Beyaz Salih, Açıcı Koray, Sümer Emre
Başkent Üniversitesi Adana Turgut Noyan Eğitim ve Araştırma Merkezi Ortopedi ve Travmatoloji Kliniği, 01240 Yüreğir, Adana, Türkiye.
Jt Dis Relat Surg. 2020;31(2):175-183. doi: 10.5606/ehc.2020.72163. Epub 2020 Mar 26.
This study aims to detect frontal pelvic radiograph femoral neck fracture using deep learning techniques.
This retrospective study was conducted between January 2013 and January 2018. A total of 234 frontal pelvic X-ray images collected from 65 patients (32 males, 33 females; mean age 74.9 years; range, 33 to 89 years) were augmented to 2106 images to achieve a satisfactory dataset. A total of 1,341 images were fractured femoral necks while 765 were non-fractured ones. The proposed convolutional neural network (CNN) architecture contained five blocks, each containing a convolutional layer, batch normalization layer, rectified linear unit, and maximum pooling layer. After the last block, a dropout layer existed with a probability of 0.5. The last three layers of the architecture were a fully connected layer of two classes, a softmax layer and a classification layer that computes cross entropy loss. The training process was terminated after 50 epochs and an Adam Optimizer was used. Learning rate was dropped by a factor of 0.5 on every five epochs. To reduce overfitting, regularization term was added to the weights of the loss function. The training process was repeated for pixel sizes 50x50, 100x100, 200x200, and 400x400. The genetic algorithm (GA) approach was employed to optimize the hyperparameters of the CNN architecture and to minimize the error after testing the model created by the CNN architecture in the training phase.
Performance in terms of sensitivity, specificity, accuracy, F1 score, and Cohen's kappa coefficient were evaluated using five- fold cross validation tests. Best performance was obtained when cropped images were rescaled to 50x50 pixels. The kappa metric showed more reliable classifier performance when 50x50 pixels image size was used to feed the CNN. The classifier performance was more reliable according to other image sizes. Sensitivity and specificity rates were computed to be 83% and 73%, respectively. With the inclusion of the GA, this rate increased by 1.6%. The detection rate of fractured bones was found to be 83%. A kappa coefficient of 55% was obtained, indicating an acceptable agreement.
This experimental study utilized deep learning techniques in the detection of bone fractures in radiography. Although the dataset was unbalanced, the results can be considered promising. It was observed that use of smaller image size decreases computational cost and provides better results according to evaluation metrics.
本研究旨在利用深度学习技术检测骨盆正位X线片上的股骨颈骨折。
本回顾性研究于2013年1月至2018年1月进行。从65例患者(32例男性,33例女性;平均年龄74.9岁;范围33至89岁)收集了234张骨盆正位X线图像,并将其扩充至2106张图像,以获得一个令人满意的数据集。其中1341张图像为股骨颈骨折,765张为无骨折。所提出的卷积神经网络(CNN)架构包含五个模块,每个模块包含一个卷积层、批归一化层、修正线性单元和最大池化层。在最后一个模块之后,存在一个概率为0.5的随机失活层。该架构的最后三层是一个两类全连接层、一个softmax层和一个计算交叉熵损失的分类层。训练过程在50个轮次后终止,并使用Adam优化器。每五个轮次学习率降低0.5倍。为减少过拟合,在损失函数的权重中添加正则化项。针对像素大小为50x50、100x100、200x200和400x400重复训练过程。采用遗传算法(GA)方法优化CNN架构的超参数,并在测试训练阶段由CNN架构创建的模型后最小化误差。
使用五折交叉验证测试评估敏感性、特异性、准确性、F1分数和科恩kappa系数方面的性能。当裁剪后的图像重新缩放到50x50像素时获得最佳性能。当使用50x50像素图像大小输入CNN时,kappa指标显示出更可靠的分类器性能。根据其他图像大小,分类器性能也更可靠。敏感性和特异性率分别计算为83%和73%。加入GA后,该率提高了1.6%。骨折骨的检测率为83%。获得的kappa系数为55%,表明一致性可接受。
本实验研究利用深度学习技术检测X线摄影中的骨折。尽管数据集不均衡,但结果可被认为是有前景的。观察到使用较小图像大小可降低计算成本,并根据评估指标提供更好的结果。
