DiffusionClusNet: Deep Clustering-Driven Diffusion Models for Ultrasound Image Enhancement

In modern medical diagnostics, high-quality ultrasound images are essential because they are cost-effective, non-invasive, and capable of providing dynamic recordings. Nevertheless, obtaining such high-quality images is challenging, especially in resource-limited areas, which negatively impacts diag...

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Bibliographic Details
Published in:IEEE transactions on consumer electronics 2025-02, p.1-1
Main Authors: Chen, Nuo, Zhang, Yongquan, Fan, Chenchen, Zhao, Wei, Wang, Changmiao, Wang, Hai
Format: Article
Language:English
Subjects:
Accuracy
Decoding
Deep Clustering
Diffusion Model
Diffusion models
Fusion of image and classification (FIC)
Image enhancement
Imaging
Medical diagnostic imaging
Noise
Noise reduction
Structural Similarity (SSIM)
Training
Ultrasonic imaging
Ultrasound Imaging
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Summary:In modern medical diagnostics, high-quality ultrasound images are essential because they are cost-effective, non-invasive, and capable of providing dynamic recordings. Nevertheless, obtaining such high-quality images is challenging, especially in resource-limited areas, which negatively impacts diagnostic accuracy. To address these issues, we propose a novel method for enhancing ultrasound images using deep clustering-enhanced diffusion models. Our proposed method consists of two main components: an image enhancement pathway and an Auxiliary Classification Pathway (ACP), which are integrated through a Fusion of Image and Classification (FIC) module. The image enhancement pathway employs a structure that includes a Variational Autoencoder (VAE) encoder, a UNet denoising network, and a VAE decoder. This structure progressively reduces noise and generates high-quality images. Simultaneously, the ACP utilizes a convolutional neural network, a transformer encoder, and a clustering module to extract classification information, which supports the enhancement process. The FIC module uses a cross-attention mechanism to merge the image and classification features, thus enhancing the overall performance of image enhancement. To ensure the generated images retain their structural integrity, Structural Similarity (SSIM) loss is employed. Experiments conducted on multiple ultrasound datasets reveal that our method surpasses existing techniques in terms of peak signal-to-noise ratio and SSIM scores. Clinically, our approach significantly improves image contrast and structural detail, leading to more accurate diagnoses. This diffusion-based strategy for image enhancement and classification feature fusion introduces a fresh perspective on preserving structure and enhancing detail in medical image processing. Our Code is available at https://github.com/ichbincn/Ultrasound-Enhancement.
ISSN:0098-3063
1558-4127
DOI:10.1109/TCE.2025.3540502