Philip Neill scite author profile

Understanding and controlling the rheology of polymeric complex fluids that are pushed out-of-equilibrium is a fundamental problem in both industry and biology. For example, to package, repair, and replicate DNA, cells use enzymes to constantly manipulate DNA topology, length, and structure. Inspired by this feat, here we engineer and study DNA-based complex fluids that undergo enzymatically-driven topological and architectural alterations via restriction endonuclease (RE) reactions. We show that these systems display time-dependent rheological properties that depend on the concentrations and properties of the comprising DNA and REs. Through time-resolved microrheology experiments and Brownian Dynamics simulations, we show that conversion of supercoiled to linear DNA topology leads to a monotonic increase in viscosity. On the other hand, the viscosity of entangled linear DNA undergoing fragmentation displays a universal decrease that we rationalise using living polymer theory. Finally, to showcase the tunability of these behaviours, we design a DNA fluid that exhibits a time-dependent increase, followed by a temporally-gated decrease, of its viscosity. Our results present a class of polymeric fluids that leverage naturally occurring enzymes to drive diverse time-varying rheology by performing architectural alterations to the constituents.

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Prevalence of attention deficit hyperactivity symptoms in parents of children diagnosed with the condition

Marshall

Neill

Theodosiou

2011

Procedia - Social and Behavioral Sciences

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Optical-Tweezers-integrating-Differential-Dynamic-Microscopy maps the spatiotemporal propagation of nonlinear strains in polymer blends and composites

et al. 2022

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How local stresses propagate through polymeric fluids, and, more generally, how macromolecular dynamics give rise to viscoelasticity are open questions vital to wide-ranging scientific and industrial fields. Here, to unambiguously connect polymer dynamics to force response, and map the deformation fields that arise in macromolecular materials, we present Optical-Tweezers-integrating-Differential -Dynamic-Microscopy (OpTiDMM) that simultaneously imposes local strains, measures resistive forces, and analyzes the motion of the surrounding polymers. Our measurements with blends of ring and linear polymers (DNA) and their composites with stiff polymers (microtubules) uncover an unexpected resonant response, in which strain alignment, superdiffusivity, and elasticity are maximized when the strain rate is comparable to the entanglement rate. Microtubules suppress this resonance, while substantially increasing elastic storage, due to varying degrees to which the polymers buildup, stretch and flow along the strain path, and configurationally relax induced stress. More broadly, the rich multi-scale coupling of mechanics and dynamics afforded by OpTiDDM, empowers its interdisciplinary use to elucidate non-trivial phenomena that sculpt stress propagation dynamics–critical to commercial applications and cell mechanics alike.

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Dynamic concatenation leads to anomalous transport of ring DNA in concentrated solutions

Marfai¹,

Neill²,

McGorty³

et al. 2023

Biophysical Journal

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Dynamic concatenation of ring DNA leads to non-equilibrium viscoelasticity tuned by DNA size and concentration

Neill

Marfai²,

Sumair³

et al. 2023

Biophysical Journal

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Topological digestion drives time-varying rheology of entangled DNA fluids

Michieletto

Neill

Weir

et al. 2021

Preprint

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Understanding and controlling the rheology of polymeric fluids that are out-of-equilibrium is a fundamental problem in biology and industry. For example, to package, repair, and replicate DNA, cells use enzymes to constantly manipulate DNA topology, length, and structure. Inspired by this impressive feat, we combine experiments with theory and simulations to show that complex fluids of entangled DNA display a rich range of non-equilibrium material properties when undergoing enzymatic reactions that alter their topology and size. We reveal that while enzymatically-active fluids of linear DNA display universal viscous thinning, circular DNA fluids - undergoing the same non-equilibrium process - display thickening with a rate and degree that can be tuned by the DNA and enzyme concentrations. Our results open the way for the topological functionalization of DNA-based materials via naturally occurring enzymes to create a new class of "topologically-active" materials that can autonomously alter their rheological properties in a programmable manner.

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Comments on “How the production engineer can be helped by the metallurgist”

Wolfe¹,

Neill²,

Lloyd³

1953

Inst. Prod. Eng. J. UK

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Philip Neill

Topological digestion drives time-varying rheology of entangled DNA fluids

Prevalence of attention deficit hyperactivity symptoms in parents of children diagnosed with the condition

Optical-Tweezers-integrating-Differential-Dynamic-Microscopy maps the spatiotemporal propagation of nonlinear strains in polymer blends and composites

Dynamic concatenation leads to anomalous transport of ring DNA in concentrated solutions

Dynamic concatenation of ring DNA leads to non-equilibrium viscoelasticity tuned by DNA size and concentration

Topological digestion drives time-varying rheology of entangled DNA fluids

Comments on “How the production engineer can be helped by the metallurgist”

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