Department of Neurosurgery, Medical School, University of Minnesota, Minneapolis, Minnesota 55455, USA.
J Comp Neurol. 2010 Oct 15;518(20):4091-112. doi: 10.1002/cne.22365.
Nuclear magnetic resonance (NMR) spectroscopy is a rapidly emerging technology that can be used to assess tissue metabolic profile in the living animal. At the present time, no approach has been developed 1) to systematically identify profiles of key chemical alterations that can be used as biomarkers to diagnose diseases and to monitor disease progression; and 2) to assess mathematically the diagnostic power of potential biomarkers. To address this issue, we have evaluated mathematical approaches that employ receiver operating characteristic (ROC) curve analysis, linear discriminant analysis, and logistic regression analysis to systematically identify key biomarkers from NMR spectra that have excellent diagnostic power and can be used accurately for disease diagnosis and monitoring. To validate our mathematical approaches, we studied the striatal concentrations of 17 metabolites of 13 R6/2 transgenic mice with Huntington's disease, as well as those of 17 wild-type (WT) mice, which were obtained via in vivo proton NMR spectroscopy (9.4 Tesla). We developed diagnostic biomarker models and clinical change assessment models based on our three aforementioned mathematical approaches, and we tested all of them, first, with the 30 original mice and, then, with 31 unknown mice. Their prediction results were compared with genotyping-the gold standard. All models correctly diagnosed all of the 30 original mice (17 WT and 13 R6/2) and all of the 31 unknown mice (20 WT and 11 R6/2), with a positive likelihood ratio approximating infinity [1/0 (→ ∞)], and with a negative likelihood ratio equal to zero [0/1 = 0].
磁共振波谱(NMR)是一种新兴的技术,可用于评估活体动物的组织代谢谱。目前,尚未开发出 1)系统性地鉴定可作为诊断疾病和监测疾病进展的生物标志物的关键化学变化特征谱的方法;以及 2)评估潜在生物标志物的诊断能力的数学方法。为了解决这个问题,我们评估了采用接受者操作特征(ROC)曲线分析、线性判别分析和逻辑回归分析的数学方法,以系统性地从具有出色诊断能力且可用于准确诊断疾病和监测疾病的 NMR 光谱中鉴定关键生物标志物。为了验证我们的数学方法,我们研究了患有亨廷顿病的 13 R6/2 转基因小鼠的 17 种纹状体代谢物以及 17 种野生型(WT)小鼠的纹状体浓度,这些浓度是通过体内质子 NMR 光谱(9.4 Tesla)获得的。我们基于上述三种数学方法开发了诊断生物标志物模型和临床变化评估模型,并首先用 30 只原始小鼠和然后用 31 只未知小鼠对所有模型进行了测试。将它们的预测结果与基因分型(金标准)进行了比较。所有模型都正确诊断了 30 只原始小鼠(17 只 WT 和 13 只 R6/2)和 31 只未知小鼠(20 只 WT 和 11 只 R6/2),阳性似然比接近无穷大 [1/0(→ ∞)],而阴性似然比等于零 [0/1 = 0]。