Division of Image Processing, Department of Radiology, Leiden University Medical Center, 2300, RC, Leiden, The Netherlands.
Division of Image Processing, Department of Radiology, Leiden University Medical Center, 2300, RC, Leiden, The Netherlands; Intelligent System Group, Faculty of EEMCS, Delft University of Technology, 2600, GA, Delft, The Netherlands.
Neuroimage. 2018 Sep;178:445-460. doi: 10.1016/j.neuroimage.2018.05.051. Epub 2018 May 23.
In recent years, machine learning approaches have been successfully applied to the field of neuroimaging for classification and regression tasks. However, many approaches do not give an intuitive relation between the raw features and the diagnosis. Therefore, they are difficult for clinicians to interpret. Moreover, most approaches treat the features extracted from the brain (for example, voxelwise gray matter concentration maps from brain MRI) as independent variables and ignore their spatial and anatomical relations. In this paper, we present a new Support Vector Machine (SVM)-based learning method for the classification of Alzheimer's disease (AD), which integrates spatial-anatomical information. In this way, spatial-neighbor features in the same anatomical region are encouraged to have similar weights in the SVM model. Secondly, we introduce a group lasso penalty to induce structure sparsity, which may help clinicians to assess the key regions involved in the disease. For solving this learning problem, we use an accelerated proximal gradient descent approach. We tested our method on the subset of ADNI data selected by Cuingnet et al. (2011) for Alzheimer's disease classification, as well as on an independent larger dataset from ADNI. Good classification performance is obtained for distinguishing cognitive normals (CN) vs. AD, as well as on distinguishing between various sub-types (e.g. CN vs. Mild Cognitive Impairment). The model trained on Cuignet's dataset for AD vs. CN classification was directly used without re-training to the independent larger dataset. Good performance was achieved, demonstrating the generalizability of the proposed methods. For all experiments, the classification results are comparable or better than the state-of-the-art, while the weight map more clearly indicates the key regions related to Alzheimer's disease.
近年来,机器学习方法已成功应用于神经影像学领域的分类和回归任务。然而,许多方法并不能提供原始特征与诊断之间的直观关系,因此难以被临床医生解释。此外,大多数方法将从大脑中提取的特征(例如,大脑 MRI 的体素灰度浓度图)视为独立变量,并忽略了它们的空间和解剖关系。在本文中,我们提出了一种新的基于支持向量机(SVM)的学习方法,用于阿尔茨海默病(AD)的分类,该方法集成了空间解剖信息。通过这种方式,同一解剖区域中的空间邻居特征在 SVM 模型中被赋予相似的权重。其次,我们引入了群组 lasso 惩罚来诱导结构稀疏性,这可能有助于临床医生评估疾病涉及的关键区域。为了解决这个学习问题,我们使用了加速近端梯度下降方法。我们在 Cuingnet 等人(2011)为 AD 分类选择的 ADNI 数据子集上以及在来自 ADNI 的更大独立数据集上测试了我们的方法。在区分认知正常者(CN)与 AD 以及区分各种亚型(例如 CN 与轻度认知障碍)方面,我们的方法获得了良好的分类性能。在 Cuignet 数据集上训练的用于 AD 与 CN 分类的模型无需重新训练即可直接用于更大的独立数据集。良好的性能证明了所提出方法的泛化能力。在所有实验中,分类结果与最先进的方法相当或更好,而权重图更清楚地表明了与阿尔茨海默病相关的关键区域。
