Demyelination reduces brain parenchymal stiffness quantified in vivo by magnetic resonance elastography

Schregel, Katharina; Tysiak, Eva; Garteiser, Philippe; Gemeinhardt, Ines; Prozorovski, Timour; Aktaş, Orhan; Merz, Hartmut; Petersen, Dirk; Wuerfel, Jens; Sinkus, Ralph

doi:10.1073/pnas.1200151109

Cited by 205 publications

(212 citation statements)

References 35 publications

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“…As other factors may contribute to changes in local tissue stiffness as well, it is possible that relative differences between the elastic stiffness of the various retinal layers are species-dependent. Parts of the nerve fiber layer in the rabbit retina, for example, are strongly myelinated, which might make this part of the tissue much stiffer than NFLs in non-myelinated retinae (7, 54). Future work will reveal which and to what extent other cellular and extracellular components contribute to mechanical heterogeneities in CNS tissue, which have significant implications for the developing and diseased CNS (2, 5, 41).…”

Section: Discussionmentioning

confidence: 99%

The role of cell body density in ruminant retina mechanics assessed by atomic force and Brillouin microscopy

et al. 2017

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Cells in the central nervous system (CNS) respond to the stiffness of their environment. CNS tissue is mechanically highly heterogeneous, thus providing motile cells with region-specific mechanical signals. While CNS mechanics has been measured with a variety of techniques, reported values of tissue stiffness vary greatly, and the morphological structures underlying spatial changes in tissue stiffness remain poorly understood. We here exploited two complementary techniques, contact-based atomic force microscopy and contact-free Brillouin microscopy, to determine the mechanical properties of ruminant retinae, which are built up by different tissue layers. As in all vertebrate retinae, layers of high cell body densities (‘nuclear layers’) alternate with layers of low cell body densities (‘plexiform layers’). Different tissue layers varied significantly in their mechanical properties, with the photoreceptor layer being the stiffest region of the retina, and the inner plexiform layer belonging to the softest regions. As both techniques yielded similar results, our measurements allowed us to calibrate the Brillouin microscopy measurements and convert the Brillouin shift into a quantitative assessment of elastic tissue stiffness with optical resolution. Similar as in the mouse spinal cord and the developing Xenopus brain, we found a strong correlation between nuclear densities and tissue stiffness. Hence, the cellular composition of retinae appears to strongly contribute to local tissue stiffness, and Brillouin microscopy shows a great potential for the application in vivo to measure the mechanical properties of transparent tissues.

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Section: Discussionmentioning

confidence: 99%

The role of cell body density in ruminant retina mechanics assessed by atomic force and Brillouin microscopy

et al. 2017

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“…The difference between white and grey matter might stem from the lower cell density in the former 53 , which is structurally dependent on the oligodendrocyte connectivity, because demyelination in the rat spinal cord leads to lower stiffness and tensile stress 62 . Lower stiffness has also been reported for demyelinated regions in the murine brain parenchyma measured with magnetic resonance elastography (MRE) 63 . Although this seems to form a clear picture, it should be noted that there are also reports of white matter being 40% stiffer, and more viscous, than grey matter 55 .…”

Section: Tissue Considerationsmentioning

confidence: 91%

Materials and technologies for soft implantable neuroprostheses

2016

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| Implantable neuroprostheses are engineered systems designed to restore or substitute function for individuals with neurological deficits or disabilities. These systems involve at least one uni-or bidirectional interface between a living neural tissue and a synthetic structure, through which information in the form of electrons, ions or photons flows. Despite a few notable exceptions, the clinical dissemination of implantable neuroprostheses remains limited, because many implants display inconsistent long-term stability and performance, and are ultimately rejected by the body. Intensive research is currently being conducted to untangle the complex interplay of failure mechanisms. In this Review, we emphasize the importance of minimizing the physical and mechanical mismatch between neural tissues and implantable interfaces. We explore possible materials solutions to design and manufacture neurointegrated prostheses, and outline their immense therapeutic potential. NATURE REVIEWS | MATERIALSADVANCE ONLINE PUBLICATION | 1 REVIEWS© 2 0 1 6 M a c m i l l a n P u b l i s h e r s L i m i t e d , p a r t o f S p r i n g e r N a t u r e . A l l r i g h t s r e s e r v e d .

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“…[6][7][8][9][10][11][12][13][14][15][16][17][18][19] In MRE, the sample is excited mechanically, and the response is measured with magnetic resonance imaging. The primary goal of the technique is early detection of tissue lesions by determining the elasticity coefficients from the wavelengths of the stress waves.…”

Section: Introductionmentioning

confidence: 99%

“…The primary goal of the technique is early detection of tissue lesions by determining the elasticity coefficients from the wavelengths of the stress waves. After Ehman 6 proposed MRE system, MRE has been used to determine mechanical properties of various parts of body such as brain, 7,12 breast, 8,10 skeletal muscle, 9 liver, 11,17,18 heart, 11 lung, 13 and head and neck 15 as a research phase. Although MRE may be applied to detect mechanical properties of gels, which span a broad range of elasticity coefficients, the excitation source must contain a broad range of frequency components from about ten hertz to several tens of kilohertz.…”

Section: Introductionmentioning

confidence: 99%

High spatial and temporal resolution measurement of mechanical properties in hydrogels by non-contact laser excitation

et al. 2016

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Gels have received increased attention as potential materials for biological materials because they can exhibit similar mechanical properties. One obstacle for using gels is that their mechanical properties are significantly altered by defects, such as an inhomogeneous crosslink density distribution. If these defects could be detected and the values and spatial distributions of mechanical properties in the gel could be determined, it would be possible to apply gels for several fields. To achieve the high spatial and temporal resolution measurement of mechanical properties in hydrogels, in our method, a conventional contact excitation device is replaced with a non-contact excitation using laser ablation for the input and magnetic resonance elastography to measure stress waves is replaced with the Schlieren method with a high-speed camera. Magnetic resonance elastography is a local measurement technique, and consequently, requires a lot of time to characterize a sample, as well as does not have sufficient spatial resolution to obtain a broad range of elasticity coefficients of gels. We use laser ablation to apply non-contact impulse excitations to gels to generate stress waves inside them. We can determine mechanical properties of gels using the stress waves’ propagation velocity.

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Demyelination reduces brain parenchymal stiffness quantified in vivo by magnetic resonance elastography

Cited by 205 publications

References 35 publications

The role of cell body density in ruminant retina mechanics assessed by atomic force and Brillouin microscopy

The role of cell body density in ruminant retina mechanics assessed by atomic force and Brillouin microscopy

Materials and technologies for soft implantable neuroprostheses

High spatial and temporal resolution measurement of mechanical properties in hydrogels by non-contact laser excitation

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