Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.

Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.

The spontaneous self-organization of conformational isomers from identical precursors is of fundamental importance in chemistry. Since the precursors are identical, it is the multi-unit interactions, characteristics of the intermediates, and assembly pathways that determine the final conformation. H...

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Main Authors: Shivendra Pandey, Daniel Johnson, Ryan Kaplan, Joseph Klobusicky, Govind Menon, David H Gracias
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2014-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4191966?pdf=render
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spelling doaj-ff1836037886457d8240e19832ad28c22020-11-25T01:52:45ZengPublic Library of Science (PLoS)PLoS ONE1932-62032014-01-01910e10896010.1371/journal.pone.0108960Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.Shivendra PandeyDaniel JohnsonRyan KaplanJoseph KlobusickyGovind MenonDavid H GraciasThe spontaneous self-organization of conformational isomers from identical precursors is of fundamental importance in chemistry. Since the precursors are identical, it is the multi-unit interactions, characteristics of the intermediates, and assembly pathways that determine the final conformation. Here, we use geometric path sampling and a mesoscale experimental model to investigate the self-assembly of a model polyhedral system, an octahedron, that forms two isomers. We compute the set of all possible assembly pathways and analyze the degrees of freedom or rigidity of intermediates. Consequently, by manipulating the degrees of freedom of a precursor, we were able to experimentally enrich the formation of one isomer over the other. Our results suggest a new approach to direct pathways in both natural and synthetic self-assembly using simple geometric criteria. We also compare the process of folding and unfolding in this model with a geometric model for cyclohexane, a well-known molecule with chair and boat conformations.http://europepmc.org/articles/PMC4191966?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Shivendra Pandey
Daniel Johnson
Ryan Kaplan
Joseph Klobusicky
Govind Menon
David H Gracias
spellingShingle Shivendra Pandey
Daniel Johnson
Ryan Kaplan
Joseph Klobusicky
Govind Menon
David H Gracias
Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
PLoS ONE
author_facet Shivendra Pandey
Daniel Johnson
Ryan Kaplan
Joseph Klobusicky
Govind Menon
David H Gracias
author_sort Shivendra Pandey
title Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
title_short Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
title_full Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
title_fullStr Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
title_full_unstemmed Self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
title_sort self-assembly of mesoscale isomers: the role of pathways and degrees of freedom.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2014-01-01
description The spontaneous self-organization of conformational isomers from identical precursors is of fundamental importance in chemistry. Since the precursors are identical, it is the multi-unit interactions, characteristics of the intermediates, and assembly pathways that determine the final conformation. Here, we use geometric path sampling and a mesoscale experimental model to investigate the self-assembly of a model polyhedral system, an octahedron, that forms two isomers. We compute the set of all possible assembly pathways and analyze the degrees of freedom or rigidity of intermediates. Consequently, by manipulating the degrees of freedom of a precursor, we were able to experimentally enrich the formation of one isomer over the other. Our results suggest a new approach to direct pathways in both natural and synthetic self-assembly using simple geometric criteria. We also compare the process of folding and unfolding in this model with a geometric model for cyclohexane, a well-known molecule with chair and boat conformations.
url http://europepmc.org/articles/PMC4191966?pdf=render
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