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全景成像中颏孔的神经网络检测与分割

Neural Network Detection and Segmentation of Mental Foramen in Panoramic Imaging.

作者信息

Kats Lazar, Vered Marilena, Blumer Sigalit, Kats Eytan

出版信息

J Clin Pediatr Dent. 2020;44(3):168-173. doi: 10.17796/1053-4625-44.3.6. Epub 2020 Jun 17.

DOI:10.17796/1053-4625-44.3.6
PMID:32552450
Abstract

To apply the technique of deep learning on a small dataset of panoramic images for the detection and segmentation of the mental foramen (MF). In this study we used in-house dataset created within the School of Dental Medicine, Tel Aviv University. The dataset contained randomly chosen and anonymized 112 digital panoramic X-ray images and corresponding segmentations of MF. In order to solve the task of segmentation of the MF we used a single fully convolution neural network, that was based on U-net as well as a cascade architecture. 70% of the data were randomly chosen for training, 15% for validation and accuracy was tested on 15%. The model was trained using NVIDIA GeForce GTX 1080 GPU. The SPSS software, version 17.0 (Chicago, IL, USA) was used for the statistical analysis. The study was approved by the ethical committee of Tel Aviv University. The best results of the dice similarity coefficient ( DSC), precision, recall, MF-wise true positive rate (MF) and MF-wise false positive rate (MF) in single networks were 49.51%, 71.13%, 68.24%, 87.81% and 14.08%, respectively. The cascade of networks has shown better results than simple networks in recall and MF, which were 88.83%, 93.75%, respectively, while DSC and precision achieved the lowest values, 31.77% and 23.92%, respectively. Currently, the U-net, one of the most used neural network architectures for biomedical application, was effectively used in this study. Methods based on deep learning are extremely important for automatic detection and segmentation in radiology and require further development.

摘要

将深度学习技术应用于全景图像小数据集,以检测和分割颏孔(MF)。在本研究中,我们使用了特拉维夫大学牙医学院创建的内部数据集。该数据集包含随机选择并匿名化的112张数字化全景X线图像以及相应的颏孔分割图像。为了解决颏孔分割任务,我们使用了基于U-net的单全卷积神经网络以及级联架构。70%的数据被随机选择用于训练,15%用于验证,15%用于测试准确性。模型使用NVIDIA GeForce GTX 1080 GPU进行训练。使用SPSS软件17.0版(美国伊利诺伊州芝加哥)进行统计分析。该研究获得了特拉维夫大学伦理委员会的批准。单网络中骰子相似系数(DSC)、精确率、召回率、颏孔-wise真阳性率(MF)和颏孔-wise假阳性率(MF)的最佳结果分别为49.51%、71.13%、68.24%、87.81%和14.08%。级联网络在召回率和颏孔方面的结果优于简单网络,分别为88.83%和93.75%,而DSC和精确率达到最低值,分别为31.77%和23.92%。目前,U-net是生物医学应用中最常用的神经网络架构之一,在本研究中得到了有效应用。基于深度学习的方法对于放射学中的自动检测和分割极为重要,需要进一步发展。

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