Vergun Svyat, Suhonen Josh I, Nair Veena A, Kuo J S, Baskaya M K, Garcia-Ramos Camille, Meyerand Elizabeth E, Prabhakaran Vivek
Department of Medical Physics, University of Wisconsin-Madison, School of Medicine and Public Health, 1111 Highland Avenue, Madison, WI53792-3252, USA.
Department of Radiology, University of Wisconsin-Madison, School of Medicine and Public Health, 600 Highland Avenue, Wisconsin Institutes for Medical Research (WIMR), Madison, WI 53705, USA.
Interdiscip Neurosurg. 2018 Sep;13:109-118. doi: 10.1016/j.inat.2018.04.013. Epub 2018 Apr 25.
Advanced neuroimaging measures along with clinical variables acquired during standard imaging protocols provide a rich source of information for brain tumor patient treatment and management. Machine learning analysis has had much recent success in neuroimaging applications for normal and patient populations and has potential, specifically for brain tumor patient outcome prediction. The purpose of this work was to construct, using the current patient population distribution, a high accuracy predictor for brain tumor patient outcomes of mortality and morbidity (i.e., transient and persistent language and motor deficits). The clinical value offered is a statistical tool to help guide treatment and planning as well as an investigation of the influential factors of the disease process.
Resting state fMRI, diffusion tensor imaging, and task fMRI data in combination with clinical and demographic variables were used to represent the tumor patient population (n = 62; mean age = 51.2 yrs.) in a machine learning analysis in order to predict outcomes.
A support vector machine classifier with a -test filter and recursive feature elimination predicted patient mortality (18-month interval) with 80.7% accuracy, language deficits (transient) with 74.2%, motor deficits with 71.0%, language outcomes (persistent) with 80.7% and motor outcomes with 83.9%. The most influential features of the predictors were resting fMRI connectivity, and fractional anisotropy and mean diffusivity measures in the internal capsule, brain stem and superior and inferior longitudinal fasciculi.
This study showed that advanced neuroimaging data with machine learning methods can potentially predict patient outcomes and reveal influential factors driving the predictions.
先进的神经影像学测量方法以及在标准成像方案中获取的临床变量,为脑肿瘤患者的治疗和管理提供了丰富的信息来源。机器学习分析最近在正常人群和患者群体的神经影像学应用中取得了很大成功,并且具有潜力,特别是在脑肿瘤患者预后预测方面。这项工作的目的是利用当前患者群体分布,构建一个用于预测脑肿瘤患者死亡率和发病率(即短暂性和持续性语言及运动功能障碍)的高精度预测模型。所提供的临床价值是一种统计工具,有助于指导治疗和规划,以及对疾病过程的影响因素进行研究。
在机器学习分析中,将静息态功能磁共振成像、扩散张量成像和任务态功能磁共振成像数据与临床和人口统计学变量相结合,以代表肿瘤患者群体(n = 62;平均年龄 = 51.2岁),从而预测预后。
一个带有t检验滤波器和递归特征消除的支持向量机分类器预测患者死亡率(18个月间隔)的准确率为80.7%,语言功能障碍(短暂性)的准确率为74.2%,运动功能障碍的准确率为71.0%,语言预后(持续性)的准确率为80.7%,运动预后的准确率为83.9%。预测模型中最具影响力的特征是静息态功能磁共振成像连接性,以及内囊、脑干和上下纵束中的各向异性分数和平均扩散率测量值。
这项研究表明,先进的神经影像学数据与机器学习方法相结合,有可能预测患者预后并揭示驱动预测的影响因素。