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基于双路径融合网络的颅内动脉瘤分割

Intracranial Aneurysm Segmentation with a Dual-Path Fusion Network.

作者信息

Wang Ke, Zhang Yong, Fang Bin

机构信息

College of Computer Science, Chongqing University, Chongqing 400038, China.

出版信息

Bioengineering (Basel). 2025 Feb 15;12(2):185. doi: 10.3390/bioengineering12020185.

DOI:10.3390/bioengineering12020185
PMID:40001704
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11852351/
Abstract

Intracranial aneurysms (IAs), a significant medical concern due to their prevalence and life-threatening nature, pose challenges regarding diagnosis owing to their diminutive and variable morphology. There are currently challenges surrounding automating the segmentation of IAs, which is essential for diagnostic precision. Existing deep learning methods in IAs segmentation tend to emphasize semantic features at the expense of detailed information, potentially compromising segmentation quality. Our research introduces the innovative Dual-Path Fusion Network (DPF-Net), an advanced deep learning architecture crafted to refine IAs segmentation by adeptly incorporating detailed information. DPF-Net, with its unique resolution-preserving detail branch, ensures minimal loss of detail during feature extraction, while its cross-fusion module effectively promotes the connection of semantic information and finer detail features, enhancing segmentation precision. The network also integrates a detail aggregation module for effective fusion of multi-scale detail features. A view fusion strategy is employed to address spatial disruptions in patch generation, thereby improving feature extraction efficiency. Evaluated on the CADA dataset, DPF-Net achieves a remarkable mean Dice similarity coefficient (DSC) of 0.8967, highlighting its potential in automated IAs diagnosis in clinical settings. Furthermore, DPF-Net's outstanding performance on the BraTS 2020 MRI dataset for brain tumor segmentation with a mean DSC of 0.8535 further confirms its robustness and generalizability.

摘要

颅内动脉瘤(IAs)因其普遍性和危及生命的性质而成为重大医学问题,由于其体积微小且形态多变,在诊断方面面临挑战。目前在IAs分割自动化方面存在挑战,而这对于诊断精度至关重要。现有的IAs分割深度学习方法往往以牺牲详细信息为代价来强调语义特征,这可能会损害分割质量。我们的研究引入了创新的双路径融合网络(DPF-Net),这是一种先进的深度学习架构,旨在通过巧妙地整合详细信息来优化IAs分割。DPF-Net凭借其独特的保留分辨率的细节分支,确保在特征提取过程中细节损失最小,同时其交叉融合模块有效地促进了语义信息与更精细细节特征的连接,提高了分割精度。该网络还集成了一个细节聚合模块,用于有效融合多尺度细节特征。采用视图融合策略来解决补丁生成中的空间干扰问题,从而提高特征提取效率。在CADA数据集上进行评估时,DPF-Net实现了0.8967的显著平均骰子相似系数(DSC),突出了其在临床环境中IAs自动诊断的潜力。此外,DPF-Net在BraTS 2020脑肿瘤分割MRI数据集上的出色表现,平均DSC为0.8535,进一步证实了其鲁棒性和通用性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ac9f/11852351/64955a4c0455/bioengineering-12-00185-g010.jpg
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本文引用的文献

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Comput Med Imaging Graph. 2023 Dec;110:102313. doi: 10.1016/j.compmedimag.2023.102313. Epub 2023 Nov 24.
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A systematic review on intracranial aneurysm and hemorrhage detection using machine learning and deep learning techniques.基于机器学习和深度学习技术的颅内动脉瘤与出血检测的系统评价。
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Geometric Deep Learning Using Vascular Surface Meshes for Modality-Independent Unruptured Intracranial Aneurysm Detection.
基于血管表面网格的几何深度学习在模态独立颅内未破裂动脉瘤检测中的应用。
IEEE Trans Med Imaging. 2023 Nov;42(11):3451-3460. doi: 10.1109/TMI.2023.3288746. Epub 2023 Oct 27.
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FSTIF-UNet: A Deep Learning-Based Method Towards Automatic Segmentation of Intracranial Aneurysms in Un-Reconstructed 3D-RA.FSTIF-UNet:一种基于深度学习的方法,用于自动分割未重建的 3D-RA 中的颅内动脉瘤。
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A review of deep learning-based multiple-lesion recognition from medical images: classification, detection and segmentation.基于深度学习的医学图像多病灶识别综述:分类、检测和分割。
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Fully Automatic Liver and Tumor Segmentation from CT Image Using an AIM-Unet.使用AIM-Unet从CT图像中进行全自动肝脏和肿瘤分割。
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