医学
分割
脑出血
血肿
人工智能
放射科
计算机断层摄影术
深度学习
模式识别(心理学)
脑内血肿
计算机视觉
冲程(发动机)
图像分割
计算机断层血管造影
临床实习
断层摄影术
血管造影
神经影像学
作者
Nannan Yu,He Yu,Haonan Li,Nannan Ma,Chunai Hu,Jia Wang
出处
期刊:Stroke
[Lippincott Williams & Wilkins]
日期:2021-10-04
卷期号:53 (1): 167-176
被引量:66
标识
DOI:10.1161/strokeaha.120.032243
摘要
BACKGROUND AND PURPOSE: Hematoma volume (HV) is a significant diagnosis for determining the clinical stage and therapeutic approach for intracerebral hemorrhage (ICH). The aim of this study is to develop a robust deep learning segmentation method for the fast and accurate HV analysis using computed tomography. METHODS: A novel dimension reduction UNet (DR-UNet) model was developed for computed tomography image segmentation and HV measurement. Two data sets, 512 ICH patients with 12 568 computed tomography slices in the retrospective data set and 50 ICH patients with 1257 slices in the prospective data set, were used for network training, validation, and internal and external testing. Moreover, 13 irregular hematoma cases, 11 subdural and epidural hematoma cases, and 50 different HV cases into 3 groups (<30, 30-60, and >60 mL) were selected to further evaluate the robustness of DR-UNet. The image segmentation performance of DR-UNet was compared with those of UNet, the fuzzy clustering method, and the active contour method. The HV measurement performance was compared using DR-UNet, UNet, and the Coniglobus formula method. RESULTS: <0.0001). In the irregularly shaped hematoma group and the subdural and epidural hematoma group, DR-UNet was more robust than UNet in both hematoma segmentation and HV measurement. There is no statistical significance in segmentation accuracy among 3 different HV groups. CONCLUSIONS: DR-UNet can segment hematomas from the computed tomography scans of ICH patients and quantify the HV with better accuracy and greater efficiency than the main existing methods and with similar performance to expert clinicians. Due to robust performance and stable segmentation on different ICHs, DR-UNet could facilitate the development of deep learning systems for a variety of clinical applications.
科研通智能强力驱动
Strongly Powered by AbleSci AI