Future Directions in Physiochemical Modeling of the Thermodynamics of Polyelectrolyte Coacervates (PECs)

Mapping Intimacies ◽

10.22541/au.163874886.68905569/v1 ◽

2021 ◽

Author(s):

Mohsen Ghasemi ◽

Ronald Larson

Keyword(s):

Electrostatic Interactions ◽

Dense Phase ◽

Future Directions ◽

Chain Flexibility ◽

Chain Molecules ◽

Chemical Effects ◽

Physical And Chemical ◽

Oppositely Charged ◽

Local Binding ◽

Long Chain

We review theories of polyelectrolyte (PE) coacervation, which is the spontaneous association of oppositely charged units of PEs and phase separation into a polymer-dense phase in aqueous solution. The simplest theories can be divided into “physics-based” and “chemistry-based” approaches. In the former, polyelectrolytes are treated as charged, long-chain, molecules, defined by charge level, chain length, and chain flexibility, but otherwise lacking chemical identity, with electrostatic interactions driving coacervation. The “chemistry-based” approaches focus on the local interactions between the species for which chemical identity is critical, and describe coacervation as the result of competitive local binding interactions of monomers and salts. In this article, we show how these approaches complement each other by presenting recent approaches that take both physical and chemical effects into account. Finally, we suggest future directions towards producing theories that are made quantitatively predictive by accounting for both long range electrostatic and local chemically specific interactions.

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Hybrid Acrylated Chitosan and Thiolated Pectin Cross-Linked Hydrogels with Tunable Properties

Polymers ◽

10.3390/polym13020266 ◽

2021 ◽

Vol 13 (2) ◽

pp. 266

Author(s):

Shaked Eliyahu ◽

Alexandra Galitsky ◽

Esther Ritov ◽

Havazelet Bianco-Peled

Keyword(s):

Electrostatic Interactions ◽

Profile Analysis ◽

Hybrid Hydrogel ◽

Texture Profile ◽

Ph Values ◽

X Ray Scattering ◽

Wide Range ◽

Michael Type Addition ◽

Physical And Chemical ◽

Hydrogel System

We developed and characterized a new hydrogel system based on the physical and chemical interactions of pectin partially modified with thiol groups and chitosan modified with acrylate end groups. Gelation occurred at high pectin thiol ratios, indicating that a low acrylated chitosan concentration in the hydrogel had a profound effect on the cross-linking. Turbidity, Fourier transform infrared spectroscopy, and free thiol determination analyses were performed to determine the relationships of the different bonds inside the gel. At low pH values below the pKa of chitosan, more electrostatic interactions were formed between opposite charges, but at high pH values, the Michael-type addition reaction between acrylate and thiol took place, creating harder hydrogels. Swelling experiments and Young’s modulus measurements were performed to study the structure and properties of the resultant hydrogels. The nanostructure was examined using small-angle X-ray scattering. The texture profile analysis showed a unique property of hydrogel adhesiveness. By implementing changes in the preparation procedure, we controlled the hydrogel properties. This hybrid hydrogel system can be a good candidate for a wide range of biomedical applications, such as a mucosal biomimetic surface for mucoadhesive testing.

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