Research Article

, 01 May 2025 | 10.62346/ijbsip_q2_v12_no2_25_01
Year : 2025 | Volume: 12 | Issue: 2 | Pages : 1-6

LUNG LESION DETECTION AND SEGMENTATION BASED ON CNN AND RESNET APPROACH WITH 3D IMAGES

  • 1Anna University Chennai, Assistant professor, Department of Computer Science and Engineering Loyola Institute of Technology & Science, Thovalai, IN
This project aims to develop a robust and efficient method for the detection and segmentation of lung lesions from medical imaging data, particularly focusing on Computed Tomography (CT) scans. Applied deep learning and CNN to detecting and classified lung disease using imagery data. We used the images that belong to 4 categories: healthy, covid-19, viral pneumonia, and bacterial pneumonia. Each category is consisting of 133 images and we used it to develop model that could detect and classify the images in less than 1 minutes. For the image dataset that is used on this project put it on google drive. I put label in each imageโ€™s categories with numbers from 0 to 3 (0 = covid-19, 1 = normal, 2 = viral pneumonia, 3 = bacterial pneumonia) 1. Understand the Problem Statement and Business Case Deep learning has been proven to superior in detecting and classifying disease using imagery data. Skin cancer could be detected more accurately by Deep Learning than by dermatologist (2018). Human dermatologist can detect skin cancer with 86.6% accuracy while deep learning can detect skin cancer with 95% accuracy. (Reference: "Computer learns to detect skin cancer more accurately than doctors". The Guardian. 29 May 2018) In this project, we try to develop a model that could detect and classify lung disease using 133 X-Ray images that belong to 4 classes: Healthy, Covid-19, Bacterial Pneumonia, and Viral Pneumonia. To import our data, we used image generator to generate tensor images data and normalize them. We used 428 images for training (80%) and 104 images for our validation (20&). Before we generate our data, we perform shuffling to prevents the model from learning the order of the training. We generate a batch of 40 images and labels. The following is label names for each classification: 0 = Covid- 19 1 = Normal 2 = Viral Pneumonia 3 = Bacterial Pneumonia.

References

[1]       Sung H., Ferlay J., Siegel R. L., et al., โ€œGlobal cancer statistics 2020: Globocan estimates of incidence and mortality worldwide for 36 cancers in 185 countries,โ€ Ca-Cancer J. Clin. 71, 209โ€“249 (2021). 10.3322/caac.21660.

[2]       Wu G. X., Raz D. J., โ€œLung cancer screening,โ€ Lung Cancer: Treat. Res. 170, 1โ€“23 (2016). 10.1007/978-3-319-40389-2_1.

[3]       Zhou Z., Gou F., Tan Y., et al., โ€œA cascaded multi-stage framework for automatic detection and segmentation of pulmonary nodules in developing countries,โ€ IEEE J. Biomed. Health Inform. 26(11), 5619โ€“5630(2022). 10.1109/JBHI.2022.3198509.

[4]       Huang H., Wu R., Li Y., et al., โ€œSelf- supervised transfer learning based on domain adaptation for benign-malignant lung nodule classification on thoracic ct,โ€ IEEE J. Biomed. Health Inform. 26(8), 3860โ€“3871(2022).

[5]       Mkindu H., Wu L., Zhao Y., โ€œLung nodule detection of ct images based on combining 3d-cnn and squeeze-and- excitation networks,โ€ Multimed. Tools Appl 82(17), 25747โ€“25760 (2023). 10.1007/s11042-023-14581-0.

[6]       Agnes S. A., Anitha J., Solomon A. A., โ€œTwo- stage lung nodule detection framework using enhanced unet and convolutional lstm networks in ct images,โ€ Comput. Biol. Med. 149, 106059 (2022). 10.1016/j.compbiomed.2022.106059.

[7]       Guo Z., Zhao L., Yuan J., et al., โ€œMsanet: multiscale aggregation network integrating spatial and channel information for lung nodule detection,โ€ IEEE J. Biomed. Health Inform. 26(6), 2547โ€“2558(2021). 10.1109/JBHI.2021.3131671.

[8]       Zhu L., Zhu H., Yang S., et al., โ€œPulmonary nodule detection based on hierarchical-split hrnet and feature pyramid network with atrous convolution,โ€ Biomed. Signal Process. Control.85,105024(2023) .10.1016/j.bspc.2023.105024.

[9]       Zhao D., Liu Y., Yin H., et al., โ€œAn attentive and   adaptive 3d cnnfor automatic pulmonary nodule detection in ct image,โ€ Expert Syst. with Appl. 211, 118672 (2023) .10.1016/j.eswa.2022.118672.

[10]    MacMahon H., Naidich D. P., Goo J. M., et al.,โ€œGuidelines for management of incidental pulmonary nodules detected on ct images: from the fleischner society 2017,โ€ Radiology 284(1),  228โ€“243(2017). 10.1148/radiol.2017161659.

[11]    Chen Y., Hou X., Yang Y., et al., โ€œA novel deep learning model based on multi-scale and multi-view for detection of pulmonary nodules,โ€ J Digit Imaging 36(2), 688โ€“699(2023). 10.1007/s10278- 022-00749-x.

[12]    Wu R., Liang C., Li Y., et al., โ€œSelf- supervised transfer learning framework driven by visual attention for benignโ€“ malignant lung nodule classification on chest ct,โ€ Expert Syst. with Appl. 215, 119339 (2023).

[13]    Setio A. A. A., Traverso A., De Bel T., et al., โ€œValidation, comparison, and combination of algorithms for automatic detection of pulmonary nodules in computed tomography images: the luna16 challenge,โ€ Med. Image Anal. 42, 1โ€“13(2017). 10.1016/j.media.2017.06.015

[14]    Huang Y.-S., Chou P.-R., Chen H.-M.,et al., โ€œOne-stage pulmonary nodule detection using 3-d dcnn with feature fusion and attention mechanism in ct image,โ€ Comput. Methods Programs Biomed. 220, 106786 (2022). 10.1016/j.cmpb.2022.106786.

[15]    Han Y., Qi H., Wang L., et al., โ€œPulmonary nodules detection assistant platform: An effective computer aided system for early pulmonary nodules detection in physical examination,โ€ Comput. Methods Programs Biomed. 217, 106680(2022).


Keywords: CNN, Resnet50, Lung Cancer

Citation: merryIda*,merryIda ( 2025), LUNG LESION DETECTION AND SEGMENTATION BASED ON CNN AND RESNET APPROACH WITH 3D IMAGES. , 12(2): 1-6

Received: 25/04/2025; Accepted: 01/05/2025;
Published: 01/05/2025

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*Correspondence: merryIda, ida.cse@lites.edu.in


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