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Abstract

Lung cancer pathology images are categorized with enhanced accuracy in this research, addressing the significant challenge posed by the limited availability of labeled images, a limitation exacerbated by the complexity of cellular morphologies.

Background:

The accurate classification of lung cancer pathology images is of paramount importance for both diagnostic and therapeutic purposes. However, the development of robust classification models is often hindered by the intricate cellular morphologies and the scarcity of labeled images, which is a critical bottleneck in the field.

Objectives:

The study is designed to incorporate unlabeled data into the training process, thereby enhancing the classification of lung cancer pathology images through the use of comparative learning techniques.

Methods:

A methodology is introduced wherein confidently classified unlabeled images are integrated with labeled ones, enriching the training dataset. This approach draws on principles of farthest and nearest neighbor contrastive learning to cultivate a more challenging learning environment and to augment the variability of contrastive samples. To effectively extract key cellular morphological features, an encoder based on the ResNet50 architecture, fortified with deformable and dynamic convolutional techniques, is utilized.

Results:

Demonstrated by experimental results, the proposed classification strategy achieves a significant improvement in the accuracy of lung cancer image classification, even under conditions characterized by a limited availability of labeled data, thus underscoring the robustness of the method.

Conclusion:

The integration of comparative learning with both labeled and unlabeled images, complemented by the application of advanced convolutional techniques, is shown to be a promising avenue for enhancing the classification of lung cancer pathology images. This research is presented as a practical solution to the urgent need for accurate and efficient diagnostic tools in the field of oncology.

Keywords

lung cancer pathological image classification contrastive learning deformable convolution dynamic convolution

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References

Travis

. Lung cancer pathology: current concepts. Clin Chest Med 2020; 41: 67–85.

Travis

Brambilla

Noguchi

, et al. The new IASLC/ATS/ERS international multidisciplinary lung adenocarcinoma classification. J Thorac Oncol 2011; 5: 244–285.

Ding

Zhu

, et al. Comorbidity in lung cancer patients and its association with medical service cost and treatment choice in China. BMC Cancer 2020; 20: 1–11.

Grose

Morrison

Devereux

, et al. Comorbidities in lung cance: prevalence, severity and links with socioeconomic status and treatment. Postgrad Med J 2014; 90: 305–310.

Monirul

Jiang

Anggondowati

, et al. Comorbidity and survival in lung cancer patients. Cancer Epidemiol Biomarkers Prev 2015; 24: 1001–1148.

Zheng

. Classification and pathology of lung cancer. Surg Oncol Clin N Am 2016; 25: 447–468.

Travis

Brambilla

Nicholson

, et al. The 2015 world health organization classification of lung tumors : impact of genetic, clinical and radiologic advances since the 2004 classification. J Thorac Oncol 2015; 10: 1243–1260.

Wang

Yang

Rong

, et al. Artificial intelligence in lung cancer pathology image analysis. Cancer 2019; 11: 1–16.

Gou

Song

Jiang

, et al. Histological subtypes classification of lung cancers on CT images using 3D deep learning and radiomics. Acad Radiol 2020; 28: 258–266.

10.

Ibtehaz

Rahman

. MultiResUNet: rethinking the U-Net architecture for multimodal biomedical image segmentation. Neural Netw 2020; 121: 74–87.

11.

Ali

. Multi-input dual-stream capsule network for improved lung and colon cancer classification. Diagnostics 2021; 11: 1–18.

12.

Vambol

Kharchenko

Potii

, et al. Dynamic routing between capsules. In: Proceedings of the 31st International Conference on Neural Information Processing Systems, Long Beach, California, USA, December 4–9, 2017, 3859–3869.

13.

Chen

, et al. Research on the auxiliary classification and diagnosis of lung cancer subtypes based on histopathological images. IEEE Access 2021; 9: 53687–53707.

14.

Fan

, et al. Momentum contrast for unsupervised visual representation learning. In: Proceedings of the 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition, Seattle, USA, June 13–19, 2020. New York: IEEE Press, 2020, 9726–9735.

15.

Chen

Kornblith

Norouzi

, et al. A simple framework for contrastive learning of visual epresentations. In: Proceedings of the 37th International Conference on Machine Learning, Los Angeles, USA, July 14–16, 2020. New York: ACM, 2020, 1–11.

16.

Dwibedi

Aytar

Tompson

, et al. With a little help from my friends: nearest-neighbor contrastive learning of visual representations. In: Proceedings of the 2021 IEEE/CVF International Conference on Computer Vision, Montreal, Canada, October 10–17, 2021. New York: IEEE Press, 2021, 9568–9597.

17.

Geaney

O’Reilly

Maxwell

, et al. Translation of tissue-based artificial intelligence into clinical practice: from discovery to adoption. Oncogene 2023; 42: 3545–3555.

18.

Canavesi

D’Arnese

Caramaschi

, et al. Lung cancer identification via deep learning: A multi-stage workflow. In: 2022 IEEE 19th International Symposium on Biomedical Imaging (ISBI), 28–31 March 2022, Kolkata, India.

19.

Kumar Swain

Swetapadma

Kumar Rout

, et al. Classification of non-small cell lung cancer types using sparse deep neural network features. Biomed Signal Process Control 2024; 87: 105485.

20.

Saravanaprasad

Anbu Karuppusamy

. Advanced lung tumor diagnosis using a 3D deep neural network based CAD system. Biomed Signal Process Control 2024; 89: 105650.

21.

Fava

Dianat

, et al. Pre-processing techniques to enhance the classification of lung sounds based on deep learning. Biomed Signal Process Control 2024; 92: 106009.

22.

Dai

Xiong

, et al. Deformable convolutional networks. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Venice, Italy, October 22–29, 2017, New York: IEEE Press, 2017, 764–773.

23.

Zhang

Wang

Zhang

, et al. DyNet: dynamic convolution for accelerating convolutional neural networks. arXiv : 2004.10694, 2000.

24.

Clark

Vendt

Smith

, et al. The cancer imaging archive(TCIA): maintaining and operating a public information repository. J Digit Imaging 2013; 26: 1045–1057.

25.

Borkowski

Bui

Thomas

, et al. Lung and colon cancer histopathological image dataset (LC25000). arXiv:1912.12142, 2019.

Intelligent classification of lung cancer pathology images through comparative morphological feature learning

Abstract

Background:

Objectives:

Methods:

Results:

Conclusion:

Keywords

Get full access to this article

References