Brain stiffness increases with myelin content

Weickenmeier, J., de Rooij, R., Budday, S., Steinmann, P. , Ovaert, T.C. and Kuhl, E. (2016) Brain stiffness increases with myelin content. Acta Biomaterialia, 42, pp. 265-272. (doi: 10.1016/j.actbio.2016.07.040) (PMID:27475531)

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Abstract

Brain stiffness plays an important role in neuronal development and disease, but reported stiffness values vary significantly for different species, for different brains, and even for different regions within the same brain. Despite extensive research throughout the past decade, the mechanistic origin of these stiffness variations remains elusive. Here we show that brain tissue stiffness is correlated to the underlying tissue microstructure and directly proportional to the local myelin content. In 116 indentation tests of six freshly harvested bovine brains, we found that the cerebral stiffnesses of 1.33 ± 0.63 kPa in white matter and 0.68 ± 0.20 kPa in gray matter were significantly different (p < 0.01). Strikingly, while the inter-specimen variation was rather moderate, the minimum and maximum cerebral white matter stiffnesses of 0.59 ± 0.19 kPa and 2.36 ± 0.64 kPa in each brain varied by a factor of four on average. To provide a mechanistic interpretation for this variation, we performed a histological characterization of the tested brain regions. We stained the samples with hematoxylin and eosin and luxol fast blue and quantified the local myelin content using image analysis. Interestingly, we found that the cerebral white matter stiffness increased with increasing myelin content, from 0.72 kPa at a myelin content of 64–2.45 kPa at a myelin content of 89%, with a Pearson correlation coefficient of (p < 0.01). This direct correlation could have significant neurological implications. During development, our results could help explain why immature, incompletely myelinated brains are softer than mature, myelinated brains and more vulnerable to mechanical insult as evident, for example, in shaken baby syndrome. During demyelinating disease, our findings suggest to use stiffness alterations as clinical markers for demyelination to quantify the onset of disease progression, for example, in multiple sclerosis. Taken together, our study indicates that myelin might play a more important function than previously thought: It not only insulates signal propagation and improves electrical function of single axons, it also provides structural support and mechanical stiffness to the brain as a whole.

Item Type:Articles
Additional Information:This study was supported by the German National Science Foundation grant STE 544/50-1 and by the Bavaria California Technology Center grant ’Mechanical Characterization of Brain Development’ to Silvia Budday and Paul Steinmann and by the Bio-X IIP seed grant ‘Understanding Gyrification Dynamics in the Human Brain’ to Ellen Kuhl.
Status:Published
Refereed:Yes
Glasgow Author(s) Enlighten ID:Steinmann, Professor Paul
Authors: Weickenmeier, J., de Rooij, R., Budday, S., Steinmann, P., Ovaert, T.C., and Kuhl, E.
College/School:College of Science and Engineering > School of Engineering > Infrastructure and Environment
Journal Name:Acta Biomaterialia
Publisher:Elsevier
ISSN:1742-7061
ISSN (Online):1878-7568
Published Online:27 July 2016

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