Stable DNA-based reaction–diffusion patterns

Zenk, Johannes; Scalise, Dominic; Wang, Kaiyuan; Dorsey, Phillip; Fern, Joshua; Cruz, Ariana; Schulman, Rebecca

doi:10.1039/c7ra00824d

Cited by 30 publications

(36 citation statements)

References 65 publications

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“…(1). For instance, recent advances in (bio)materials science are enabling material design and control at submicron and nano scales [66] through DNA circuits based on reaction-diffusion systems [67,68]. Working at such small scales, it is important to assess the potential quantitative and qualitative influence of external and internal noise in the relevant reaction-diffusion processes and systems.…”

Section: Discussionmentioning

confidence: 99%

Kardar–Parisi–Zhang universality class for the critical dynamics of reaction–diffusion fronts

Barreales¹,

Meléndez²,

Cuerno³

et al. 2020

J. Stat. Mech.

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We have studied front dynamics for the discrete A + A ↔ A reactiondiffusion system, which in the continuum is described by the (stochastic) Fisher-Kolmogorov-Petrovsky-Piscunov equation. We have revisited this discrete model in two space dimensions by means of extensive numerical simulations and an improved analysis of the time evolution of the interface separating the stable and unstable phases. In particular, we have measured the full set of critical exponents which characterize the spatio-temporal fluctuations of such front for different lattice sizes, focusing mainly in the front width and correlation length. These exponents are in very good agreement with those computed in [E. Moro, Phys. Rev. Lett. 87, 238303 (2001)] and correspond to those of the Kardar-Parisi-Zhang (KPZ) universality class for onedimensional interfaces. Furthermore, we have studied the one-point statistics and the covariance of rescaled front fluctuations, which had remained thus far unexplored in the literature and allows for a further stringent test of KPZ universality. arXiv:1910.06211v1 [cond-mat.stat-mech]

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Section: Discussionmentioning

confidence: 99%

Kardar–Parisi–Zhang universality class for the critical dynamics of reaction–diffusion fronts

Barreales¹,

Meléndez²,

Cuerno³

et al. 2020

J. Stat. Mech.

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“…To address this need, recent work has begun to explore the feasibility of DNA-only reaction-diffusion patterns. 29,[34][35][36][37] Toehold-mediated DNA strand displacement has proved to be a convenient framework for implementing complex reaction sequences using synthetic DNA in well-mixed test tubes. 38,39 Using the principles of strand displacement, researchers have created sophisticated reaction networks that perform computation like neural networks, 40,41 diagnostic classifiers, 42 dynamic 3D nanostructures 43,44 and even approximate the dynamics of formal, mathematically specified chemical reaction networks (CRNs).…”

Section: Introductionmentioning

confidence: 99%

Programmable patterns in a DNA-based reaction–diffusion system

Chen

Seelig

2020

Soft Matter

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“…Previously, Zenk et al. demonstrated the formation of stable 1‐dimensional DNA gradients in an agarose hydrogel medium by supplying reactants from liquid reservoirs at the edges of the gel [27] . Here, we construct attractor patterns using synthetic DNA strand displacement networks (Figure 1 a).…”

Section: Introductionmentioning

confidence: 98%

“…[12] Previously,Z enk et al demonstrated the formation of stable 1-dimensional DNAg radients in an agarose hydrogel medium by supplying reactants from liquid reservoirs at the edges of the gel. [27] Here,weconstruct attractor patterns using synthetic DNAs trand displacement networks ( Figure 1a). We show how such patterns form as designed and can recover their original shapes after perturbations.T oprecisely perturb patterns,w eu se UV light-triggered strand displacement reactions that degrade the patterned species (Figure 1b,c).…”

Section: Introductionmentioning

confidence: 99%

DNA Reaction–Diffusion Attractor Patterns

2020

Self Cite

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Living systems can form and recover complex chemical patterns with precisely sized features in the ranges of tens or hundreds of microns.W eshow howdesigned reactiondiffusion processes can likewise produce precise patterns, termed attractor patterns,t hat reform their precise shape after being perturbed. We use oligonucleotide reaction networks, photolithography,a nd microfluidic delivery to form precisely controlled attractor patterns and study the responses of these patterns to different localized perturbations.Linear and "hill"shaped patterns formed and stabilized into shapes and at time scales consistent with reaction-diffusion models.W hen patterns were perturbed in particular locations with UV light, they reliably reformed their steady-state profiles.R ecovery also occurred after repeated perturbations.B yd esigning the farfrom-equilibrium dynamics of ac hemical system, this study shows howitispossible to design spatial patterns of molecules that are sustained and regenerated by continually evolving towards aspecific steady state configuration.

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Stable DNA-based reaction–diffusion patterns

Cited by 30 publications

References 65 publications

Kardar–Parisi–Zhang universality class for the critical dynamics of reaction–diffusion fronts

Kardar–Parisi–Zhang universality class for the critical dynamics of reaction–diffusion fronts

Programmable patterns in a DNA-based reaction–diffusion system

DNA Reaction–Diffusion Attractor Patterns

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