The structure and interaction mechanism of a polyelectrolyte complex: a dissipative particle dynamics study

Meneses-Juárez, Efraín; Márquez‐Beltrán, César; Rivas-Silva, J.F.; Pal, U.; González‐Melchor, Minerva

doi:10.1039/c5sm00911a

Cited by 23 publications

(20 citation statements)

References 60 publications

(111 reference statements)

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“…As this review focuses primarily on the electrostatic co-assembly, the papers by Gonzalez-Melchor et al [161,165] deserve to be mentioned first. Using the potential of electrostatic interactions between smeared charges expressed by Equation ( 5), the authors applied the Ewald summation [166] for the enumeration of long-distance interactions and proposed a suitable alternative to the original method developed by Groot [102].…”

Section: Studies Aimed At the Improvement Of Dpd Methodology And At Important Trends Of The Behaviourmentioning

confidence: 99%

DPD Modelling of the Self- and Co-Assembly of Polymers and Polyelectrolytes in Aqueous Media: Impact on Polymer Science

et al. 2022

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This review article is addressed to a broad community of polymer scientists. We outline and analyse the fundamentals of the dissipative particle dynamics (DPD) simulation method from the point of view of polymer physics and review the articles on polymer systems published in approximately the last two decades, focusing on their impact on macromolecular science. Special attention is devoted to polymer and polyelectrolyte self- and co-assembly and self-organisation and to the problems connected with the implementation of explicit electrostatics in DPD numerical machinery. Critical analysis of the results of a number of successful DPD studies of complex polymer systems published recently documents the importance and suitability of this coarse-grained method for studying polymer systems.

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Section: Studies Aimed At the Improvement Of Dpd Methodology And At Important Trends Of The Behaviourmentioning

confidence: 99%

DPD Modelling of the Self- and Co-Assembly of Polymers and Polyelectrolytes in Aqueous Media: Impact on Polymer Science

et al. 2022

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“…The simulation steps of 100 000 were used. For the electrostatic interaction, we used the parameters previously employed by Meneses‐Juarez et al, Slater‐type charge distribution was used with smearing coefficient β = 0.929. Ewald real forces were truncated at

r_{normalc}^{ele} = 3

, real‐space convergence parameter was set as α = 0.975, for the reciprocal part, we considered the sum with a maximum vector k max = (5, 5, 5) .…”

Section: Simulation Methodsmentioning

confidence: 99%

“…All simulations were carried out with the DL_MESO 2.6 mesoscopic simulation package and the visualization was achieved by VMD . In salt‐added systems, the molar concentration of salt was calculated by

c^{real} = (N_{{normalI}^{+} {normalI}^{-}} / V^{*}) / (r_{normalc}^{3} N_{normalA})

, where

N_{{normalI}^{+} {normalI}^{-}}

is the number of salt ion pair and N A is the Avogadro number. The repulsive parameters between I + or I − bead and other beads are the same as that of C + or C − bead.…”

Section: Simulation Methodsmentioning

confidence: 99%

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Computer Simulation of DNA Condensation by PAMAM Dendrimer

Quan

et al. 2018

Macro Theory & Simulations

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In this study, dissipative particle dynamics is employed to investigate the complexation of poly(amido amine) dendrimer and single‐stranded DNA (ssDNA). A coarse‐grained model for ssDNA is constructed, which reproduces correctly the conformational behavior of the ssDNA molecules. The effects of pH, dendrimer generation, ionic strength, and dendrimer/ssDNA charge ratio on DNA–dendrimer complexes are explored. Simulation results show that ssDNA molecules can be significantly condensed by dendrimers and stable complexes are obtained by regulating the pH value. The ssDNA chain penetration would complicate its release from dendrimer, while this can be tuned by different generations of dendrimer. Salt concentration affects the size and stability of the complexes through ion screening effect. Dendrimer/ssDNA charge ratio can be used to control the size and morphology of the complex. This work can help design dendrimer‐based gene vectors.

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“…The articles that have not carried out simulations with dl meso dpd mainly refer to the code as available DPD modelling software. Some of these mention dl meso dpd as a code that can model coarse-grained systems [78], electrostatics [79] and many-body DPD [80], as well as an alternative to other developed DPD codes [81,82]. Other articles refer to dl meso dpd in the context of algorithmic developments -e.g.…”

Section: Work Carried Out Using DL Meso Dpdmentioning

confidence: 99%

DL_MESO_DPD: development and use of mesoscale modelling software

Seaton

2018

Molecular Simulation

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dl meso is a highly-scalable general purpose software package for mesoscale modelling. Created and developed at Daresbury Laboratory for the UK Collaborative Computational Project CCP5, it was intended to be a companion package to the flagship molecular dynamics code dl poly. One of dl meso's component codes, dl meso dpd, is based on dissipative particle dynamics, a mesoscale modelling technique with many similarities to classical molecular dynamics. While this code and dl poly were created with different applications in mind, they share a significant amount of functionality and development history. This article gives an overview on how dl meso dpd has been developed, including its shared history with dl polyand information on its current performance, and a selection of applications for which the code has been used.

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The structure and interaction mechanism of a polyelectrolyte complex: a dissipative particle dynamics study

Cited by 23 publications

References 60 publications

DPD Modelling of the Self- and Co-Assembly of Polymers and Polyelectrolytes in Aqueous Media: Impact on Polymer Science

DPD Modelling of the Self- and Co-Assembly of Polymers and Polyelectrolytes in Aqueous Media: Impact on Polymer Science

Computer Simulation of DNA Condensation by PAMAM Dendrimer

DL_MESO_DPD: development and use of mesoscale modelling software

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