HDN：基于深度学习和非视线重建的经颅人脑光声成像框架

IF 4.8 2区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Computational Imaging Pub Date : 2025-08-11 DOI:10.1109/TCI.2025.3594073

Pengcheng Wan;Fan Zhang;Yuting Shen;Hulin Zhao;Xiran Cai;Xiaohua Feng;Fei Gao

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引用次数: 0

摘要

光声成像结合了光学成像的高对比度和超声成像的深穿透深度，在脑血管疾病检测中显示出巨大的潜力。然而，超声波在穿过颅骨组织时受到强烈的衰减和多重散射，导致采集到的光声信号失真。本文受深度学习和非视距成像原理的启发，提出了一种图像重建框架HDN (Hybrid deep -learning and non-line-of-sight)，该框架由信号提取部分和差分利用部分组成。信号提取部分用于校正失真信号并重建初始图像。差值利用部分用于进一步利用失真信号与校正信号之间的信号差，重构初始图像与目标图像之间的残差图像。在光声数字脑模拟数据集上的测试结果表明，与传统的延迟求和方法和基于深度学习的UNet方法相比，HDN在信号校正和图像重建方面都取得了更好的效果。具体到结构相似指数，成像结果HDN达到0.661，而延迟和方法的HDN为0.157，基于深度学习的HDN为0.305。

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HDN: Hybrid Deep-Learning and Non-Line-of-Sight Reconstruction Framework for Transcranial Photoacoustic Imaging of Human Brain

Photoacoustic imaging combines the high contrast of optical imaging with the deep penetration depth of ultrasonic imaging, showing great potential in cerebrovascular disease detection. However, the ultrasonic wave suffers strong attenuation and multi-scattering when it passes through the skull tissue, resulting in the distortion of the collected photoacoustic signal. In this paper, inspired by the principles of deep learning and non-line-of-sight imaging, we propose an image reconstruction framework named HDN (Hybrid Deep-learning and Non-line-of-sight), which consists of the signal extraction part and difference utilization part. The signal extraction part is used to correct the distorted signal and reconstruct an initial image. The difference utilization part is used to make further use of the signal difference between the distorted signal and corrected signal, reconstructing the residual image between the initial image and the target image. The test results on a photoacoustic digital brain simulation dataset show that compared with the traditional method (delay-and-sum) and deep-learning-based method (UNet), the HDN achieved superior performance in both signal correction and image reconstruction. Specifically for the structural similarity index, the HDN reached 0.661 in imaging results, compared to 0.157 for the delay-and-sum method and 0.305 for the deep-learning-based method.

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来源期刊

IEEE Transactions on Computational Imaging Mathematics-Computational Mathematics

CiteScore

8.20

自引率

7.40%

发文量

期刊介绍： The IEEE Transactions on Computational Imaging will publish articles where computation plays an integral role in the image formation process. Papers will cover all areas of computational imaging ranging from fundamental theoretical methods to the latest innovative computational imaging system designs. Topics of interest will include advanced algorithms and mathematical techniques, model-based data inversion, methods for image and signal recovery from sparse and incomplete data, techniques for non-traditional sensing of image data, methods for dynamic information acquisition and extraction from imaging sensors, software and hardware for efficient computation in imaging systems, and highly novel imaging system design.