Thermoresponsive supramolecular nanocontainers from ionic complexes of amphiphilic wedge-shaped mesogens and polybases

[Display omitted] •Thermoresponsive nanocontainers are synthesized from ionic complexes of polybases.•The complexes can be readily (re)formed by simple mixing of the components.•Resulting comb-like complexes with wedge-shaped ligands exhibit multiscale ordering.•Ligand type controls shape and therma...

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Bibliographic Details
Published in:Journal of colloid and interface science 2025-01, Vol.678 (Pt A), p.458-469
Main Authors: Maryasevskaya, Alina V., Anokhin, Denis V., Buglakov, Aleksandr I., Subcheva, Elena N., Zhu, Xiaomin, Barinov, Nikolay A., Klinov, Dmitriy V., Ivanov, Dimitri A.
Format: Article
Language:English
Subjects:
Amphiphilic wedge-shaped mesogens
Polyelectrolyte-surfactant complexes
Polymersomes
Temperature-responsive polymer
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Summary:[Display omitted] •Thermoresponsive nanocontainers are synthesized from ionic complexes of polybases.•The complexes can be readily (re)formed by simple mixing of the components.•Resulting comb-like complexes with wedge-shaped ligands exhibit multiscale ordering.•Ligand type controls shape and thermal stability of nanocontainers.•Coarse-grain simulation explores the routes of vesicle and nanocylinders formation. Multi-responsive polymeric nanocontainers attract significant attention for their potential applications in biotechnology, drug delivery, catalysis, and other fields. By incorporating a liquid-crystalline (LC) mesogenic ligand with an alkyl tail length ranging from 8–12 carbons, ionically linked to the polymer backbone, we generate vesicles with walls significantly thinner than those of conventional polymersomes, approaching the thickness of a lipid bilayer. These LC vesicles, ranging in size from 50–120 nm, are designed to be mechanically robust due to the alignment of the hydrophilic polymer backbone within the plane of the vesicle wall. Additionally, incorporating a temperature-sensitive block into the polymer structure imparts thermoresponsiveness to the nanocontainers, enhancing their functionality and adaptability for various applications. Ionic complexes of hydrophilic polybases, specifically poly(2-(dimethylamino)ethyl methacrylate) (PDMAEMA) and PDMAEMA-b-PNIPAM (poly(N-isopropylacrylamide)) block copolymers, with amphiphilic wedge-shaped mesogens bearing a sulfonic acid group at the focal point were synthesized. The designed nanocontainers, in the form of either vesicles or nanotubes, exhibit a well-defined wall thickness of 5 nm, dictated by the organization of a smectic LC phase. The constructed coarse-grained models elucidate the mechanism of self-assembly, demonstrating that the balance between the hydrophilicity of the main polymer chain and the hydrophobicity of the wedge-shaped pendant groups determines both the internal and external structure of the vesicles.
ISSN:0021-9797
1095-7103
1095-7103
DOI:10.1016/j.jcis.2024.08.158