Systematic profiling of spatiotemporal tissue and cellular stiffness in the developing brain

Iwashita, Misato; Kataoka, Noriyuki; Toida, Kazunori; Kosodo, Yoichi

doi:10.1242/dev.109637

Cited by 127 publications

(129 citation statements)

References 28 publications

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“…The biophysical properties and innate stiffness of niches within the brain are also likely to play a role in cell fate. A recent report noted a pattern of stiffness gradients in the embryonic brain, as measured using in situ atomic force microscopy (AFM) (Koser et al, 2016), and the SVZ specifically is known to stiffen gradually over the course of embryonic development (Iwashita et al, 2014), although the bulk elastic modulus of the brain does not appreciably change during development or postnatally (Majkut et al, 2013). Directly altering brain stiffness or blocking mechanotransduction during development results in aberrant axonal growth and migration (Koser et al, 2016), also implicating mechanical signals as regulators of this process.…”

Section: Ecm In the Developing Brainmentioning

confidence: 99%

Tissue mechanics regulate brain development, homeostasis and disease

Barnes

Przybyla

Weaver

2017

Journal of Cell Science

250

243

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All cells sense and integrate mechanical and biochemical cues from their environment to orchestrate organismal development and maintain tissue homeostasis. Mechanotransduction is the evolutionarily conserved process whereby mechanical force is translated into biochemical signals that can influence cell differentiation, survival, proliferation and migration to change tissue behavior. Not surprisingly, disease develops if these mechanical cues are abnormal or are misinterpreted by the cells – for example, when interstitial pressure or compression force aberrantly increases, or the extracellular matrix (ECM) abnormally stiffens. Disease might also develop if the ability of cells to regulate their contractility becomes corrupted. Consistently, disease states, such as cardiovascular disease, fibrosis and cancer, are characterized by dramatic changes in cell and tissue mechanics, and dysregulation of forces at the cell and tissue level can activate mechanosignaling to compromise tissue integrity and function, and promote disease progression. In this Commentary, we discuss the impact of cell and tissue mechanics on tissue homeostasis and disease, focusing on their role in brain development, homeostasis and neural degeneration, as well as in brain cancer.

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Section: Ecm In the Developing Brainmentioning

confidence: 99%

Tissue mechanics regulate brain development, homeostasis and disease

Barnes

Przybyla

Weaver

2017

Journal of Cell Science

250

243

View full text Add to dashboard Cite

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“…Stiffness gradients have been found in brain (2, 6–9), spinal cord (10), and retinal tissue (11). CNS tissue is characterized by a complex, non-linear, viscoelastic response to applied strain (relative sample deformation) or stress (force per unit area) (6–15).…”

Section: Introductionmentioning

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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“…36 In particular, NSCs have been shown to alter their proliferation, migration and fate in response to stiffness changes [12][13][14][15] and this has led to speculation properties may indeed influence the maintenance of the different cerebral cortex layers, including the ventricular zone (VZ) and SVZ NSC niches. 37 We observed that, over the range of collagen concentrations used here, hydrogel stiffness increased with collagen concentration from ca. 34 to 350 Pa.…”

Section: Discussionmentioning

confidence: 68%

“…30 -3000 Pa). [37][38][39] However, our stiffness measurement at 0.6 mg/mL (ca. 43 Crucially, collagen is transparent and therefore facilitates live cell monitoring of intraconstruct cells using both phase and fluorescence imaging technologies.…”

mentioning

confidence: 99%

Nanoengineering neural stem cells on biomimetic substrates using magnetofection technology

et al. 2016

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Tissue engineering studies are witnessing a major paradigm shift to cell culture on biomimetic materials that replicate native tissue features from which the cells are derived. Few studies have been performed in this regard for neural cells, particularly in nanomedicine. For example, platforms such as magnetic nanoparticles (MNPs) have proven efficient as multifunctional tools for cell tracking and genetic engineering of neural transplant populations. However, as far as we are aware, all current studies have been conducted using neural cells propagated on non-neuromimetic substrates that fail to represent the mechano-elastic properties of brain and spinal cord microenvironments. Accordingly, it can be predicted that such data is of less translational and physiological relevance than that derived from cells grown in neuromimetic environments. Therefore, we have performed the first test of magnetofection technology (enhancing MNP delivery using applied magnetic fields with significant potential for therapeutic application) and its utility in genetically engineering neural stem cells (NSCs; a population of high clinical relevance) propagated

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Systematic profiling of spatiotemporal tissue and cellular stiffness in the developing brain

Cited by 127 publications

References 28 publications

Tissue mechanics regulate brain development, homeostasis and disease

Tissue mechanics regulate brain development, homeostasis and disease

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

Nanoengineering neural stem cells on biomimetic substrates using magnetofection technology

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