Liu Zhong, Li Wei, Zhu Ziqi, Wen Huiying, Li Ming-de, Hou Chao, Shen Hui, Huang Bin, Luo Yudi, Wang Wei, Chen Xin
National-Regional Key Technology Engineering Laboratory for Medical Ultrasound, Guangdong Key Laboratory for Biomedical Measurements and Ultrasound Imaging, School of Biomedical Engineering, Shenzhen University Medical School, Shenzhen University, 1066 Xueyuan Road, Shenzhen, 518055, People's Republic of China.
Department of Medical Ultrasonics, Institute of Diagnostic and Interventional Ultrasound, The First Affiliated Hospital of Sun Yat-Sen University, 58 Zhongshan Road 2, Guangzhou, 510080, People's Republic of China.
Eur Radiol. 2023 Aug;33(8):5871-5881. doi: 10.1007/s00330-023-09436-z. Epub 2023 Feb 3.
To develop and investigate a deep learning model with data integration of ultrasound contrast-enhanced micro-flow (CEMF) cines, B-mode images, and patients' clinical parameters to improve the diagnosis of significant liver fibrosis (≥ F2) in patients with chronic hepatitis B (CHB).
Of 682 CHB patients who underwent ultrasound and histopathological examinations between October 2016 and May 2020, 218 subjects were included in this retrospective study. We devised a data integration-based deep learning (DIDL) model for assessing ≥ F2 in CHB patients. The model contained three convolutional neural network branches to automatically extract features from ultrasound CEMF cines, B-mode images, and clinical data. The extracted features were fused at the backend of the model for decision-making. The diagnostic performance was evaluated across fivefold cross-validation and compared against the other methods in terms of the area under the receiver operating characteristic curve (AUC), with histopathological results as the reference standard.
The mean AUC achieved by the DIDL model was 0.901 [95% CI, 0.857-0.939], which was significantly higher than those of the comparative methods, including the models trained by using only CEMF cines (0.850 [0.794-0.893]), B-mode images (0.813 [0.754-0.862]), or clinical data (0.757 [0.694-0.812]), as well as the conventional TIC method (0.752 [0.689-0.808]), APRI (0.792 [0.734-0.845]), FIB-4 (0.776 [0.714-0.829]), and visual assessments of two radiologists (0.812 [0.754-0.862], and 0.800 [0.739-0.849]), all ps < 0.01, DeLong test.
The DIDL model with data integration of ultrasound CEMF cines, B-mode images, and clinical parameters showed promising performance in diagnosing significant liver fibrosis for CHB patients.
• The combined use of ultrasound contrast-enhanced micro-flow cines, B-mode images, and clinical data in a deep learning model has potential to improve the diagnosis of significant liver fibrosis. • The deep learning model with the fusion of features extracted from multimodality data outperformed the conventional methods including mono-modality data-based models, the time-intensity curve-based recognizer, fibrosis biomarkers, and visual assessments by experienced radiologists. • The interpretation of the feature attention maps in the deep learning model may help radiologists get better understanding of liver fibrosis-related features and hence potentially enhancing their diagnostic capacities.
开发并研究一种深度学习模型,该模型整合超声造影增强微血流(CEMF)动态图像、B 模式图像和患者临床参数,以改善慢性乙型肝炎(CHB)患者显著肝纤维化(≥F2)的诊断。
在 2016 年 10 月至 2020 年 5 月期间接受超声和组织病理学检查的 682 例 CHB 患者中,218 名受试者被纳入这项回顾性研究。我们设计了一种基于数据整合的深度学习(DIDL)模型,用于评估 CHB 患者的≥F2。该模型包含三个卷积神经网络分支,以自动从超声 CEMF 动态图像、B 模式图像和临床数据中提取特征。提取的特征在模型后端融合以进行决策。通过五重交叉验证评估诊断性能,并以组织病理学结果作为参考标准,与其他方法在受试者操作特征曲线(AUC)下面积方面进行比较。
DIDL 模型实现的平均 AUC 为 0.901 [95%CI,0.857 - 0.939],显著高于比较方法,包括仅使用 CEMF 动态图像训练的模型(0.850 [0.794 - 0.893])、B 模式图像训练的模型(0.813 [0.754 - 0.862])或临床数据训练的模型(0.757 [0.694 - 0.812]),以及传统 TIC 方法(0.752 [0.689 - 0.808])、APRI(0.792 [0.734 - 0.845])、FIB - 4(0.776 [0.714 - 0.829])和两位放射科医生的视觉评估(0.812 [0.754 - 0.862]和 0.800 [0.739 - 0.849]),所有 p 值均<0.01,DeLong 检验。
整合超声 CEMF 动态图像、B 模式图像和临床参数的数据整合深度学习模型在诊断 CHB 患者显著肝纤维化方面表现出良好的性能。
• 将超声造影增强微血流动态图像、B 模式图像和临床数据联合用于深度学习模型有潜力改善显著肝纤维化的诊断。
• 融合从多模态数据中提取的特征的深度学习模型优于传统方法,包括基于单模态数据的模型、基于时间 - 强度曲线的识别器、纤维化生物标志物以及经验丰富的放射科医生的视觉评估。
• 深度学习模型中特征注意力图的解读可能有助于放射科医生更好地理解肝纤维化相关特征,从而潜在地提高他们的诊断能力。
