Banzato T, Bonsembiante F, Aresu L, Gelain M E, Burti S, Zotti A
Department of Animal Medicine, Production and Health, University of Padua, Viale dell'Università 16, 35020 Legnaro, Padua, Italy.
Department of Comparative Biomedicine and Food Science, University of Padua, Viale dell'Università 16, 35020 Legnaro, Padua, Italy.
Vet J. 2018 Mar;233:35-40. doi: 10.1016/j.tvjl.2017.12.026. Epub 2018 Jan 3.
The aim of this methodological study was to develop a deep convolutional neural network (DNN) to detect degenerative hepatic disease from ultrasound images of the liver in dogs and to compare the diagnostic accuracy of the newly developed DNN with that of serum biochemistry and cytology on the same samples, using histopathology as a standard. Dogs with suspected hepatic disease that had no prior history of neoplastic disease, no hepatic nodular pathology, no ascites and ultrasonography performed 24h prior to death were included in the study (n=52). Ultrasonography and serum biochemistry were performed as part of the routine clinical evaluation. On the basis of histopathology, dogs were categorised as 'normal' (n=8), or having 'vascular abnormalities'(n=8), or 'inflammatory'(n=0), 'neoplastic' (n=4) or 'degenerative'(n=32) disease; dogs with 'neoplastic' disease were excluded from further analysis. On cytological evaluation, dogs were categorised as 'normal' (n=11), or having 'inflammatory' (n=0), 'neoplastic' (n=4) or 'degenerative' (n=37) disease. Dogs were categorised as having 'degenerative' (n=32) or 'non-degenerative' (n=16) liver disease for analysis due to the limited sample size. The DNN was developed using a transfer learning methodology on a pre-trained neural network that was retrained and fine-tuned to our data set. The resultant DNN had a high diagnostic accuracy for degenerative liver disease (area under the curve 0.91; sensitivity 100%; specificity 82.8%). Cytology and serum biochemical markers (alanine transaminase and aspartate transaminase) had poor diagnostic accuracy in the detection of degenerative liver disease. The DNN outperformed all the other non-invasive diagnostic tests in the detection of degenerative liver disease.
这项方法学研究的目的是开发一种深度卷积神经网络(DNN),用于从犬类肝脏的超声图像中检测退行性肝病,并将新开发的DNN与血清生化和细胞学对相同样本的诊断准确性进行比较,以组织病理学作为标准。研究纳入了疑似患有肝病、无肿瘤疾病既往史、无肝结节病理、无腹水且在死亡前24小时进行过超声检查的犬只(n = 52)。超声检查和血清生化检查作为常规临床评估的一部分进行。根据组织病理学,犬只被分类为“正常”(n = 8)、患有“血管异常”(n = 8)、“炎症”(n = 0)、“肿瘤”(n = 4)或“退行性”(n = 32)疾病;患有“肿瘤”疾病的犬只被排除在进一步分析之外。在细胞学评估中,犬只被分类为“正常”(n = 11)、患有“炎症”(n = 0)、“肿瘤”(n = 4)或“退行性”(n = 37)疾病。由于样本量有限,犬只被分类为患有“退行性”(n = 32)或“非退行性”(n = 16)肝病进行分析。DNN是使用迁移学习方法在预训练神经网络上开发的,该网络针对我们的数据集进行了重新训练和微调。所得的DNN对退行性肝病具有较高的诊断准确性(曲线下面积为0.91;敏感性为100%;特异性为82.8%)。细胞学和血清生化标志物(丙氨酸转氨酶和天冬氨酸转氨酶)在检测退行性肝病方面的诊断准确性较差。在检测退行性肝病方面,DNN的表现优于所有其他非侵入性诊断测试。
