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WHA-Net:一种用于眼底图像中准确假性视乳头水肿分类的低复杂度混合模型。

WHA-Net: A Low-Complexity Hybrid Model for Accurate Pseudopapilledema Classification in Fundus Images.

作者信息

Pei Junpeng, Wang Yousong, Ge Mingliang, Li Jun, Li Yixing, Wang Wei, Zhou Xiaohong

机构信息

School of Health Science and Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China.

PLA Naval Medical Center, Naval Medical University, Shanghai 200433, China.

出版信息

Bioengineering (Basel). 2025 May 21;12(5):550. doi: 10.3390/bioengineering12050550.

DOI:10.3390/bioengineering12050550
PMID:40428169
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12108818/
Abstract

The fundus manifestations of pseudopapilledema closely resemble those of optic disc edema, making their differentiation particularly challenging in certain clinical situations. However, rapid and accurate diagnosis is crucial for alleviating patient anxiety and guiding treatment strategies. This study proposes an efficient low-complexity hybrid model, WHA-Net, which innovatively integrates three core modules to achieve precise auxiliary diagnosis of pseudopapilledema. First, the wavelet convolution (WTC) block is introduced to enhance the model's characterization capability for vessel and optic disc edge details in fundus images through 2D wavelet transform and deep convolution. Additionally, the hybrid attention inverted residual (HAIR) block is incorporated to extract critical features such as vascular morphology, hemorrhages, and exudates. Finally, the Agent-MViT module effectively captures the continuity features of optic disc contours and retinal vessels in fundus images while reducing the computational complexity of traditional Transformers. The model was trained and evaluated on a dataset of 1793 rigorously curated fundus images, comprising 895 normal optic discs, 485 optic disc edema (ODE), and 413 pseudopapilledema (PPE) cases. On the test set, the model achieved outstanding performance, with 97.79% accuracy, 95.55% precision, 95.69% recall, and 98.53% specificity. Comparative experiments confirm the superiority of WHA-Net in classification tasks, while ablation studies validate the effectiveness and rationality of each module's combined design. This research provides a clinically valuable solution for the automated differential diagnosis of pseudopapilledema, with both computational efficiency and diagnostic reliability.

摘要

假性视乳头水肿的眼底表现与视盘水肿极为相似,这使得在某些临床情况下二者的鉴别极具挑战性。然而,快速准确的诊断对于缓解患者焦虑及指导治疗策略至关重要。本研究提出了一种高效低复杂度的混合模型WHA-Net,该模型创新性地整合了三个核心模块,以实现对假性视乳头水肿的精确辅助诊断。首先,引入小波卷积(WTC)模块,通过二维小波变换和深度卷积增强模型对眼底图像中血管和视盘边缘细节的表征能力。此外,并入混合注意力倒置残差(HAIR)模块,以提取血管形态、出血和渗出物等关键特征。最后,Agent-MViT模块有效捕捉眼底图像中视盘轮廓和视网膜血管的连续性特征,同时降低传统Transformer的计算复杂度。该模型在一个由1793张经过严格筛选的眼底图像组成的数据集上进行训练和评估,该数据集包含895个正常视盘、485个视盘水肿(ODE)和413个假性视乳头水肿(PPE)病例。在测试集上,该模型表现出色,准确率为97.79%,精确率为95.55%,召回率为95.69%,特异性为98.53%。对比实验证实了WHA-Net在分类任务中的优越性,而消融研究验证了每个模块组合设计的有效性和合理性。本研究为假性视乳头水肿的自动鉴别诊断提供了一种具有临床价值的解决方案,兼具计算效率和诊断可靠性。

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Artificial Intelligence to Differentiate Pediatric Pseudopapilledema and True Papilledema on Fundus Photographs.利用人工智能在眼底照片上鉴别儿童假性视乳头水肿和真性视乳头水肿
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