Egger Christine, Opfer Roland, Wang Chenyu, Kepp Timo, Sormani Maria Pia, Spies Lothar, Barnett Michael, Schippling Sven
Neuroimmunology and Multiple Sclerosis Research, Department of Neurology, University Hospital Zurich and University of Zurich, Frauenklinikstrasse 26, CH-8091 Zurich, Switzerland.
Neuroimmunology and Multiple Sclerosis Research, Department of Neurology, University Hospital Zurich and University of Zurich, Frauenklinikstrasse 26, CH-8091 Zurich, Switzerland; jung diagnostics GmbH, Hamburg, Germany.
Neuroimage Clin. 2016 Nov 20;13:264-270. doi: 10.1016/j.nicl.2016.11.020. eCollection 2017.
Magnetic resonance imaging (MRI) has become key in the diagnosis and disease monitoring of patients with multiple sclerosis (MS). Both, T2 lesion load and Gadolinium (Gd) enhancing T1 lesions represent important endpoints in MS clinical trials by serving as a surrogate of clinical disease activity. T2- and fluid-attenuated inversion recovery (FLAIR) lesion quantification - largely due to methodological constraints - is still being performed manually or in a semi-automated fashion, although strong efforts have been made to allow automated quantitative lesion segmentation. In 2012, Schmidt and co-workers published an algorithm to be applied on FLAIR sequences. The aim of this study was to apply the Schmidt algorithm on an independent data set and compare automated segmentation to inter-rater variability of three independent, experienced raters.
MRI data of 50 patients with RRMS were randomly selected from a larger pool of MS patients attending the MS Clinic at the Brain and Mind Centre, University of Sydney, Australia. MRIs were acquired on a 3.0T GE scanner (Discovery MR750, GE Medical Systems, Milwaukee, WI) using an 8 channel head coil. We determined T2-lesion load (total lesion volume and total lesion number) using three versions of an automated segmentation algorithm (Lesion growth algorithm (LGA) based on SPM8 or SPM12 and lesion prediction algorithm (LPA) based on SPM12) as first described by Schmidt et al. (2012). Additionally, manual segmentation was performed by three independent raters. We calculated inter-rater correlation coefficients (ICC) and dice coefficients (DC) for all possible pairwise comparisons.
We found a strong correlation between manual and automated lesion segmentation based on LGA SPM8, regarding lesion volume (ICC = 0.958 and DC = 0.60) that was not statistically different from the inter-rater correlation (ICC = 0.97 and DC = 0.66). Correlation between the two other algorithms (LGA SPM12 and LPA SPM12) and manual raters was weaker but still adequate (ICC = 0.927 and DC = 0.53 for LGA SPM12 and ICC = 0.949 and DC = 0.57 for LPA SPM12). Variability of both manual and automated segmentation was significantly higher regarding lesion numbers.
Automated lesion volume quantification can be applied reliably on FLAIR data sets using the SPM based algorithm of Schmidt et al. and shows good agreement with manual segmentation.
磁共振成像(MRI)已成为多发性硬化症(MS)患者诊断和疾病监测的关键手段。T2病变负荷和钆(Gd)增强T1病变在MS临床试验中均作为临床疾病活动的替代指标,代表着重要的终点。尽管人们已做出巨大努力来实现病变的自动定量分割,但由于方法学的限制,T2加权成像(T2WI)和液体衰减反转恢复序列(FLAIR)的病变量化仍主要通过手动或半自动方式进行。2012年,施密特及其同事发表了一种应用于FLAIR序列的算法。本研究的目的是将施密特算法应用于一个独立数据集,并将自动分割结果与三位独立、经验丰富的评估者之间的评分者间变异性进行比较。
从澳大利亚悉尼大学脑与心智中心MS诊所的大量MS患者中随机选取50例复发缓解型多发性硬化症(RRMS)患者的MRI数据。使用8通道头部线圈在3.0T通用电气扫描仪(Discovery MR750,通用电气医疗系统公司,威斯康星州密尔沃基)上采集MRI图像。我们使用施密特等人(2012年)首次描述的三种自动分割算法版本(基于SPM8或SPM12的病变生长算法(LGA)以及基于SPM12的病变预测算法(LPA))来确定T2病变负荷(总病变体积和总病变数量)。此外,由三位独立评估者进行手动分割。我们计算了所有可能的两两比较的评分者间相关系数(ICC)和骰子系数(DC)。
我们发现基于LGA SPM8的手动和自动病变分割在病变体积方面具有很强的相关性(ICC = 0.958,DC = 0.60),与评分者间相关性(ICC = 0.97,DC = 0.66)相比无统计学差异。其他两种算法(LGA SPM12和LPA SPM12)与手动评估者之间的相关性较弱,但仍足够(LGA SPM12的ICC = 0.927,DC = 0.53;LPA SPM12的ICC = 0.949,DC = 0.57)。在病变数量方面,手动和自动分割的变异性均显著更高。
使用施密特等人基于SPM的算法可将自动病变体积量化可靠地应用于FLAIR数据集,且与手动分割显示出良好的一致性。
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