Mayo Clinic, Department of Neurology, College of Medicine, Rochester, MN 55905, USA.
Neuroimage. 2011 Jan 15;54(2):802-6. doi: 10.1016/j.neuroimage.2010.08.055. Epub 2010 Sep 15.
White matter (WM) lesions are the classic pathological hallmarks of multiple sclerosis (MS). However, MRI-based WM lesion load shows relatively poor correlation with functional outcome, resulting in the "clinico-radiological paradox" of MS. Unlike lesion based measures, volumetric MRI assessment of brain atrophy shows a strong correlation with functional outcome, and the presence of early atrophy predicts a worse disease course. While extensive literature exists describing MRI characteristics of atrophy in MS, the exact pathogenesis and the substrate of atrophy-gray vs. WM loss, axonal/neuronal damage vs. demyelination, or a combination of the above-remain unclear. Animal models of atrophy would allow for detailed investigations of the pathomechanism, and would contribute to an enhanced understanding of structural-functional connections in this complex disease. We now report that in the Theiler's Murine Encephalitis Virus (TMEV) model of MS in SJL/J mice, significant brain atrophy accompanies the development of the progressive MS-like disease. We conducted volumetric MRI studies in 8 cases and 4 age, gender- and strain-matched control mice. While in controls we did not detect any brain atrophy, significant atrophy developed as early as 3 months into the disease course, and reached its peak by 6 months, resulting in ventricular enlargement by 118% (p=0.00003). A strong correlation (r=-0.88) between atrophy and disability, as assessed by rotarod assay, was also demonstrated. We earlier reported another neurodegenerative feature in this model, the presence of deep gray matter T2 hypointensity in thalamic nuclei. Future studies utilizing this model will allow us to investigate key components of MRI detectable neurodegenerative feature development, their tissue correlations and associations with functional outcome measures. These studies are expected to pave the way to a better understanding of the substrate of disability in MS models.
脑白质(WM)病变是多发性硬化症(MS)的经典病理学标志。然而,基于 MRI 的 WM 病变负荷与功能结果相关性较差,导致 MS 的“临床放射学悖论”。与基于病变的测量方法不同,脑萎缩的容积 MRI 评估与功能结果具有很强的相关性,早期萎缩的存在预示着疾病过程更差。尽管有大量文献描述了 MS 中脑萎缩的 MRI 特征,但确切的发病机制和萎缩的基质——灰质与 WM 丢失、轴突/神经元损伤与脱髓鞘,或者上述的组合——仍然不清楚。脑萎缩的动物模型可以对病理机制进行详细的研究,并有助于增强对这种复杂疾病的结构-功能联系的理解。我们现在报告,在 SJL/J 小鼠的 Theiler's 鼠脑炎病毒(TMEV)MS 模型中,进行性 MS 样疾病的发展伴随着明显的脑萎缩。我们对 8 例和 4 例年龄、性别和品系匹配的对照小鼠进行了容积 MRI 研究。在对照组中,我们没有检测到任何脑萎缩,而在疾病过程的 3 个月时就出现了明显的萎缩,到 6 个月时达到高峰,导致脑室扩大 118%(p=0.00003)。我们还证明了萎缩与旋转棒试验评估的残疾之间存在很强的相关性(r=-0.88)。我们之前在该模型中报道了另一个神经退行性特征,即丘脑核深部灰质 T2 低信号的存在。利用该模型进行的未来研究将使我们能够研究 MRI 可检测的神经退行性特征发展的关键组成部分、它们的组织相关性以及与功能结果测量的关联。这些研究有望为更好地理解 MS 模型中残疾的基质铺平道路。