Chemistry of Life Processes Institute and Biomedical Engineering, Northwestern University Feinberg School of Medicine, Chicago, IL, United States of America.
Center for Genetic Medicine, Northwestern University Feinberg School of Medicine, Chicago, IL, United States of America.
PLoS One. 2024 Sep 19;19(9):e0310551. doi: 10.1371/journal.pone.0310551. eCollection 2024.
The pathology in Duchenne muscular dystrophy (DMD) is characterized by degenerating muscle fibers, inflammation, fibro-fatty infiltrate, and edema, and these pathological processes replace normal healthy muscle tissue. The mdx mouse model is one of the most commonly used preclinical models to study DMD. Mounting evidence has emerged illustrating that muscle disease progression varies considerably in mdx mice, with inter-animal differences as well as intra-muscular differences in pathology in individual mdx mice. This variation is important to consider when conducting assessments of drug efficacy and in longitudinal studies. We developed a magnetic resonance imaging (MRI) segmentation and analysis pipeline to rapidly and non-invasively measure the severity of muscle disease in mdx mice.
Wildtype and mdx mice were imaged with MRI and T2 maps were obtained axially across the hindlimbs. A neural network was trained to rapidly and semi-automatically segment the muscle tissue, and the distribution of resulting T2 values was analyzed. Interdecile range and Pearson Skew were identified as biomarkers to quickly and accurately estimate muscle disease severity in mice.
The semiautomated segmentation tool reduced image processing time approximately tenfold. Measures of Pearson skew and interdecile range based on that segmentation were repeatable and reflected muscle disease severity in healthy wildtype and diseased mdx mice based on both qualitative observation of images and correlation with Evans blue dye uptake.
Use of this rapid, non-invasive, semi-automated MR image segmentation and analysis pipeline has the potential to transform preclinical studies, allowing for pre-screening of dystrophic mice prior to study enrollment to ensure more uniform muscle disease pathology across treatment groups, improving study outcomes.
杜氏肌营养不良症(DMD)的病理学特征为肌肉纤维退化、炎症、纤维脂肪浸润和水肿,这些病理过程取代了正常健康的肌肉组织。mdx 小鼠模型是研究 DMD 的最常用临床前模型之一。越来越多的证据表明,mdx 小鼠的肌肉疾病进展差异很大,同一种属动物之间以及同一动物不同肌肉之间的病理差异都很大。在进行药物疗效评估和纵向研究时,这种变异性很重要。我们开发了一种磁共振成像(MRI)分割和分析管道,以快速、非侵入性地测量 mdx 小鼠肌肉疾病的严重程度。
使用 MRI 对野生型和 mdx 小鼠进行成像,并在轴位上获得后腿的 T2 图谱。训练神经网络以快速半自动分割肌肉组织,并分析所得 T2 值的分布。采用 interdecile range 和 Pearson Skew 作为生物标志物,快速准确地估计小鼠的肌肉疾病严重程度。
半自动分割工具将图像处理时间缩短了约十倍。基于该分割的 Pearson Skew 和 interdecile range 测量值具有可重复性,能够根据图像的定性观察和与 Evans 蓝染料摄取的相关性,反映健康野生型和患病 mdx 小鼠的肌肉疾病严重程度。
这种快速、非侵入性、半自动的 MR 图像分割和分析管道具有改变临床前研究的潜力,允许在研究入组前对进行筛选,以确保治疗组之间具有更均匀的肌肉疾病病理学,从而改善研究结果。
