Structural Characterization and Statistical-Mechanical Model of Epidermal Patterns

Chen, Duyu; Aw, Wen; Devenport, Danelle; Torquato, Salvatore

doi:10.1016/j.bpj.2016.10.036

Cited by 14 publications

(19 citation statements)

References 110 publications

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“…Figure 54 shows that there is excellent agreement between the structure factors obtained from the aforementioned statisticalmechanical cell model and their experimental counterparts for the total population and the individual cell types. This epithelium system stands in contrast to epithelia in mammalian skin, which has been shown not be hyperuniform [317], since the latter, unlike the former, must be very pliable to deformations. Figure 54: Comparison of the structure factors S (k) of the experimentally obtained and simulated point configurations representing the spatial arrangements of the individual cell types and total population, as presented in Ref.…”

Section: Avian Photoreceptor Cellsmentioning

confidence: 93%

Hyperuniform states of matter

2018

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Hyperuniform states of matter are correlated systems that are characterized by an anomalous suppression of longwavelength (i.e., large-length-scale) density fluctuations compared to those found in garden-variety disordered systems, such as ordinary fluids and amorphous solids. All perfect crystals, perfect quasicrystals and special disordered systems are hyperuniform. Thus, the hyperuniformity concept enables a unified framework to classify and structurally characterize crystals, quasicrystals and the exotic disordered varieties. While disordered hyperuniform systems were largely unknown in the scientific community over a decade ago, now there is a realization that such systems arise in a host of contexts across the physical, materials, chemical, mathematical, engineering, and biological sciences, including disordered ground states, glass formation, jamming, Coulomb systems, spin systems, photonic and electronic band structure, localization of waves and excitations, self-organization, fluid dynamics, number theory, stochastic point processes, integral and stochastic geometry, the immune system, and photoreceptor cells. Such unusual amorphous states can be obtained via equilibrium or nonequilibrium routes, and come in both quantum-mechanical and classical varieties. The connections of hyperuniform states of matter to many different areas of fundamental science appear to be profound and yet our theoretical understanding of these unusual systems is only in its infancy. The purpose of this review article is to introduce the reader to the theoretical foundations of hyperuniform ordered and disordered systems. Special focus will be placed on fundamental and practical aspects of the disordered kinds, including our current state of knowledge of these exotic amorphous systems as well as their formation and novel physical properties.

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Section: Avian Photoreceptor Cellsmentioning

confidence: 93%

Hyperuniform states of matter

2018

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“…Qualitatively, our finding of power law correlations says that cells in growing epithelia are more clumped together on large scales than for a totally random spatial distribution, with the effect becoming more pronounced for smaller k/γ0. Correlations in cell density are experimentally accessible (13)(14)(15)(16), and we expect that similar clumping should be observed in spatial distributions of mitotic cells (which, intriguingly, are known cluster in some tissues (1,24)). Estimates of the exponent 2k/γ0 could be used to determine the strength c of mechanical feedback, which has not previously been measured.…”

Section: Isotropic Growthmentioning

confidence: 64%

“…ξ ll − 2ξ [14] ∂t ZT = ξ ⊥ [15] ∂t ZL = ξ ll + 2 k k (d) ξ , [16] where k (d) is defined similarly to k, and ZT = G ⊥ /Ḡ and ZL = [ G ll +2(k/k (d) ) G ]/Ḡ are the amplitudes respectively of transverse and longitudinal soft modes, which do not produce any stress and thus grow diffusively. Before studying the density and clone statistics, we next consider these soft modes more carefully.…”

Section: Anisotropic Growthmentioning

confidence: 99%

“…In experiments, noise in growth has most often been probed through the size and spatial distribution of clones of cells (4)(5)(6)(7)(8)(9)(10), especially of neutral clones that are genetically identical to surrounding tissue except for a clone marker. Cell density variation has also been observed directly in culture (11)(12)(13)(14)(15) and in fixed tissues (16), as have correlations in positions of mitotic cells (1), and size asymmetry between contralateral organs can be used as an indirect readout of noise levels (17).…”

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The statistics of noisy growth with mechanical feedback in elastic tissues

Damavandi¹,

Lubensky²

2018

Preprint

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“…In experiments, noise in growth has most often been probed through the size and spatial distribution of clones of cells (4-10), especially of neutral clones that are genetically identical to surrounding tissue except for a clone marker. Cell density variation has also been observed directly in culture (11)(12)(13)(14)(15) and in fixed tissues (16), as have correlations in positions of mitotic cells (1), and size asymmetry between contralateral organs can be used as an indirect readout of noise levels (17).…”

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Statistics of noisy growth with mechanical feedback in elastic tissues

Damavandi

Lubensky

2019

Proc. Natl. Acad. Sci. U.S.A.

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Tissue growth is a fundamental aspect of development and is intrinsically noisy. Stochasticity has important implications for morphogenesis, precise control of organ size, and regulation of tissue composition and heterogeneity. However, the basic statistical properties of growing tissues, particularly when growth induces mechanical stresses that can in turn affect growth rates, have received little attention. Here, we study the noisy growth of elastic sheets subject to mechanical feedback. Considering both isotropic and anisotropic growth, we find that the density-density correlation function shows power law scaling. We also consider the dynamics of marked, neutral clones of cells. We find that the areas (but not the shapes) of two clones are always statistically independent, even when they are adjacent. For anisotropic growth, we show that clone size variance scales like the average area squared and that the mode amplitudes characterizing clone shape show a slow 1/n decay, where n is the mode index. This is in stark contrast to the isotropic case, where relative variations in clone size and shape vanish at long times. The high variability in clone statistics observed in anisotropic growth is due to the presence of two soft modes-growth modes that generate no stress. Our results lay the groundwork for more in-depth explorations of the properties of noisy tissue growth in specific biological contexts. tissue mechanics | noisy growth | clonal dynamics | mechanical feedback G rowth is central to biology and usually involves a level of stochasticity (1-3). The presence of such noise can have significant consequences for developmental processes like morphogenesis and the regulation of organ size. However, relatively little is known about quantitative aspects of stochastic growth. Our goal here is to understand the interplay between noise and mechanical feedback in growing elastic tissues. To that end, we present a generic, continuum model of such tissues and use it to study measurable features of tissue architecture like density fluctuations and statistics of marked, neutral clones. Our model makes a number of unexpected predictions, including the presence of power law correlations in space and the existence of soft modes that allow clone sizes to grow diffusively, evading the effects of mechanical feedbacks that might otherwise be expected to limit clone size variability.In experiments, noise in growth has most often been probed through the size and spatial distribution of clones of cells (4-10), especially of neutral clones that are genetically identical to surrounding tissue except for a clone marker. Cell density variation has also been observed directly in culture (11-15) and in fixed tissues (16), as have correlations in positions of mitotic cells (1), and size asymmetry between contralateral organs can be used as an indirect readout of noise levels (17).Theoretically, the most thoroughly explored area is the noisy dynamics of stem cell populations (4,5,9), where zerodimensional descriptions are often appropriat...

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Structural Characterization and Statistical-Mechanical Model of Epidermal Patterns

Cited by 14 publications

References 110 publications

Hyperuniform states of matter

Hyperuniform states of matter

The statistics of noisy growth with mechanical feedback in elastic tissues

Statistics of noisy growth with mechanical feedback in elastic tissues

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