Early Screening and Subtype Identification of High-Risk Lung Nodules via Breathprint by Graphene eNose Platform: A Large Cohort Study

Early Screening and Subtype Identification of High-Risk Lung Nodules via Breathprint by Graphene eNose Platform: A Large Cohort Study

Early screening of individuals with high-risk lung nodules can significantly improve the prognosis of lung cancer patients, and accurate identification of lung nodule subtypes can provide guidance for medical treatment. Exhaled breath (EB) analysis via eNoses offers a quick and noninvasive approach,...

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Main Author: Xingyu Zhu (1372587) (author)
Other Authors: Qiaofen Chen (413800) (author), Jiajing Sun (8711571) (author), Lichen Zhang (5431988) (author), Zhengwei Huang (4855729) (author), Jingwei Xu (337549) (author), Haichuan Hu (109331) (author), Yuqi He (298660) (author), Zhao Chen (92571) (author), Xiaogang Ye (6904340) (author), Xueyin Chen (19690633) (author), Aotian Guo (18801535) (author), Sheng Lu (309194) (author), Tao Shen (209797) (author), Jianmin Wu (19537) (author), Zhengfu He (8653965) (author)
Published: 2025
Subjects:
Medicine
Cell Biology
Genetics
Physiology
Biotechnology
Developmental Biology
Cancer
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
reactive resistance response
including various benign
external test set
lung cancer patients
dimensionality reduction analysis
breath sampling accessory
427 healthy subjects
graphene enose platform
enose platform integrated
risk lung nodules
lung nodule subtypes
large population studies
89 – 0
enose platform
lung nodules
malignant subtypes
exhaled breath
breathprint analysis
2586 subjects
subtype identification
study demonstrates
solid validation
significantly improve
robust performance
rapid method
quality control
provide guidance
model achieved
metal ion
medical treatment
early screening
baseline data
accurate identification
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Summary:Early screening of individuals with high-risk lung nodules can significantly improve the prognosis of lung cancer patients, and accurate identification of lung nodule subtypes can provide guidance for medical treatment. Exhaled breath (EB) analysis via eNoses offers a quick and noninvasive approach, but current eNose technology lacks quality control and solid validation in large population studies. Herein, an eNose platform integrated with a metal ion-decorated graphene sensor array and a breath sampling accessory was established. EB samples from 427 healthy subjects and 2586 subjects with lung nodules, including various benign and malignant subtypes, were collected through the breath sampling accessory for quality control. The large-cohort clinical EB samples were analyzed by the eNose platform to acquire the cross-reactive resistance response. Breathprint analysis for high-risk lung nodules using SVM and age-matched training sets yielded strong and robust performance. Combined with baseline data, the model achieved an AUC of 0.93 (95% CI, 0.89–0.96) on the external test set, with 97% sensitivity and 73% specificity. Moreover, dimensionality reduction analysis of breathprints demonstrated separability across different lung nodule subtypes. This study demonstrates the reliability of the graphene eNose platform to identify high-risk lung nodules and classify lung nodule subtypes in a noninvasive and rapid method.

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