Winter Patrick, Berhane Haben, Moore Jackson E, Aristova Maria, Reichl Teresa, Wollenberg Julian, Richter Adam, Jarvis Kelly B, Patel Abhinav, Caprio Fan Z, Abdalla Ramez N, Ansari Sameer A, Markl Michael, Schnell Susanne
Department of Medical Physics, Faculty of Mathematics and Natural Sciences, University of Greifswald, Greifswald, Germany.
Department of Radiology, Northwestern University, Feinberg School of Medicine, Chicago, IL, United States.
Front Radiol. 2024 Jun 4;4:1385424. doi: 10.3389/fradi.2024.1385424. eCollection 2024.
Intracranial 4D flow MRI enables quantitative assessment of hemodynamics in patients with intracranial atherosclerotic disease (ICAD). However, quantitative assessments are still challenging due to the time-consuming vessel segmentation, especially in the presence of stenoses, which can often result in user variability. To improve the reproducibility and robustness as well as to accelerate data analysis, we developed an accurate, fully automated segmentation for stenosed intracranial vessels using deep learning.
154 dual-VENC 4D flow MRI scans (68 ICAD patients with stenosis, 86 healthy controls) were retrospectively selected. Manual segmentations were used as ground truth for training. For automated segmentation, deep learning was performed using a 3D U-Net. 20 randomly selected cases (10 controls, 10 patients) were separated and solely used for testing. Cross-sectional areas and flow parameters were determined in the Circle of Willis (CoW) and the sinuses. Furthermore, the flow conservation error was calculated. For statistical comparisons, Dice scores (DS), Hausdorff distance (HD), average symmetrical surface distance (ASSD), Bland-Altman analyses, and interclass correlations were computed using the manual segmentations from two independent observers as reference. Finally, three stenosis cases were analyzed in more detail by comparing the 4D flow-based segmentations with segmentations from black blood vessel wall imaging (VWI).
Training of the network took approximately 10 h and the average automated segmentation time was 2.2 ± 1.0 s. No significant differences in segmentation performance relative to two independent observers were observed. For the controls, mean DS was 0.85 ± 0.03 for the CoW and 0.86 ± 0.06 for the sinuses. Mean HD was 7.2 ± 1.5 mm (CoW) and 6.6 ± 3.7 mm (sinuses). Mean ASSD was 0.15 ± 0.04 mm (CoW) and 0.22 ± 0.17 mm (sinuses). For the patients, the mean DS was 0.85 ± 0.04 (CoW) and 0.82 ± 0.07 (sinuses), the HD was 8.4 ± 3.1 mm (CoW) and 5.7 ± 1.9 mm (sinuses) and the mean ASSD was 0.22 ± 0.10 mm (CoW) and 0.22 ± 0.11 mm (sinuses). Small bias and limits of agreement were observed in both cohorts for the flow parameters. The assessment of the cross-sectional lumen areas in stenosed vessels revealed very good agreement (ICC: 0.93) with the VWI segmentation but a consistent overestimation (bias ± LOA: 28.1 ± 13.9%).
Deep learning was successfully applied for fully automated segmentation of stenosed intracranial vasculatures using 4D flow MRI data. The statistical analysis of segmentation and flow metrics demonstrated very good agreement between the CNN and manual segmentation and good performance in stenosed vessels. To further improve the performance and generalization, more ICAD segmentations as well as other intracranial vascular pathologies will be considered in the future.
颅内四维血流磁共振成像(4D flow MRI)能够对颅内动脉粥样硬化疾病(ICAD)患者的血流动力学进行定量评估。然而,由于血管分割耗时,尤其是在存在狭窄的情况下,定量评估仍然具有挑战性,这往往会导致用户之间的差异。为了提高可重复性和稳健性并加速数据分析,我们利用深度学习开发了一种针对狭窄颅内血管的准确、全自动分割方法。
回顾性选取154例双速度编码(dual-VENC)4D flow MRI扫描数据(68例患有狭窄的ICAD患者,86例健康对照)。手动分割用作训练的基准真值。对于自动分割,使用3D U-Net进行深度学习。随机选取20例病例(10例对照,10例患者)并单独用于测试。在Willis环(CoW)和静脉窦中确定横截面积和血流参数。此外,计算血流守恒误差。为了进行统计比较,使用两名独立观察者的手动分割作为参考,计算Dice分数(DS)、豪斯多夫距离(HD)、平均对称表面距离(ASSD)、Bland-Altman分析和组内相关性。最后,通过将基于4D血流的分割与黑血血管壁成像(VWI)的分割进行比较,对三例狭窄病例进行更详细的分析。
网络训练耗时约10小时,平均自动分割时间为2.2±1.0秒。相对于两名独立观察者,未观察到分割性能的显著差异。对于对照组,CoW的平均DS为0.85±0.03,静脉窦的平均DS为0.86±0.06。平均HD为7.2±1.5毫米(CoW)和6.6±3.毫米(静脉窦)。平均ASSD为0.15±0.04毫米(CoW)和0.22±0.17毫米(静脉窦)。对于患者,平均DS为0.85±0.04(CoW)和0.82±0.07(静脉窦),HD为8.4±3.1毫米(CoW)和5.7±1.9毫米(静脉窦),平均ASSD为0.22±0.10毫米(CoW)和0.22±0.11毫米(静脉窦)。在两个队列中,血流参数均观察到较小的偏差和一致性界限。对狭窄血管横截面积腔的评估显示与VWI分割具有非常好的一致性(组内相关系数:0.93),但存在一致的高估(偏差±一致性界限:28.1±13.9%)。
深度学习成功应用于利用4D flow MRI数据对狭窄颅内血管系统进行全自动分割。分割和血流指标的统计分析表明,卷积神经网络(CNN)与手动分割之间具有非常好的一致性,并且在狭窄血管中表现良好。为了进一步提高性能和通用性,未来将考虑更多的ICAD分割以及其他颅内血管病变。
