (2) a deep learning framework integrating convolutional neural networks with a multilayer perceptron.
Diagnostic models based on these approaches achieved overall accuracies, sensitivities, and specificities of 0.95, 1.00, and 0.89
(PCA-based) and 0.86, 0.91, and 0.83 (deep learning-based), respectively. Receiver operating characteristic curve analyses yielded area
under the curve values of 0.98 and 0.94 for the PCA and deep learning models, respectively. These findings suggest that the sensor has
a significant potential for clinical lung cancer diagnosis.

Original language	English
Pages (from-to)	1875
Number of pages	1890
Journal	ACS Sensors
Volume	11
DOIs	https://doi.org/10.1021/acssensors.5c02692
Publication status	Published - 16 Feb 2026

UN SDGs

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

SDG 3 Good Health and Well-being

Access to Document

10.1021/acssensors.5c02692

Cite this

Song, F., Gong, CY., Feng, XY., Xu, GP., Meng, QK., You, XY., Wang, JS., Zhang, LX., Yang, C., Li, QX., Liu, JW., Ning, FY., Zhai, NL., Jing, Q., Han, SS., & Liu, B. (2026). Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning. ACS Sensors, 11, 1875. https://doi.org/10.1021/acssensors.5c02692

@article{b14f3688394345ff838af93a16304935,

title = "Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning",

abstract = "Lung cancer is often diagnosed at an advanced stage due to its subtle and imperceptible early symptoms. Therefore, the development of a convenient and reliable method or device for early screening and diagnosis of lung cancer is urgently needed. Benzene derivatives and alkanes have been identified as key breath biomarkers for lung cancer. In this study, we fabricated an ultrasensitive and cross-selective gas sensor based on Pd/PdO co-doped SnO2, specifically designed to detect benzene derivatives. The sensor demonstrates detection limits at the ppb level for several key lung cancer breath biomarkers, including toluene (40 ppb), 1-methyl-4-(1-methylethyl)- benzene (100 ppb), o-xylene (90 ppb), styrene (500 ppb), ethylbenzene (100 ppb), 2-methylhexane (500 ppb), and ethyl alcohol (150 ppb). Clinically, exhaled breath samples from 50 lung cancer patients and 60 healthy control subjects were analyzed using the sensor. Two machine learning approaches were employed to distinguish between the two groups: (1) manual feature extraction, followed by principal component analysis (PCA), and (2) a deep learning framework integrating convolutional neural networks with a multilayer perceptron. Diagnostic models based on these approaches achieved overall accuracies, sensitivities, and specificities of 0.95, 1.00, and 0.89 (PCA-based) and 0.86, 0.91, and 0.83 (deep learning-based), respectively. Receiver operating characteristic curve analyses yielded area under the curve values of 0.98 and 0.94 for the PCA and deep learning models, respectively. These findings suggest that the sensor has a significant potential for clinical lung cancer diagnosis.",

author = "F Song and CY Gong and XY Feng and GP Xu and QK Meng and XY You and JS Wang and LX Zhang and C Yang and QX Li and JW Liu and FY Ning and NL Zhai and Q Jing and SS Han and Bo Liu",

year = "2026",

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doi = "10.1021/acssensors.5c02692",

language = "English",

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Song, F, Gong, CY, Feng, XY, Xu, GP, Meng, QK, You, XY, Wang, JS, Zhang, LX, Yang, C, Li, QX, Liu, JW, Ning, FY, Zhai, NL, Jing, Q, Han, SS & Liu, B 2026, 'Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning', ACS Sensors, vol. 11, pp. 1875. https://doi.org/10.1021/acssensors.5c02692

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T1 - Clinical Diagnosis of Lung Cancer via Exhaled Breath Analysis Using an Ultrasensitive and Cross-Selective Benzene-Derivative Gas Sensor Assisted by Machine Learning

AU - Song, F

AU - Gong, CY

AU - Feng, XY

AU - Xu, GP

AU - Meng, QK

AU - You, XY

AU - Wang, JS

AU - Zhang, LX

AU - Yang, C

AU - Li, QX

AU - Liu, JW

AU - Ning, FY

AU - Zhai, NL

AU - Jing, Q

AU - Han, SS

AU - Liu, Bo

PY - 2026/2/16

Y1 - 2026/2/16

N2 - Lung cancer is often diagnosed at an advanced stage due to its subtle and imperceptible early symptoms. Therefore, the development of a convenient and reliable method or device for early screening and diagnosis of lung cancer is urgently needed. Benzene derivatives and alkanes have been identified as key breath biomarkers for lung cancer. In this study, we fabricated an ultrasensitive and cross-selective gas sensor based on Pd/PdO co-doped SnO2, specifically designed to detect benzene derivatives. The sensor demonstrates detection limits at the ppb level for several key lung cancer breath biomarkers, including toluene (40 ppb), 1-methyl-4-(1-methylethyl)- benzene (100 ppb), o-xylene (90 ppb), styrene (500 ppb), ethylbenzene (100 ppb), 2-methylhexane (500 ppb), and ethyl alcohol (150 ppb). Clinically, exhaled breath samples from 50 lung cancer patients and 60 healthy control subjects were analyzed using the sensor. Two machine learning approaches were employed to distinguish between the two groups: (1) manual feature extraction, followed by principal component analysis (PCA), and (2) a deep learning framework integrating convolutional neural networks with a multilayer perceptron. Diagnostic models based on these approaches achieved overall accuracies, sensitivities, and specificities of 0.95, 1.00, and 0.89 (PCA-based) and 0.86, 0.91, and 0.83 (deep learning-based), respectively. Receiver operating characteristic curve analyses yielded area under the curve values of 0.98 and 0.94 for the PCA and deep learning models, respectively. These findings suggest that the sensor has a significant potential for clinical lung cancer diagnosis.

AB - Lung cancer is often diagnosed at an advanced stage due to its subtle and imperceptible early symptoms. Therefore, the development of a convenient and reliable method or device for early screening and diagnosis of lung cancer is urgently needed. Benzene derivatives and alkanes have been identified as key breath biomarkers for lung cancer. In this study, we fabricated an ultrasensitive and cross-selective gas sensor based on Pd/PdO co-doped SnO2, specifically designed to detect benzene derivatives. The sensor demonstrates detection limits at the ppb level for several key lung cancer breath biomarkers, including toluene (40 ppb), 1-methyl-4-(1-methylethyl)- benzene (100 ppb), o-xylene (90 ppb), styrene (500 ppb), ethylbenzene (100 ppb), 2-methylhexane (500 ppb), and ethyl alcohol (150 ppb). Clinically, exhaled breath samples from 50 lung cancer patients and 60 healthy control subjects were analyzed using the sensor. Two machine learning approaches were employed to distinguish between the two groups: (1) manual feature extraction, followed by principal component analysis (PCA), and (2) a deep learning framework integrating convolutional neural networks with a multilayer perceptron. Diagnostic models based on these approaches achieved overall accuracies, sensitivities, and specificities of 0.95, 1.00, and 0.89 (PCA-based) and 0.86, 0.91, and 0.83 (deep learning-based), respectively. Receiver operating characteristic curve analyses yielded area under the curve values of 0.98 and 0.94 for the PCA and deep learning models, respectively. These findings suggest that the sensor has a significant potential for clinical lung cancer diagnosis.

U2 - 10.1021/acssensors.5c02692

DO - 10.1021/acssensors.5c02692

M3 - Article

SN - 2379-3694

VL - 11

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JO - ACS Sensors

JF - ACS Sensors

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