Concentration dependence of the longest relaxation times of dilute and semi-dilute polymer solutions

Liu, Yonggang; Jun, Yonggun; Steinberg, Victor

doi:10.1122/1.3160734

Cited by 112 publications

(107 citation statements)

References 46 publications

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“…We estimate from the optical size that the DNA concentration inside a globule produced under 200 V∕cm is about 7c Ã (the segment concentration inside a equilibrium DNA coil is c Ã ). This concentration is very close to the critical concentration (∼9c Ã ) for the onset of entangled regime in semidilute DNA solutions (34) and thus can possibly lead to selfentangling of the molecule. However, an internal DNA concentration of 7c Ã alone does not give rise to enough entanglements to fully account for the observed slow expansion as it only corresponds to an equilibrium number of entanglements on order of 1 (35).…”

Section: Resultsmentioning

confidence: 94%

Compression and self-entanglement of single DNA molecules under uniform electric field

Tang

Doyle

2011

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

134

168

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We experimentally study the effects of a uniform electric field on the conformation of single DNA molecules. We demonstrate that a moderate electric field (∼200 V∕cm) strongly compresses isolated DNA polymer coils into isotropic globules. Insight into the nature of these compressed states is gained by following the expansion of the molecules back to equilibrium after halting the electric field. We observe two distinct types of expansion modes: a continuous molecular expansion analogous to a compressed spring expanding, and a much slower expansion characterized by two long-lived metastable states. Fluorescence microscopy and stretching experiments reveal that the metastable states are the result of intramolecular self-entanglements induced by the electric field. These results have broad importance in DNA separations and single molecule genomics, polymer rheology, and DNA-based nanofabrication.DNA conformation | electrophoresis | polymer physics | knots | microfluidic T he use of electric fields to transport DNA has become an essential technique for a variety of research areas including molecular biology, gene therapy, and fundamental studies of polyelectrolytes (1). In most applications, nonlinear electrokinetics (2) due to the interplay of negatively charged DNA and the electric field are neglected. However, Viovy and coworkers (3, 4) demonstrated the ability of an electric field on order of 100 V∕cm to induce strong intermolecular DNA aggregation in a standard electrophoresis buffer in the absence of a sieving matrix. Follow-up studies (5, 6) have attributed the aggregation to an electrohydrodynamic instability triggered by a coupling of macroion (DNA) concentration fluctuations and electric field induced flows beyond the Debye length scale in a moderately concentrated DNA solution (around the DNA overlap concentration c Ã ). These results shed light onto why it is so difficult to separate large DNA molecules using capillary electrophoresis.Over the last decade there has been a shift from techniques measuring ensemble-averaged molecular properties (e.g., the aforementioned capillary electrophoresis experiments), to techniques that manipulate single, dilute DNA molecules in micro/ nanofluidic devices or nanopores (7-9). Electric fields are a convenient mode to transport DNA as they scale favorably with device dimensions. The long standing belief in such dilute, single molecule experiments is that uniform DC (direct current) electric fields (up to a few hundred V∕cm in standard electrophoresis buffers) do not greatly perturb the conformation of large DNA unless some sort of sieving matrix is used (e.g., gel or microfabricated post array) (1). Numerous fluorescence microscopy experiments confirm this belief to be true [see (10) for a recent review], but are typically limited to field strengths of a few tens of V∕cm to avoid image blur. Much larger electric fields give rise to some chain orientation and possibly some slight chain stretching (11), though the stretching is inconclusive because it is not directly meas...

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Section: Resultsmentioning

confidence: 94%

Compression and self-entanglement of single DNA molecules under uniform electric field

Tang

Doyle

2011

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

134

168

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“…However, the relaxation times of polymer solutions, which were measured under shear flows, slowly increased until c reaches c* (refs 45,46), which was also observed by single DNA experiments 47 . The relative difference between the relaxation time of the 5 p.p.m.…”

Section: Methodsmentioning

confidence: 87%

DNA-based highly tunable particle focuser

et al. 2013

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DNA is distinguished by both long length and structural rigidity. Classical polymer theories predict that DNA enhances the non-Newtonian elastic properties of its dilute solution more significantly than common synthetic flexible polymers because of its larger size and longer relaxation time. Here we exploit this property to report that under Poiseuille microflow, rigid spherical particles laterally migrate and form a tightly focused stream in an extremely dilute DNA solution (0.0005 (w/v)%). By the use of the DNA solution, we achieve highly efficient focusing (499.5%) over an unprecedented wide range of flow rates (ratio of maximum to minimum flow rates B400). This highly tunable particle-focusing technique can be used in the design of cost-effective portable flow cytometers, high-throughput cell analysis and also for cell sorting by size. We demonstrate that DNA is an efficient elasticity enhancer, which originates from its unique structural properties.

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“…Only the samples with PVP concentration decidedly in the semidilute entangled regime (~0.23 g/mL and ~0.27 g/mL) exhibit purely shear thinning behavior (Figure 4a). We note here that the critical concentration for entanglement (see Figure S1 and Figure S2 in supporting material) is determined by a semiempirical method, 38,39 and it is possible that the ~0.16 g/mL PVP/DMSO solutions at 25 °C may still be in the semidilute unentangled regime, as the inferred critical concentration for entanglement is 0.155 g/mL. The samples with 1a in ~0.19 g/mL PVP/DMSO solutions at 25 °C, however, exhibit steady shear behavior that is quite different from that of samples in the semidilute unentangled regime (Figure 4a), and so we believe that the ~0.19 g/mL PVP/DMSO solutions at 25 °C are definitely in the semidilute entangled regime.…”

Section: Discussionmentioning

confidence: 99%

Divergent Shear Thinning and Shear Thickening Behavior of Supramolecular Polymer Networks in Semidilute Entangled Polymer Solutions

2011

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The steady shear behavior of metallo-supramolecular polymer networks formed by bis-Pd(II) cross-linkers and semidilute entangled solutions of poly(4-vinylpyridine) (PVP) in dimethyl sulfoxide (DMSO) or N,N-dimethyl formamide (DMF) is reported. The steady shear behavior of the networks depends on the dissociation rate and association rate of the cross-linkers, the concentration of cross-linkers, and the concentration of the polymer solution. The divergent steady shear behavior—shear thinning versus shear thickening—of samples with identical structure but different cross-linker dynamics (J. Phys. Chem. Lett. 2010, 1, 1683-1686) is further explored in this paper. The divergent steady shear behavior for networks with different cross-linkers is connected to a competition between different time scales: the average time that a cross-linker remains open (τ1) and the local relaxation time of a segment of polymer chain (τsegment). When τ1 is larger than τsegment, shear thickening is observed. When τ1 is smaller than τsegment, only shear thinning is observed.

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Concentration dependence of the longest relaxation times of dilute and semi-dilute polymer solutions

Cited by 112 publications

References 46 publications

Compression and self-entanglement of single DNA molecules under uniform electric field

Compression and self-entanglement of single DNA molecules under uniform electric field

DNA-based highly tunable particle focuser

Divergent Shear Thinning and Shear Thickening Behavior of Supramolecular Polymer Networks in Semidilute Entangled Polymer Solutions

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