Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images

Wei Tai Hsu; Obinna Agbodike; Jenhui Chen

doi:10.1109/ICASI60819.2024.10547886

Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images

Wei Tai Hsu, Obinna Agbodike, Jenhui Chen^*

^*Corresponding author for this work

Department of Computer Science and Information Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Scopus citations

Abstract

Ultrasound (US) imaging plays a pivotal role in medical diagnostics due to its non-invasiveness and semi-real-time imaging capabilities. However, the prevalent occurrence of speckle noise artifacts, originating from RF signal interference during the US image formation, poses a significant challenge by distorting crucial anatomical details. To address this problem, we propose an optimized U-Net model integrated with gated attention and trained using a physics-informed loss function. This approach enables the network to adeptly suppress noise distortions in US images during training. The integration of the attention mechanism is to facilitate effective capturing of long-range feature representations, while the physics-informed loss function is implemented to promote rapid convergence and self-adaptive learning, aligning with the physical constraints of interpretable US images with clinical relevance. Experimental validation conducted on the US-4 and BUSI datasets demonstrates competitive performance, indicating significant reduction of speckle noise. This study presents a niche methodology in the domain of medical image denoising aimed at improving US diagnostic accuracy and clinical outcomes through AI-driven advancements.

Original language	English
Title of host publication	Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024
Editors	Shoou-Jinn Chang, Sheng-Joue Young, Artde Donald Kin-Tak Lam, Liang-Wen Ji, Stephen D. Prior
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	409-411
Number of pages	3
ISBN (Electronic)	9798350394924
DOIs	https://doi.org/10.1109/ICASI60819.2024.10547886
State	Published - 2024
Event	10th International Conference on Applied System Innovation, ICASI 2024 - Kyoto, Japan Duration: 17 04 2024 → 21 04 2024

Publication series

Name	Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024

Conference

Conference	10th International Conference on Applied System Innovation, ICASI 2024
Country/Territory	Japan
City	Kyoto
Period	17/04/24 → 21/04/24

Bibliographical note

Publisher Copyright:
© 2024 IEEE.

Keywords

Attention
PINN
deep learning
image denoising
ultrasound

Access to Document

10.1109/ICASI60819.2024.10547886

Cite this

Hsu, W. T., Agbodike, O., & Chen, J. (2024). Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images. In S.-J. Chang, S.-J. Young, A. D. K.-T. Lam, L.-W. Ji, & S. D. Prior (Eds.), Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024 (pp. 409-411). (Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICASI60819.2024.10547886

Hsu, Wei Tai ; Agbodike, Obinna ; Chen, Jenhui. / Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images. Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024. editor / Shoou-Jinn Chang ; Sheng-Joue Young ; Artde Donald Kin-Tak Lam ; Liang-Wen Ji ; Stephen D. Prior. Institute of Electrical and Electronics Engineers Inc., 2024. pp. 409-411 (Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024).

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title = "Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images",

abstract = "Ultrasound (US) imaging plays a pivotal role in medical diagnostics due to its non-invasiveness and semi-real-time imaging capabilities. However, the prevalent occurrence of speckle noise artifacts, originating from RF signal interference during the US image formation, poses a significant challenge by distorting crucial anatomical details. To address this problem, we propose an optimized U-Net model integrated with gated attention and trained using a physics-informed loss function. This approach enables the network to adeptly suppress noise distortions in US images during training. The integration of the attention mechanism is to facilitate effective capturing of long-range feature representations, while the physics-informed loss function is implemented to promote rapid convergence and self-adaptive learning, aligning with the physical constraints of interpretable US images with clinical relevance. Experimental validation conducted on the US-4 and BUSI datasets demonstrates competitive performance, indicating significant reduction of speckle noise. This study presents a niche methodology in the domain of medical image denoising aimed at improving US diagnostic accuracy and clinical outcomes through AI-driven advancements.",

keywords = "Attention, PINN, deep learning, image denoising, ultrasound",

author = "Hsu, \{Wei Tai\} and Obinna Agbodike and Jenhui Chen",

note = "Publisher Copyright: {\textcopyright} 2024 IEEE.; 10th International Conference on Applied System Innovation, ICASI 2024 ; Conference date: 17-04-2024 Through 21-04-2024",

year = "2024",

doi = "10.1109/ICASI60819.2024.10547886",

language = "英语",

series = "Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024",

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pages = "409--411",

editor = "Shoou-Jinn Chang and Sheng-Joue Young and Lam, \{Artde Donald Kin-Tak\} and Liang-Wen Ji and Prior, \{Stephen D.\}",

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Hsu, WT, Agbodike, O & Chen, J 2024, Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images. in S-J Chang, S-J Young, ADK-T Lam, L-W Ji & SD Prior (eds), Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024. Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024, Institute of Electrical and Electronics Engineers Inc., pp. 409-411, 10th International Conference on Applied System Innovation, ICASI 2024, Kyoto, Japan, 17/04/24. https://doi.org/10.1109/ICASI60819.2024.10547886

Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images. / Hsu, Wei Tai; Agbodike, Obinna; Chen, Jenhui.
Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024. ed. / Shoou-Jinn Chang; Sheng-Joue Young; Artde Donald Kin-Tak Lam; Liang-Wen Ji; Stephen D. Prior. Institute of Electrical and Electronics Engineers Inc., 2024. p. 409-411 (Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images

AU - Hsu, Wei Tai

AU - Agbodike, Obinna

AU - Chen, Jenhui

PY - 2024

Y1 - 2024

N2 - Ultrasound (US) imaging plays a pivotal role in medical diagnostics due to its non-invasiveness and semi-real-time imaging capabilities. However, the prevalent occurrence of speckle noise artifacts, originating from RF signal interference during the US image formation, poses a significant challenge by distorting crucial anatomical details. To address this problem, we propose an optimized U-Net model integrated with gated attention and trained using a physics-informed loss function. This approach enables the network to adeptly suppress noise distortions in US images during training. The integration of the attention mechanism is to facilitate effective capturing of long-range feature representations, while the physics-informed loss function is implemented to promote rapid convergence and self-adaptive learning, aligning with the physical constraints of interpretable US images with clinical relevance. Experimental validation conducted on the US-4 and BUSI datasets demonstrates competitive performance, indicating significant reduction of speckle noise. This study presents a niche methodology in the domain of medical image denoising aimed at improving US diagnostic accuracy and clinical outcomes through AI-driven advancements.

AB - Ultrasound (US) imaging plays a pivotal role in medical diagnostics due to its non-invasiveness and semi-real-time imaging capabilities. However, the prevalent occurrence of speckle noise artifacts, originating from RF signal interference during the US image formation, poses a significant challenge by distorting crucial anatomical details. To address this problem, we propose an optimized U-Net model integrated with gated attention and trained using a physics-informed loss function. This approach enables the network to adeptly suppress noise distortions in US images during training. The integration of the attention mechanism is to facilitate effective capturing of long-range feature representations, while the physics-informed loss function is implemented to promote rapid convergence and self-adaptive learning, aligning with the physical constraints of interpretable US images with clinical relevance. Experimental validation conducted on the US-4 and BUSI datasets demonstrates competitive performance, indicating significant reduction of speckle noise. This study presents a niche methodology in the domain of medical image denoising aimed at improving US diagnostic accuracy and clinical outcomes through AI-driven advancements.

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KW - PINN

KW - deep learning

KW - image denoising

KW - ultrasound

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BT - Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024

A2 - Chang, Shoou-Jinn

A2 - Young, Sheng-Joue

A2 - Lam, Artde Donald Kin-Tak

A2 - Ji, Liang-Wen

A2 - Prior, Stephen D.

PB - Institute of Electrical and Electronics Engineers Inc.

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Y2 - 17 April 2024 through 21 April 2024

ER -

Hsu WT, Agbodike O, Chen J. Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images. In Chang SJ, Young SJ, Lam ADKT, Ji LW, Prior SD, editors, Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024. Institute of Electrical and Electronics Engineers Inc. 2024. p. 409-411. (Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024). doi: 10.1109/ICASI60819.2024.10547886

Attentive U-Net with Physics-Informed Loss for Noise Suppression in Medical Ultrasound Images

Abstract

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Keywords

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