Department of Molecular Genetics, Erasmus University Medical Center, Rotterdam, the Netherlands.
Phares/ESP Consultancy, Hank, the Netherlands.
Comput Biol Med. 2024 Sep;179:108853. doi: 10.1016/j.compbiomed.2024.108853. Epub 2024 Jul 15.
Methods to monitor cardiac functioning non-invasively can accelerate preclinical and clinical research into novel treatment options for heart failure. However, manual image analysis of cardiac substructures is resource-intensive and error-prone. While automated methods exist for clinical CT images, translating these to preclinical μCT data is challenging. We employed deep learning to automate the extraction of quantitative data from both CT and μCT images.
We collected a public dataset of cardiac CT images of human patients, as well as acquired μCT images of wild-type and accelerated aging mice. The left ventricle, myocardium, and right ventricle were manually segmented in the μCT training set. After template-based heart detection, two separate segmentation neural networks were trained using the nnU-Net framework.
The mean Dice score of the CT segmentation results (0.925 ± 0.019, n = 40) was superior to those achieved by state-of-the-art algorithms. Automated and manual segmentations of the μCT training set were nearly identical. The estimated median Dice score (0.940) of the test set results was comparable to existing methods. The automated volume metrics were similar to manual expert observations. In aging mice, ejection fractions had significantly decreased, and myocardial volume increased by age 24 weeks.
With further optimization, automated data extraction expands the application of (μ)CT imaging, while reducing subjectivity and workload. The proposed method efficiently measures the left and right ventricular ejection fraction and myocardial mass. With uniform translation between image types, cardiac functioning in diastolic and systolic phases can be monitored in both animals and humans.
非侵入性监测心脏功能的方法可以加速心力衰竭新治疗方案的临床前和临床研究。然而,手动分析心脏亚结构的图像既耗费资源又容易出错。虽然存在用于临床 CT 图像的自动化方法,但将这些方法转化为临床前 μCT 数据具有挑战性。我们利用深度学习技术,实现了从 CT 和 μCT 图像中自动提取定量数据。
我们收集了一组公共的心脏 CT 图像数据集,以及野生型和加速衰老小鼠的 μCT 图像。手动分割了 μCT 训练集中的左心室、心肌和右心室。在基于模板的心脏检测之后,使用 nnU-Net 框架训练了两个独立的分割神经网络。
CT 分割结果的平均 Dice 评分(0.925 ± 0.019,n = 40)优于最先进算法的得分。μCT 训练集的自动和手动分割结果几乎完全相同。测试集结果的估计中位数 Dice 评分(0.940)与现有方法相当。自动体积测量值与手动专家观察值相似。在衰老小鼠中,射血分数随年龄显著降低,心肌体积在 24 周时增加。
进一步优化后,自动化数据提取可扩大(μ)CT 成像的应用范围,同时减少主观性和工作量。该方法可以有效地测量左、右心室射血分数和心肌质量。通过在图像类型之间进行统一转换,可以在动物和人类中监测舒张期和收缩期的心脏功能。
