Development of a Coarse-Grained Model of Chitosan for Predicting Solution Behavior

Benner, Steven W.; Hall, Carol K.

doi:10.1021/acs.jpcb.6b03407

Cited by 31 publications

(27 citation statements)

References 43 publications

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“…Provided the system is well-parameterized and the force field carefully chosen, MD simulations can replicate the key results of more realistic but computationally expensive calculation techniques. MD studies have been used to map the self-assembly pathways of peptides, [37][38][39] lipids, 40,41 and polysaccharides, 42 as well as generalized polymers, [43][44][45] rod-shaped molecules, 46,47 and colloidal particles. 48,49 Simulations have captured the formation of experimentally observable structures such as b sheets, cylindrical micelles, and phospholipid bilayers and provided realistic illustrations of their interactions with solvents, ions, and biologically relevant additives.…”

Section: Figure 1 Stages In the Hierarchical Self-assembly Of Fibroumentioning

confidence: 99%

Scrolling of Supramolecular Lamellae in the Hierarchical Self-Assembly of Fibrous Gels

Jones

Kennedy

Walker

et al. 2017

Chem

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Gelation by small molecules is enormously topical in catalysis, nanomaterials, drug delivery, and pharmaceutical crystallization. The way in which gelators selforganize to give a 3D gel network is poorly understood. How does a system progress from a continuous pattern of supramolecular motifs to a network of fibers with well-defined morphologies? Why are gel fibers so homogeneous, and why do they form instead of crystals? This work shows, predictively, that gels arise by the scrolling of sheets with asymmetric surface structures.

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Section: Figure 1 Stages In the Hierarchical Self-assembly Of Fibroumentioning

confidence: 99%

Scrolling of Supramolecular Lamellae in the Hierarchical Self-Assembly of Fibrous Gels

Jones

Kennedy

Walker

et al. 2017

Chem

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“…Different strategies for the parametrization of bottom-up CG models for different polysaccharides, which preserve as much chemical detail of the atomistic system as possible have been pursued in the past [24–27]. In addition, the popular top-down MARTINI CG model [28–30] has recently been extended to include parameters specifically for modeling the α -Chitin [31] crystal and for GlcNac and [32] monomers, which have been used to model chitosan self assembly with discontinuous molecular dynamics simulations.…”

Section: Introductionmentioning

confidence: 99%

An accurate coarse-grained model for chitosan polysaccharides in aqueous solution

Tsereteli

Grafmüller

2017

PLoS ONE

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Computational models can provide detailed information about molecular conformations and interactions in solution, which is currently inaccessible by other means in many cases. Here we describe an efficient and precise coarse-grained model for long polysaccharides in aqueous solution at different physico-chemical conditions such as pH and ionic strength. The Model is carefully constructed based on all-atom simulations of small saccharides and metadynamics sampling of the dihedral angles in the glycosidic links, which represent the most flexible degrees of freedom of the polysaccharides. The model is validated against experimental data for Chitosan molecules in solution with various degree of deacetylation, and is shown to closely reproduce the available experimental data. For long polymers, subtle differences of the free energy maps of the glycosidic links are found to significantly affect the measurable polymer properties. Therefore, for titratable monomers the free energy maps of the corresponding links are updated according to the current charge of the monomers. We then characterize the microscopic and mesoscopic structural properties of large chitosan polysaccharides in solution for a wide range of solvent pH and ionic strength, and investigate the effect of polymer length and degree and pattern of deacetylation on the polymer properties.

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“…The total structure weight in this system is~10313.984 g/mol. The coarse-grained structure of chitosan was obtained using the model by Benner and Hall [37]. The number of beads in the coarse-grained representation of chitosan is 704.…”

Section: Methodsmentioning

confidence: 99%

“…If these parameters stabilized in time and did not change, then the complex reached an equilibrium and energetically favorable configuration. Next, we investigated three types of natural polymer matrix, representing a carbon framework with filler as a human albumin protein [36], with collagen [33] and with chitosan [37]. In all cases, the trigonal coarse-grained model of the carbon framework constructed by us and coarse-grained natural polymer models constructed using data from a protein database (PDB) and MARTINI model were used.…”

Section: Atomic Structure and Energy Of A Multilayer Natural Polymer mentioning

confidence: 99%

Specific Features of Structure, Electrical Conductivity and Interlayer Adhesion of the Natural Polymer Matrix from the Layers of Branched Carbon Nanotube Networks Filled with Albumin, Collagen and Chitosan

et al. 2018

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This paper considers the problem of creating a conductive matrix with a framework made of carbon nanotubes (CNTs) for cell and tissue engineering. In silico investigation of the electrical conductivity of the framework formed by T-junctions of single-walled carbon nanotubes (SWNTs) (12, 12) with a diameter of 1.5 nm has been carried out. A numerical evaluation of the contact resistance and electrical conductivity of seamless and suture T-junctions of SWCNTs is given. The effect of the type of structural defects in the contact area of the tubes on the contact resistance of the T-junction of SWCNTs was revealed. A coarse-grained model of a branched SWCNT network with different structure densities is constructed and its electrical conductivity is calculated. A new layered bioconstruction is proposed, the layers of which are formed by natural polymer matrixes: CNT-collagen, CNT-albumin and CNT-chitosan. The energy stability of the layered natural polymer matrix has been analyzed, and the adhesion of various layers to each other has been calculated. Based on the obtained results, a new approach has been developed in the formation of 3D electrically conductive bioengineering structures for the restoration of cell activity.

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Development of a Coarse-Grained Model of Chitosan for Predicting Solution Behavior

Cited by 31 publications

References 43 publications

Scrolling of Supramolecular Lamellae in the Hierarchical Self-Assembly of Fibrous Gels

Scrolling of Supramolecular Lamellae in the Hierarchical Self-Assembly of Fibrous Gels

An accurate coarse-grained model for chitosan polysaccharides in aqueous solution

Specific Features of Structure, Electrical Conductivity and Interlayer Adhesion of the Natural Polymer Matrix from the Layers of Branched Carbon Nanotube Networks Filled with Albumin, Collagen and Chitosan

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