Transfer Learning with Pretrained Convolutional Neural Network for Automated Gleason Grading of Prostate Cancer Tissue Microarrays.

IF 1.3 Q4 ENGINEERING, BIOMEDICAL Journal of Medical Signals & Sensors Pub Date : 2024-02-14 eCollection Date: 2024-01-01 DOI:10.4103/jmss.jmss_42_22

Parisa Gifani, Ahmad Shalbaf

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Abstract

Background: The Gleason grading system has been the most effective prediction for prostate cancer patients. This grading system provides this possibility to assess prostate cancer's aggressiveness and then constitutes an important factor for stratification and therapeutic decisions. However, determining Gleason grade requires highly-trained pathologists and is time-consuming and tedious, and suffers from inter-pathologist variability. To remedy these limitations, this paper introduces an automatic methodology based on transfer learning with pretrained convolutional neural networks (CNNs) for automatic Gleason grading of prostate cancer tissue microarray (TMA).

Methods: Fifteen pretrained (CNNs): Efficient Nets (B0-B5), NasNetLarge, NasNetMobile, InceptionV3, ResNet-50, SeResnet 50, Xception, DenseNet121, ResNext50, and inception_resnet_v2 were fine-tuned on a dataset of prostate carcinoma TMA images. Six pathologists separately identified benign and cancerous areas for each prostate TMA image by allocating benign, 3, 4, or 5 Gleason grade for 244 patients. The dataset was labeled by these pathologists and majority vote was applied on pixel-wise annotations to obtain a unified label.

Results: Results showed the NasnetLarge architecture is the best model among them in the classification of prostate TMA images of 244 patients with accuracy of 0.93 and area under the curve of 0.98.

Conclusion: Our study can act as a highly trained pathologist to categorize the prostate cancer stages with more objective and reproducible results.

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利用预训练卷积神经网络进行迁移学习，实现前列腺癌组织芯片格雷欣分级自动化

背景：格里森分级系统一直是对前列腺癌患者最有效的预测方法。该分级系统为评估前列腺癌的侵袭性提供了可能，进而成为分层和治疗决策的重要因素。然而，确定格里森分级需要训练有素的病理学家，既费时又繁琐，而且病理学家之间也存在差异。为了弥补这些局限性，本文介绍了一种基于迁移学习的自动方法，利用经过预训练的卷积神经网络（CNN）对前列腺癌组织芯片（TMA）进行自动格里森分级：方法：15 个预训练卷积神经网络（CNN）：在前列腺癌 TMA 图像数据集上对 Efficient Nets (B0-B5)、NasNetLarge、NasNetMobile、InceptionV3、ResNet-50、SeResnet 50、Xception、DenseNet121、ResNext50 和 inception_resnet_v2 进行了微调。六位病理学家为 244 名患者的每张前列腺 TMA 图像分配良性、3 级、4 级或 5 级 Gleason 等级，分别确定良性和癌变区域。这些病理学家对数据集进行标注，并对像素标注进行多数票表决，以获得统一的标注：结果表明，NasnetLarge 架构是对 244 名患者的前列腺 TMA 图像进行分类的最佳模型，准确率为 0.93，曲线下面积为 0.98：我们的研究可作为训练有素的病理学家对前列腺癌进行分期，结果更客观、更可重复。

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

Journal of Medical Signals & Sensors ENGINEERING, BIOMEDICAL-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

33 weeks

期刊介绍： JMSS is an interdisciplinary journal that incorporates all aspects of the biomedical engineering including bioelectrics, bioinformatics, medical physics, health technology assessment, etc. Subject areas covered by the journal include: - Bioelectric: Bioinstruments Biosensors Modeling Biomedical signal processing Medical image analysis and processing Medical imaging devices Control of biological systems Neuromuscular systems Cognitive sciences Telemedicine Robotic Medical ultrasonography Bioelectromagnetics Electrophysiology Cell tracking - Bioinformatics and medical informatics: Analysis of biological data Data mining Stochastic modeling Computational genomics Artificial intelligence & fuzzy Applications Medical softwares Bioalgorithms Electronic health - Biophysics and medical physics: Computed tomography Radiation therapy Laser therapy - Education in biomedical engineering - Health technology assessment - Standard in biomedical engineering.