Department of Bioengineering, George Mason University, Fairfax, Virginia, USA
Department of Bioengineering, George Mason University, Fairfax, Virginia, USA.
J Neurointerv Surg. 2022 Oct;14(10):1002-1007. doi: 10.1136/neurintsurg-2021-017976. Epub 2021 Oct 22.
Bleb presence in intracranial aneurysms (IAs) is a known indication of instability and vulnerability.
To develop and evaluate predictive models of bleb development in IAs based on hemodynamics, geometry, anatomical location, and patient population.
Cross-sectional data (one time point) of 2395 IAs were used for training bleb formation models using machine learning (random forest, support vector machine, logistic regression, k-nearest neighbor, and bagging). Aneurysm hemodynamics and geometry were characterized using image-based computational fluid dynamics. A separate dataset with 266 aneurysms was used for model evaluation. Model performance was quantified by the area under the receiving operating characteristic curve (AUC), true positive rate (TPR), false positive rate (FPR), precision, and balanced accuracy.
The final model retained 18 variables, including hemodynamic, geometrical, location, multiplicity, and morphology parameters, and patient population. Generally, strong and concentrated inflow jets, high speed, complex and unstable flow patterns, and concentrated, oscillatory, and heterogeneous wall shear stress patterns together with larger, more elongated, and more distorted shapes were associated with bleb formation. The best performance on the validation set was achieved by the random forest model (AUC=0.82, TPR=91%, FPR=36%, misclassification error=27%).
Based on the premise that aneurysm characteristics prior to bleb formation resemble those derived from vascular reconstructions with their blebs virtually removed, machine learning models can identify aneurysms prone to bleb development with good accuracy. Pending further validation with longitudinal data, these models may prove valuable for assessing the propensity of IAs to progress to vulnerable states and potentially rupturing.
颅内动脉瘤(IA)中的瘤颈存在是不稳定和脆弱的已知标志。
基于血流动力学、几何形状、解剖位置和患者人群,开发和评估 IA 中瘤颈形成的预测模型。
使用机器学习(随机森林、支持向量机、逻辑回归、k-最近邻和袋装法)对 2395 个 IA 的横截面数据(一个时间点)进行训练以形成瘤颈形成模型。使用基于图像的计算流体动力学来描述动脉瘤的血流动力学和几何形状。使用包含 266 个动脉瘤的单独数据集进行模型评估。通过接收者操作特征曲线下的面积(AUC)、真阳性率(TPR)、假阳性率(FPR)、精度和平衡准确性来量化模型性能。
最终模型保留了 18 个变量,包括血流动力学、几何形状、位置、多发性和形态参数以及患者人群。通常,强而集中的流入射流、高速、复杂且不稳定的流动模式以及集中、振荡和不均匀的壁切应力模式,再加上更大、更长和更扭曲的形状与瘤颈形成相关。在验证集上表现最好的是随机森林模型(AUC=0.82,TPR=91%,FPR=36%,误分类错误=27%)。
基于在瘤颈形成之前动脉瘤的特征类似于虚拟去除瘤颈后的血管重建的特征的前提,机器学习模型可以准确识别易发生瘤颈形成的动脉瘤。在使用纵向数据进行进一步验证之前,这些模型可能对评估 IA 向易损状态和潜在破裂进展的倾向具有重要价值。
