EGDNet: an efficient glomerular detection network for multiple anomalous pathological feature in glomerulonephritis

Saba Ghazanfar Ali, Xiaoxia Wang, Ping Li, Huating Li, Po Yang, Younhyun Jung, Jing Qin, Jinman Kim, Bin Sheng
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Abstract

Glomerulonephritis (GN) is a severe kidney disorder in which the tissues in the kidney become inflamed and have problems filtering waste from the blood. Typical approaches for GN diagnosis require a specialist’s examination of pathological glomerular features (PGF) in pathology images of a patient. These PGF are primarily analyzed via manual quantitative evaluation, which is a time-consuming, labor-intensive, and error-prone task for doctors. Thus, automatic and accurate detection of PGF is crucial for the efficient diagnosis of GN and other kidney-related diseases. Recent advances in convolutional neural network-based deep learning methods have shown the capability of learning complex structural variants with promising detection results in medical image applications. However, these methods are not directly applicable to glomerular detection due to large spatial and structural variability and inter-class imbalance. Thus, we propose an efficient glomerular detection network (EGDNet) for the first time for seven types of PGF detection. Our EGDNet consists of four modules: (i) a hybrid data augmentation strategy to resolve dataset problems, (ii) an efficient intersection over unit balancing module for uniform sampling of hard and easy samples, (iii) a feature pyramid balancing module to obtain balanced multi-scale features for robust detection, and (iv) balanced L1 regression loss which alleviates the impact of anomalous data for multi-PGF detection. We also formulated a private dataset of seven PGF from an affiliated hospital in Shanghai, China. Experiments on the dataset show that our EGDNet outperforms state-of-the-art methods by achieving superior accuracy of 91.2\(\%\), 94.9\(\%\), and 94.2\(\%\) on small, medium, and large pathological features, respectively.

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EGDNet:针对肾小球肾炎多种异常病理特征的高效肾小球检测网络
肾小球肾炎(GN)是一种严重的肾脏疾病,肾脏组织发炎,无法过滤血液中的废物。诊断肾小球肾炎的典型方法需要专家检查患者病理图像中的病理肾小球特征(PGF)。这些病理肾小球特征主要通过人工定量评估进行分析,这对医生来说是一项耗时、耗力且容易出错的工作。因此,自动、准确地检测 PGF 对于有效诊断 GN 和其他肾脏相关疾病至关重要。基于卷积神经网络的深度学习方法的最新进展表明,这些方法具有学习复杂结构变体的能力,在医学图像应用中具有良好的检测效果。然而,由于空间和结构变异性大以及类间不平衡,这些方法并不能直接用于肾小球检测。因此,我们首次提出了一种高效的肾小球检测网络(EGDNet),用于七种类型的 PGF 检测。我们的 EGDNet 由四个模块组成:(i) 混合数据增强策略以解决数据集问题;(ii) 高效的单位交集平衡模块以实现难样本和易样本的均匀采样;(iii) 特征金字塔平衡模块以获得均衡的多尺度特征以实现鲁棒检测;(iv) 均衡的 L1 回归损失可减轻异常数据对多 PGF 检测的影响。我们还建立了一个包含 7 个 PGF 的私有数据集,这些数据来自中国上海的一家附属医院。在该数据集上的实验表明,我们的EGDNet优于最先进的方法,在小、中、大病理特征上的准确率分别达到91.2%、94.9%和94.2%。
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