Harris G, Andreasen N C, Cizadlo T, Bailey J M, Bockholt H J, Magnotta V A, Arndt S
Mental Health Clinical Research Center, University of Iowa College of Medicine and Hospitals and Clinics, Iowa City 52242, USA.
J Comput Assist Tomogr. 1999 Jan-Feb;23(1):144-54. doi: 10.1097/00004728-199901000-00030.
To improve the reliability, accuracy, and computational efficiency of tissue classification with multispectral sequences [T1, T2, and proton density (PD)], we developed an automated method for identifying training classes to be used in a discriminant function analysis. We compared it with a supervised operator-dependent method, evaluating its reliability and validity. We also developed a fuzzy (continuous) classification to correct for partial voluming.
Images were obtained on a 1.5 T GE Signa MR scanner using three pulse sequences that were co-registered. Training classes for the discriminant analysis were obtained in two ways. The operator-dependent method involved defining circular ROIs containing 5-15 voxels that represented "pure" samples of gray matter (GM), white matter (WM), and cerebrospinal fluid (CSF), using a total of 150-300 voxels for each tissue type. The automated method involved selecting a large number of samples of brain tissue with sufficiently low variance and randomly placed throughout the brain ("plugs"), partitioning these samples into GM, WM, and CSF, and minimizing the amount of variance within each partition of samples to optimize its "purity." The purity of the plug was estimated by calculating the variance of 8 voxels in all modalities (T1, T2, and PD). We also compared "sharp" (discrete) measurements (which classified tissue only as GM, WM, or CSF) and "fuzzy" (continuous) measurements (which corrected for partial voluming by weighting the classification based on the mixture of tissue types in each voxel).
Reliability was compared for the operator-dependent and automated methods as well as for the fuzzy versus sharp classification. The automated sharp classifications consistently had the highest interrater and intrarater reliability. Validity was assessed in three ways: reproducibility of measurements when the same individuals were scanned on multiple occasions, sensitivity of the method to detecting changes associated with aging, and agreement between the automated segmentation values and those produced through expert manual segmentation. The sharp automated classification emerged as slightly superior to the other three methods according to each of these validators. Its reproducibility index (intraclass r) was 0.97, 0.98, and 0.98 for total CSF, total GM, and total WM, respectively. Its correlations with age were 0.54, -0.61, and -0.53, respectively. Its percent agreement with the expert manually segmented tissue for the three tissue types was 93, 90, and 94%, respectively.
Automated identification of training classes for discriminant analysis was clearly superior to a method that required operator intervention. A sharp (discrete) classification into three tissue types was also slightly superior to one that used "fuzzy" classification to produce continuous measurements to correct for partial voluming. This multispectral automated discriminant analysis method produces a computationally efficient, reliable, and valid method for classifying brain tissue into GM, WM, and CSF. It corrects some of the problems with reliability and computational inefficiency previously observed for operator-dependent approaches to segmentation.
为提高利用多光谱序列(T1、T2和质子密度(PD))进行组织分类的可靠性、准确性和计算效率,我们开发了一种自动方法来识别用于判别函数分析的训练类别。我们将其与一种依赖操作者的监督方法进行比较,评估其可靠性和有效性。我们还开发了一种模糊(连续)分类方法来校正部分容积效应。
使用1.5T GE Signa MR扫描仪,通过三个配准的脉冲序列获取图像。判别分析的训练类别通过两种方式获得。依赖操作者的方法包括定义包含5 - 15个体素的圆形感兴趣区域(ROI),这些区域代表灰质(GM)、白质(WM)和脑脊液(CSF)的“纯”样本,每种组织类型总共使用150 - 300个体素。自动方法包括选择大量方差足够低且随机分布在整个大脑中的脑组织样本(“栓子”),将这些样本分为GM、WM和CSF,并最小化每个样本分区内的方差量以优化其“纯度”。通过计算所有模态(T1、T2和PD)中8个体素的方差来估计栓子的纯度。我们还比较了“清晰”(离散)测量(仅将组织分类为GM、WM或CSF)和“模糊”(连续)测量(通过根据每个体素中组织类型的混合对分类进行加权来校正部分容积效应)。
比较了依赖操作者的方法与自动方法以及模糊分类与清晰分类的可靠性。自动清晰分类始终具有最高的评分者间和评分者内可靠性。通过三种方式评估有效性:对同一受试者多次扫描时测量的可重复性、该方法检测与衰老相关变化的敏感性以及自动分割值与专家手动分割产生的值之间的一致性。根据这些验证指标,清晰自动分类略优于其他三种方法。其总CSF、总GM和总WM的可重复性指数(组内相关系数r)分别为0.97、0.98和0.98。其与年龄的相关性分别为0.54、 - 0.61和 - 0.53。其与专家手动分割的三种组织类型的组织一致性百分比分别为93%、90%和94%。
判别分析训练类别的自动识别明显优于需要操作者干预的方法。分为三种组织类型的清晰(离散)分类也略优于使用“模糊”分类产生连续测量以校正部分容积效应的方法。这种多光谱自动判别分析方法为将脑组织分类为GM、WM和CSF提供了一种计算高效、可靠且有效的方法。它校正了先前在依赖操作者的分割方法中观察到的一些可靠性和计算效率问题。
