Vat photopolymerization of charged monomers: 3D printing with supramolecular interactions

Additive manufacturing enables the creation of novel structures and geometries previously unattainable through traditional processing techniques. In particular, vat photopolymerization provides unprecedented resolution through the tailored delivery of light with photo-crosslinkable or photo-polymeri...

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Veröffentlicht in:	Polymer chemistry 2019-03, Vol.10 (12), p.1442-1451
Hauptverfasser:	Wilts, Emily M., Pekkanen, Allison M., White, B. Tyler, Meenakshisundaram, Viswanath, Aduba, Donald C., Williams, Christopher B., Long, Timothy E.
Format:	Artikel
Sprache:	eng
Schlagworte:	Acrylamide Crosslinking Dependence Dissolution Elongation Hydrogels Hydrogen bonding Mechanical properties Monomers Organic chemistry Photopolymerization Polymer chemistry Polymerization Tensile properties Three dimensional printing
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container_title	Polymer chemistry
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creator	Wilts, Emily M. Pekkanen, Allison M. White, B. Tyler Meenakshisundaram, Viswanath Aduba, Donald C. Williams, Christopher B. Long, Timothy E.
description	Additive manufacturing enables the creation of novel structures and geometries previously unattainable through traditional processing techniques. In particular, vat photopolymerization provides unprecedented resolution through the tailored delivery of light with photo-crosslinkable or photo-polymerizable materials. Traditionally, chemical crosslinks generate a permanent network, which exhibits swelling but not dissolution. In this work, photopolymerization of photo-reactive monomers with acrylate, acrylamide, and vinyl polymerizable sites enabled the formation of water-soluble 3D printed parts using vat photopolymerization. A library of monomers with varied ionic and hydrogen bonding sites provided photopolymerized films with tensile properties approaching 1200% elongation at break and 0.47 MPa stress at 100% elongation. The rate of polymerization and the subsequent mechanical properties revealed a dependence on the type of supramolecular interactions and functionality on the resulting hydrogel. The diverse functionality of the monomers enabled aqueous dissolution times ranging from 27 to 41 min. Vat photopolymerization of a trimethylammonium ethyl acrylate chloride solution and with 30 wt% N -vinyl pyrrolidone provided 3D parts with fine structural resolution. This method of creating soluble, water-swollen structures through vat photopolymerization provides future research with a larger library of monomers for diverse applications including soluble support scaffolds.
doi_str_mv	10.1039/C8PY01792A
format	Article
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subjects	Acrylamide Crosslinking Dependence Dissolution Elongation Hydrogels Hydrogen bonding Mechanical properties Monomers Organic chemistry Photopolymerization Polymer chemistry Polymerization Tensile properties Three dimensional printing
title	Vat photopolymerization of charged monomers: 3D printing with supramolecular interactions
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