Regression-Based Line Detection Network for Delineation of Largely Deformed Brain Midline

Brain midline shift is often caused by various clinical conditions such as high intracranial pressure, which can be deadly. To facilitate clinical evaluation, automated methods have been proposed to classify whether midline shift is severe or not, e.g., larger than 5 mm away from the ideal midline. There are only limited methods using landmark or symmetry, attempting to provide more intuitive results such as midline delineation. However, landmark- or symmetry-based methods could be easily affected by anatomical variability and large brain deformations. In this study, we formulated the midline delineation as a skeleton extraction task and proposed a novel regression-based line detection network (RLDN) for the robust midline delineation especially in largely deformed brains. Basically, the proposed method includes three parts: (1) multi-scale line detection, (2) weighted line integration, and (3) regression-based refinement. The first two parts were used to capture high-level semantic and low-level detailed information to extract deformed midline, while the last part was utilized to regress more accurate midline positions. We validated the RLDN on 100 training and 28 testing subjects with a mean midline shift of 7 mm and the maximum shift of 16 mm (induced by hemorrhage). Experimental results show that our proposed method achieves state-of-the-art accuracy with a mean line difference of \(1.17\pm 0.72\) mm and F1-score of 0.78 from manual delineations. Our proposed robust midline delineation method is also beneficial for other cases such as midline deformation from tumor, traumatic brain injury, and abscess.

[1]  Jau-Min Wong,et al.  Automatic recognition of midline shift on brain CT images , 2010, Comput. Biol. Medicine.

[2]  Tze-Yun Leong,et al.  Automatic detection and quantification of brain midline shift using anatomical marker model , 2014, Comput. Medical Imaging Graph..

[3]  Guanglin Li,et al.  Automatic estimation of midline shift in patients with cerebral glioma based on enhanced voigt model and local symmetry , 2015, Australasian Physical & Engineering Sciences in Medicine.

[4]  Zhuowen Tu,et al.  Holistically-Nested Edge Detection , 2015, ICCV.

[5]  Andrew Zisserman,et al.  Very Deep Convolutional Networks for Large-Scale Image Recognition , 2014, ICLR.

[6]  Jian Sun,et al.  Deep Residual Learning for Image Recognition , 2015, 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[7]  Vincent Lepetit,et al.  LIFT: Learned Invariant Feature Transform , 2016, ECCV.

[8]  Xiaogang Wang,et al.  Pyramid Scene Parsing Network , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[9]  Guoying Zhao,et al.  SRN: Side-Output Residual Network for Object Symmetry Detection in the Wild , 2017, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[10]  Wei Shen,et al.  Hi-Fi: Hierarchical Feature Integration for Skeleton Detection , 2018, IJCAI.

[11]  Sasank Chilamkurthy,et al.  Deep learning algorithms for detection of critical findings in head CT scans: a retrospective study , 2018, The Lancet.

[12]  Rohit Ghosh,et al.  Development and Validation of Deep Learning Algorithms for Detection of Critical Findings in Head CT Scans , 2018, ArXiv.

[13]  Jinhui Tang,et al.  Richer Convolutional Features for Edge Detection , 2017, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[14]  Fan Yang,et al.  Multi-Scale Bidirectional FCN for Object Skeleton Extraction , 2018, AAAI.