Oxygen inhibition of free-radical polymerization is the dominant mechanism behind the "mold effect" on hydrogels

Oxygen inhibition of free-radical polymerization is the dominant mechanism behind the "mold effect" on hydrogels

Hydrogel surfaces are of great importance in numerous applications ranging from cell-growth studies and hydrogel-patch adhesion to catheter coatings and contact lenses. A common method to control the structure and mechanical/tribological properties of hydrogel surfaces is by synthesizing them in var...

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Veröffentlicht in:Soft matter 2021-07, Vol.17 (26), p.6394-643
Hauptverfasser: Simi, Rok, Mandal, Joydeb, Zhang, Kaihuan, Spencer, Nicholas D
Format: Artikel
Sprache:eng
Schlagworte:
Catheters
Chemistry
Contact lenses
Control methods
Free radical polymerization
Free radicals
Gels
Hydrogels
Hydrophobic and Hydrophilic Interactions
Hydrophobicity
Mechanical properties
Medical instruments
Molding materials
Molds
Oxygen
Polyacrylamide
Polymerization
Substrates
Tribology
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container_end_page 643
container_issue 26
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container_title Soft matter
container_volume 17
creator Simi, Rok
Mandal, Joydeb
Zhang, Kaihuan
Spencer, Nicholas D
description Hydrogel surfaces are of great importance in numerous applications ranging from cell-growth studies and hydrogel-patch adhesion to catheter coatings and contact lenses. A common method to control the structure and mechanical/tribological properties of hydrogel surfaces is by synthesizing them in various mold materials, whose influence has been widely ascribed to their hydrophobicity. In this work, we examine possible mechanisms for this "mold effect" on the surface of hydrogels during polymerization. Our results for polyacrylamide gels clearly rule out the effect of mold hydrophobicity as well as any thermal-gradient effects during synthesis. We show unequivocally that oxygen diffuses out of certain molding materials and into the reaction mixture, thereby inhibiting free-radical polymerization in the vicinity of the molding interface. Removal of oxygen from the system results in homogeneously cross-linked hydrogel surfaces, irrespective of the substrate material used. Moreover, by varying the amount of oxygen at the surface of the polymerizing solutions using a permeable membrane we are able to tailor the surface structures and mechanical properties of PAAm, PEGDA and HEMA hydrogels in a controlled manner. Oxygen, diffusing out of mold materials, leads to inhibition of hydrogel formation by FRP, leading preferentially to dangling chains at the gel surface, with consequences for the mechanical and tribological properties of the gel.
doi_str_mv 10.1039/d1sm00395j
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source MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Catheters
Chemistry
Contact lenses
Control methods
Free radical polymerization
Free radicals
Gels
Hydrogels
Hydrophobic and Hydrophilic Interactions
Hydrophobicity
Mechanical properties
Medical instruments
Molding materials
Molds
Oxygen
Polyacrylamide
Polymerization
Substrates
Tribology
title Oxygen inhibition of free-radical polymerization is the dominant mechanism behind the "mold effect" on hydrogels
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