Glomerular Basement Membrane Thickness Estimation and Stratification via Active Semi-Supervised Learning Model.

IF 4.3 3区医学 Q1 UROLOGY & NEPHROLOGY

American Journal of Nephrology Pub Date : 2025-04-15 DOI:10.1159/000542658

Nico Curti, Gianluca Carlini, Sabrina Valente, Enrico Giampieri, Alessandra Merlotti, Daniel Remondini, Gaetano La Manna, Gastone Castellani, Gianandrea Pasquinelli

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引用次数: 0

Abstract

Introduction: The measure of glomerular basement membrane (GBM) thickness is used as diagnostic criteria for kidney glomerular diseases. The GBM thickness measurement, a time-consuming task, is performed by expert pathologists on transmission electron microscopy (TEM) images; therefore, it is affected by subjectivity and reproducibility issues.

Methods: Here we introduce a fully automated pipeline for the GBM segmentation and successive thickness estimation, starting from TEM images. This method is based on an active semi-supervised learning training procedure of a convolutional neural network model. Starting from the areas automatically identified by the model, we provide a robust measurement of membrane thickness using pixels distance matrix and computer vision techniques. Using these values, we trained a machine learning model to automatically determine the GBM thickness. To verify the accuracy of the method, we compared the predicted results with the full iconographic materials and diagnostic record reports from 42 renal biopsies having normal thickness (n = 21), thin (n = 10), thick GBM (n = 11).

Results: The obtained segmentations were used for the automated estimation of GBM thickness via computer vision algorithms and compared with manual measurements, obtaining a correlation of Pearson's R2 of 0.85. The GBM thickness was stratified into 3 classes, namely, normal, thin, thick, with a 0.63 Matthews correlation coefficient and a 0.76 accuracy.

Conclusion: The proposed pipeline obtained state-of-the-art performance in GBM segmentation, proving its robustness under image variations, such as magnification, contrast, and complex geometrical shapes. Automated measures could assist clinicians in standard clinical practice speeding up routine procedures with high diagnostic accuracy.

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基于主动半监督学习模型的肾小球基底膜厚度估计与分层。

肾小球基底膜（Glomerular basal Membrane， GBM）厚度的测定是肾小球疾病的诊断标准。GBM厚度测量是一项耗时的任务，由病理学专家对透射电子显微镜（TEM）图像进行测量，因此受主观性和可重复性问题的影响。方法：本文介绍了一种从TEM图像开始的GBM分割和连续厚度估计的全自动流水线。该方法基于卷积神经网络模型的主动半监督学习训练过程。从模型自动识别的区域开始，我们使用像素距离矩阵和计算机视觉技术提供了膜厚度的鲁棒测量。使用这些值，我们训练了一个机器学习模型来自动确定GBM的厚度。为了验证该方法的准确性，我们将预测结果与42例肾活检的完整影像学资料和诊断记录报告进行了比较，其中包括正常厚（21例）、薄（10例）、厚- gbm（11例）。结果：获得的分割结果用于计算机视觉算法自动估计GBM厚度，并与人工测量结果进行比较，Pearson’s R2为0.85。将GBM厚度分为正常、薄、厚3类，马修斯相关系数为0.63，精度为0.76。结论：所提出的管道在GBM分割中获得了最先进的性能，证明了其在图像变化（如放大倍数、对比度和复杂几何形状）下的鲁棒性。自动化测量可以帮助临床医生在标准临床实践中加快常规程序，具有很高的诊断准确性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

American Journal of Nephrology 医学-泌尿学与肾脏学

CiteScore

7.50

自引率

2.40%

发文量

审稿时长

4-8 weeks

期刊介绍： The ''American Journal of Nephrology'' is a peer-reviewed journal that focuses on timely topics in both basic science and clinical research. Papers are divided into several sections, including: