Edge-Enhanced Feature Pyramid SwinUNet: Advanced Segmentation of Lung Nodules in CT Images

IF 2 4区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

IET Image Processing Pub Date : 2025-04-14 DOI:10.1049/ipr2.70072

Akila Agnes S, Arun Solomon A, K Karthick, Mejdl Safran, Sultan Alfarhood

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Abstract

In the field of oncology, lung cancer is a leading contributor to cancer-related mortality, highlighting the need for early detection of lung nodules for effective intervention. However, accurate segmentation of lung nodules in Computed Tomography (CT) images remains a significant challenge due to issues such as heterogeneous nodule dimensions, low contrast, and their visual similarity with surrounding tissues. To address these challenges, this study proposes the Edge-Enhanced Feature Pyramid SwinUNet (EE-FPS-UNet), an advanced segmentation model that integrates a modified Swin Transformer with a feature pyramid network (FPN). The research objective is to enhance boundary delineation and multi-scale feature aggregation for improved segmentation performance. The proposed model uses the Swin Transformer to capture long-range dependencies and integrates an FPN for robust multi-scale feature aggregation. Its window-based self-attention mechanism also reduces computational complexity, making it well-suited for high-resolution CT images. Additionally, an edge detection module enhances segmentation by providing edge-related features to the decoder, improving boundary precision. A comparative analysis evaluates the EE-FPS-UNet against leading models, including PSPNet, U-Net, Attention U-Net, and DeepLabV3. The results demonstrate that the proposed model outperforms these models, achieving a Dice Similarity of 0.91 and a sensitivity of 0.89, establishing its efficacy for lung nodule segmentation.

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边缘增强特征金字塔SwinUNet: CT图像肺结节的高级分割

在肿瘤学领域，肺癌是导致癌症相关死亡率的主要因素，因此需要及早发现肺部结节以进行有效干预。然而，计算机断层扫描（CT）图像中肺部结节的准确分割仍然是一项重大挑战，原因包括结节尺寸不均匀、对比度低以及与周围组织的视觉相似性等问题。为了应对这些挑战，本研究提出了边缘增强特征金字塔 SwinUNet（EE-FPS-UNet），这是一种先进的分割模型，集成了改进的 Swin 变换器和特征金字塔网络（FPN）。研究目标是加强边界划分和多尺度特征聚合，以提高分割性能。所提出的模型使用 Swin 变换器捕捉长距离依赖关系，并集成了一个 FPN 以实现稳健的多尺度特征聚合。其基于窗口的自关注机制还降低了计算复杂度，因此非常适合高分辨率 CT 图像。此外，边缘检测模块通过向解码器提供与边缘相关的特征，提高了边界精度，从而增强了分割效果。对比分析将 EE-FPS-UNet 与 PSPNet、U-Net、Attention U-Net 和 DeepLabV3 等领先模型进行了评估。结果表明，所提出的模型优于这些模型，达到了 0.91 的骰子相似度和 0.89 的灵敏度，证明了其在肺结节分割方面的功效。

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来源期刊

IET Image Processing 工程技术-工程：电子与电气

CiteScore

5.40

自引率

8.70%

发文量

282

审稿时长

6 months

期刊介绍： The IET Image Processing journal encompasses research areas related to the generation, processing and communication of visual information. The focus of the journal is the coverage of the latest research results in image and video processing, including image generation and display, enhancement and restoration, segmentation, colour and texture analysis, coding and communication, implementations and architectures as well as innovative applications. Principal topics include: Generation and Display - Imaging sensors and acquisition systems, illumination, sampling and scanning, quantization, colour reproduction, image rendering, display and printing systems, evaluation of image quality. Processing and Analysis - Image enhancement, restoration, segmentation, registration, multispectral, colour and texture processing, multiresolution processing and wavelets, morphological operations, stereoscopic and 3-D processing, motion detection and estimation, video and image sequence processing. Implementations and Architectures - Image and video processing hardware and software, design and construction, architectures and software, neural, adaptive, and fuzzy processing. Coding and Transmission - Image and video compression and coding, compression standards, noise modelling, visual information networks, streamed video. Retrieval and Multimedia - Storage of images and video, database design, image retrieval, video annotation and editing, mixed media incorporating visual information, multimedia systems and applications, image and video watermarking, steganography. Applications - Innovative application of image and video processing technologies to any field, including life sciences, earth sciences, astronomy, document processing and security. Current Special Issue Call for Papers: Evolutionary Computation for Image Processing - https://digital-library.theiet.org/files/IET_IPR_CFP_EC.pdf AI-Powered 3D Vision - https://digital-library.theiet.org/files/IET_IPR_CFP_AIPV.pdf Multidisciplinary advancement of Imaging Technologies: From Medical Diagnostics and Genomics to Cognitive Machine Vision, and Artificial Intelligence - https://digital-library.theiet.org/files/IET_IPR_CFP_IST.pdf Deep Learning for 3D Reconstruction - https://digital-library.theiet.org/files/IET_IPR_CFP_DLR.pdf