差异纤维束成像:神经退行性疾病中神经元功能的生物标志物
Differential Tractography: A Biomarker for Neuronal Function in Neurodegenerative Disease.
作者信息
Lewis Connor J, Vardar Zeynep, Luisa Kühn Anna, Johnston Jean M, D'Souza Precilla, Gahl William A, Salman Shazeeb Mohammed, Tifft Cynthia J, Acosta Maria T
机构信息
Office of the Clinical Director and Medical Genetics Branch, National Human Genome Research Institute, 10 Center Drive, Bethesda MD USA.
Department of Radiology, University of Massachusetts Chan Medical School, 55 N Lake Ave, Worcester MA USA.
出版信息
medRxiv. 2024 Aug 26:2024.08.25.24312255. doi: 10.1101/2024.08.25.24312255.
GM1 gangliosidosis is an ultra-rare inherited neurodegenerative lysosomal storage disorder caused by biallelic mutations in the gene. GM1 is uniformly fatal and has no approved therapies, although clinical trials investigating gene therapy as a potential treatment for this condition are underway. Novel outcome measures or biomarkers demonstrating the longitudinal effects of GM1 and potential recovery due to therapeutic intervention are urgently needed to establish efficacy of potential therapeutics. One promising tool is differential tractography, a novel imaging modality utilizing serial diffusion weighted imaging (DWI) to quantify longitudinal changes in white matter microstructure. In this study, we present the novel use of differential tractography in quantifying the progression of GM1 alongside age-matched neurotypical controls. We analyzed 113 DWI scans from 16 GM1 patients and 32 age-matched neurotypical controls to investigate longitudinal changes in white matter pathology. GM1 patients showed white matter degradation evident by both the number and size of fiber tract loss. In contrast, neurotypical controls showed longitudinal white matter improvements as evident by both the number and size of fiber tract growth. We also corroborated these findings by documenting significant correlations between cognitive global impression (CGI) scores of clinical presentations and our differential tractography derived metrics in our GM1 cohort. Specifically, GM1 patients who lost more neuronal fiber tracts also had a worse clinical presentation. This result demonstrates the importance of differential tractography as an important biomarker for disease progression in GM1 patients with potential extension to other neurodegenerative diseases and therapeutic intervention.
GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病,由该基因的双等位基因突变引起。GM1神经节苷脂贮积症是一种极其罕见的遗传性神经退行性溶酶体贮积病均匀致命,且尚无获批疗法,不过针对该病症的基因治疗临床试验正在进行。迫切需要新的疗效指标或生物标志物来证明GM1的纵向影响以及治疗干预可能带来的恢复,以确定潜在疗法的疗效。一种有前景的工具是差异纤维束成像,这是一种利用系列扩散加权成像(DWI)来量化白质微观结构纵向变化的新型成像方式。在本研究中,我们展示了差异纤维束成像在量化GM1进展以及与年龄匹配的神经典型对照方面的新用途。我们分析了来自16名GM1患者和32名年龄匹配的神经典型对照的113次DWI扫描,以研究白质病理的纵向变化。GM1患者表现出白质退化,这在纤维束损失数量和大小上都很明显。相比之下,神经典型对照显示白质纵向改善,这在纤维束生长数量和大小上都很明显。我们还通过记录临床症状的认知总体印象(CGI)评分与我们在GM1队列中通过差异纤维束成像得出的指标之间的显著相关性,证实了这些发现。具体而言,失去更多神经纤维束的GM1患者临床症状也更严重。这一结果表明差异纤维束成像作为GM1患者疾病进展的重要生物标志物具有重要意义,可能适用于其他神经退行性疾病和治疗干预。
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