Acquired demyelination but not genetic developmental defects in myelination leads to brain tissue stiffness changes

Q3 Engineering Brain multiphysics Pub Date : 2020-11-01 DOI:10.1016/j.brain.2020.100019
Dominic Eberle , Georgia Fodelianaki , Thomas Kurth , Anna Jagielska , Stephanie Möllmert , Elke Ulbricht , Katrin Wagner , Anna V. Taubenberger , Nicole Träber , Joan-Carles Escolano , Krystyn J. Van Vliet , Jochen Guck
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引用次数: 4

Abstract

Changes in axonal myelination are an important hallmark of aging and a number of neurological diseases. Demyelinated axons are impaired in their function and degenerate over time. Oligodendrocytes, the cells responsible for myelination of axons, are sensitive to mechanical properties of their environment. Growing evidence indicates that mechanical properties of demyelinating lesions are different from the healthy state and thus have the potential to affect myelinating potential of oligodendrocytes. We performed a high-resolution spatial mapping of the mechanical heterogeneity of demyelinating lesions using atomic force microscope-enabled indentation. Our results indicate that the stiffness of specific regions of mouse brain tissue is influenced by age and degree of myelination. Here we specifically demonstrate that acquired acute but not genetic demyelination leads to decreased tissue stiffness, which could influence the remyelination potential of oligodendrocytes. We also demonstrate that specific brain regions have unique ranges of stiffness in white and grey matter. Our ex vivo findings may help the design of future in vitro models to mimic the mechanical environment of the brain in healthy and diseased states. The mechanical properties of demyelinating lesions reported here may facilitate novel approaches in treating demyelinating diseases such as multiple sclerosis.

Statement of Significance

Mechanical characteristics of a cell's environment can have a profound influence on its biological properties. Neuronal and glial cells are sensitive to mechanical input during development, in disease and regeneration. Sustained tensile strain can promote differentiation of oligodendrocyte progenitor cells into mature oligodendrocytes, which are responsible for the myelination of axons. Changing myelination is an important hallmark in human aging and disease, such as multiple sclerosis. Our hypothesis is that these diseases might be characterized by altered tissue stiffness and that this has an influence on remyelination potential. Here we investigate tissue stiffness profiles of healthy, aged and disease model mice. Manipulating the tissue stiffness might be another promising approach for new treatments.

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后天脱髓鞘而非遗传发育缺陷导致脑组织僵硬改变
轴突髓鞘形成的改变是衰老和许多神经系统疾病的重要标志。脱髓鞘轴突的功能受损,并随时间退化。少突胶质细胞是负责轴突髓鞘形成的细胞,对环境的机械特性很敏感。越来越多的证据表明,脱髓鞘病变的力学特性与健康状态不同,从而有可能影响少突胶质细胞的成髓潜能。我们使用原子力显微镜进行了脱髓鞘病变机械异质性的高分辨率空间映射。我们的结果表明,小鼠脑组织特定区域的硬度受年龄和髓鞘形成程度的影响。在这里,我们特别证明,获得性急性脱髓鞘而不是遗传性脱髓鞘导致组织硬度降低,这可能影响少突胶质细胞的再脱髓鞘潜能。我们还证明了特定的大脑区域在白质和灰质中有独特的僵硬范围。我们的离体研究结果可能有助于设计未来的体外模型来模拟健康和患病状态下大脑的机械环境。本文报道的脱髓鞘病变的力学特性可能促进治疗脱髓鞘疾病(如多发性硬化症)的新方法。细胞所处环境的力学特性对其生物学特性有深远的影响。神经元和神经胶质细胞在发育、疾病和再生过程中对机械输入很敏感。持续的拉伸应变可以促进少突胶质细胞祖细胞向成熟的少突胶质细胞分化,而成熟的少突胶质细胞负责轴突的髓鞘形成。髓鞘形成的改变是人类衰老和疾病(如多发性硬化症)的重要标志。我们的假设是,这些疾病的特征可能是组织硬度的改变,这对髓鞘再生的潜力有影响。在这里,我们研究了健康、衰老和疾病模型小鼠的组织刚度概况。控制组织硬度可能是另一种有希望的新治疗方法。
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来源期刊
Brain multiphysics
Brain multiphysics Physics and Astronomy (General), Modelling and Simulation, Neuroscience (General), Biomedical Engineering
CiteScore
4.80
自引率
0.00%
发文量
0
审稿时长
68 days
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