Classification based on the presence of skull fractures on curved maximum intensity skull projections by means of deep learning

Jakob Heimer, Michael J. Thali, Lars Ebert
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引用次数: 10

Abstract

Objectives

Postmortem computed tomography (PMCT) usually includes the generation of great amounts of imaging data, and is often reviewed by forensic pathologists. To allow a more resource-efficient diagnosis, deep neural networks may act as a pre-scanning tool in postmortem radiology. In this study, a deep neural network to classify cases depending on the presence skull fractures on curved maximum intensity projections (CMIP).

Methods

Calvarial CMIPs of each 75 cases with and without documented skull fractures were retrospectively generated from our database. Then, half of the data were randomly assigned to either training or validation. In supervised training, fractures were manually marked. During validation, each image received a gradual score between 0 and 1 predicting the likelihood of showing one or more fractures.

Results

With a total number of 100 networks trained, the average area under the Receiver Operating Characteristic curve (AUC) was 0.895. The best performing network had an AUC of 0.965. At a classification threshold of 0.79, the network classified fracture cases correctly with a sensitivity of 91.4% and a specificity of 87.5%.

Conclusion

Classification based on the existence of skull fractures on CMIPs with deep learning is feasible. For the purpose of pre-scanning PMCT data, a classification threshold of 0.75 with a sensitivity of 100% can be applied. A higher number of images of validated skull fractures available will increase the performance of the network. In the future, Deep learning might enable a more resource-efficient assessment in postmortem radiology.

Abstract Image

基于弯曲的最大强度颅骨投影是否存在颅骨骨折的深度学习分类
目的尸检计算机断层扫描(PMCT)通常包括产生大量的成像数据,并且经常被法医病理学家审查。为了实现更有效的诊断,深度神经网络可以作为死后放射学的预扫描工具。在本研究中,采用深度神经网络对颅骨骨折的弯曲最大强度投影(CMIP)进行分类。方法从我们的数据库中回顾性地生成75例有或无记录的颅骨骨折患者的CMIPs。然后,一半的数据被随机分配到训练组或验证组。在监督训练中,骨折是手工标记的。在验证过程中,每张图像获得0到1之间的渐进评分,预测显示一个或多个骨折的可能性。结果共训练100个神经网络,受试者工作特征曲线下面积(AUC)均值为0.895。最优网络的AUC为0.965。在0.79的分类阈值下,该网络对骨折病例的分类灵敏度为91.4%,特异性为87.5%。结论基于颅骨是否存在骨折进行深度学习分类是可行的。对于预扫描PMCT数据,可以采用0.75的分类阈值,灵敏度为100%。更多的有效颅骨骨折图像将提高网络的性能。在未来,深度学习可能会使死后放射学的评估更具资源效率。
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来源期刊
Journal of Forensic Radiology and Imaging
Journal of Forensic Radiology and Imaging RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
1.70
自引率
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