Confined polyelectrolytes: The complexity of a simple system.
(2015) In Journal of Computational Chemistry 36(21). p.1579-1586- Abstract
- The interaction between polyelectrolytes and counterions in confined situations and the mutual relationship between chain conformation and ion condensation is an important issue in several areas. In the biological field, it assumes particular relevance in the understanding of the packaging of nucleic acids, which is crucial in the design of gene delivery systems. In this work, a simple coarse-grained model is used to assess the cooperativity between conformational change and ion condensation in spherically confined backbones, with capsides permeable to the counterions. It is seen that the variation on the degree of condensation depends on counterion valence. For monovalent counterions, the degree of condensation passes through a minimum... (More)
- The interaction between polyelectrolytes and counterions in confined situations and the mutual relationship between chain conformation and ion condensation is an important issue in several areas. In the biological field, it assumes particular relevance in the understanding of the packaging of nucleic acids, which is crucial in the design of gene delivery systems. In this work, a simple coarse-grained model is used to assess the cooperativity between conformational change and ion condensation in spherically confined backbones, with capsides permeable to the counterions. It is seen that the variation on the degree of condensation depends on counterion valence. For monovalent counterions, the degree of condensation passes through a minimum before increasing as the confining space diminishes. In contrast, for trivalent ions, the overall tendency is to decrease the degree of condensation as the confinement space also decreases. Most of the particles reside close to the spherical wall, even for systems in which the density is higher closer to the cavity center. This effect is more pronounced, when monovalent counterions are present. Additionally, there are clear variations in the charge along the concentric layers that cannot be totally ascribed to polyelectrolyte behavior, as shown by decoupling the chain into monomers. If both chain and counterions are confined, the formation of a counterion rich region immediately before the wall is observed. Spool and doughnut-like structures are formed for stiff chains, within a nontrivial evolution with increasing confinement. © 2015 Wiley Periodicals, Inc. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/7484246
- author
- Nunes, Sandra C C ; Skepö, Marie LU and Pais, Alberto A C C
- organization
- publishing date
- 2015
- type
- Contribution to journal
- publication status
- published
- subject
- in
- Journal of Computational Chemistry
- volume
- 36
- issue
- 21
- pages
- 1579 - 1586
- publisher
- John Wiley & Sons Inc.
- external identifiers
-
- pmid:26096545
- wos:000357896900002
- scopus:84936991162
- pmid:26096545
- ISSN
- 1096-987X
- DOI
- 10.1002/jcc.23969
- language
- English
- LU publication?
- yes
- additional info
- The information about affiliations in this record was updated in December 2015. The record was previously connected to the following departments: Theoretical Chemistry (S) (011001039)
- id
- b22146dd-e4f5-44fb-9500-26cb5648f5af (old id 7484246)
- date added to LUP
- 2016-04-01 09:54:03
- date last changed
- 2023-04-03 01:16:35
@article{b22146dd-e4f5-44fb-9500-26cb5648f5af, abstract = {{The interaction between polyelectrolytes and counterions in confined situations and the mutual relationship between chain conformation and ion condensation is an important issue in several areas. In the biological field, it assumes particular relevance in the understanding of the packaging of nucleic acids, which is crucial in the design of gene delivery systems. In this work, a simple coarse-grained model is used to assess the cooperativity between conformational change and ion condensation in spherically confined backbones, with capsides permeable to the counterions. It is seen that the variation on the degree of condensation depends on counterion valence. For monovalent counterions, the degree of condensation passes through a minimum before increasing as the confining space diminishes. In contrast, for trivalent ions, the overall tendency is to decrease the degree of condensation as the confinement space also decreases. Most of the particles reside close to the spherical wall, even for systems in which the density is higher closer to the cavity center. This effect is more pronounced, when monovalent counterions are present. Additionally, there are clear variations in the charge along the concentric layers that cannot be totally ascribed to polyelectrolyte behavior, as shown by decoupling the chain into monomers. If both chain and counterions are confined, the formation of a counterion rich region immediately before the wall is observed. Spool and doughnut-like structures are formed for stiff chains, within a nontrivial evolution with increasing confinement. © 2015 Wiley Periodicals, Inc.}}, author = {{Nunes, Sandra C C and Skepö, Marie and Pais, Alberto A C C}}, issn = {{1096-987X}}, language = {{eng}}, number = {{21}}, pages = {{1579--1586}}, publisher = {{John Wiley & Sons Inc.}}, series = {{Journal of Computational Chemistry}}, title = {{Confined polyelectrolytes: The complexity of a simple system.}}, url = {{http://dx.doi.org/10.1002/jcc.23969}}, doi = {{10.1002/jcc.23969}}, volume = {{36}}, year = {{2015}}, }