Li Ran, Zheng Jie, Zayed Mohamed A, Saffitz Jeffrey E, Woodard Pamela K, Jha Abhinav K
Mallinckrodt Institute of Radiology, Washington University in St. Louis, St. Louis, MO, United States.
Department of Biomedical Engineering, Washington University in St. Louis, St. Louis, MO, United States.
Front Cardiovasc Med. 2023 May 24;10:1127653. doi: 10.3389/fcvm.2023.1127653. eCollection 2023.
A reliable and automated method to segment and classify carotid artery atherosclerotic plaque components is needed to efficiently analyze multi-weighted magnetic resonance (MR) images to allow their integration into patient risk assessment for ischemic stroke. Certain plaque components such as lipid-rich necrotic core (LRNC) with hemorrhage suggest a greater likelihood of plaque rupture and stroke event. Assessment for presence and extent of LRNC could assist in directing treatment with impact upon patient outcomes.
To address the need to accurately determine the presence and extent of plaque components on carotid plaque MRI, we proposed a two-staged deep-learning-based approach that consists of a convolutional neural network (CNN), followed by a Bayesian neural network (BNN). The rationale for the two-stage network approach is to account for the class imbalance of vessel wall and background by providing an attention mask to the BNN. A unique feature of the network training was to use ground truth defined by both high-resolution MRI data and histopathology. More specifically, standard resolution 1.5 T in vivo MR image sets with corresponding high resolution 3.0 T MR image sets and histopathology image sets were used to define ground-truth segmentations. Of these, data from 7 patients was used for training and from the remaining two was used for testing the proposed method. Next, to evaluate the generalizability of the method, we tested the method with an additional standard resolution 3.0 T in vivo data set of 23 patients obtained from a different scanner.
Our results show that the proposed method yielded accurate segmentation of carotid atherosclerotic plaque and outperforms not only manual segmentation by trained readers, who did not have access to the ex vivo or histopathology data, but also three state-of-the-art deep-learning-based segmentation methods. Further, the proposed approach outperformed a strategy where the ground truth was generated without access to the high resolution ex vivo MRI and histopathology. The accurate performance of this method was also observed in the additional 23-patient dataset from a different scanner.
In conclusion, the proposed method provides a mechanism to perform accurate segmentation of the carotid atherosclerotic plaque in multi-weighted MRI. Further, our study shows the advantages of using high-resolution imaging and histology to define ground truth for training deep-learning-based segmentation methods.
需要一种可靠的自动化方法来分割和分类颈动脉粥样硬化斑块成分,以便有效地分析多加权磁共振(MR)图像,从而将其纳入缺血性中风患者的风险评估中。某些斑块成分,如伴有出血的富含脂质的坏死核心(LRNC),提示斑块破裂和中风事件的可能性更大。评估LRNC的存在和范围有助于指导治疗,对患者预后产生影响。
为满足准确确定颈动脉斑块MRI上斑块成分的存在和范围的需求,我们提出了一种基于深度学习的两阶段方法,该方法由卷积神经网络(CNN)和贝叶斯神经网络(BNN)组成。两阶段网络方法的基本原理是通过为BNN提供注意力掩码来解决血管壁和背景的类别不平衡问题。网络训练的一个独特之处是使用由高分辨率MRI数据和组织病理学定义的地面真值。更具体地说,使用具有相应高分辨率3.0 T MR图像集和组织病理学图像集的标准分辨率1.5 T体内MR图像集来定义地面真值分割。其中,7名患者的数据用于训练,其余两名患者的数据用于测试所提出的方法。接下来,为了评估该方法的通用性,我们使用从不同扫描仪获得的另外23名患者的标准分辨率3.0 T体内数据集对该方法进行了测试。
我们的结果表明,所提出的方法能够准确分割颈动脉粥样硬化斑块,不仅优于无法获得离体或组织病理学数据的训练有素的读者的手动分割,而且优于三种基于深度学习的先进分割方法。此外,所提出的方法优于在无法获得高分辨率离体MRI和组织病理学的情况下生成地面真值的策略。在来自不同扫描仪的另外23名患者的数据集中也观察到了该方法的准确性能。
总之,所提出的方法提供了一种在多加权MRI中对颈动脉粥样硬化斑块进行准确分割的机制。此外,我们的研究表明了使用高分辨率成像和组织学来定义基于深度学习的分割方法的训练地面真值的优势。
