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Cell-Interactive Gelatin-Based <sup>19</sup>F MRI Tracers: An <i>In Vitro</i> Proof-of-Concept Study

Kristýna Kolouchová, Ondřej Groborz, Vı́t Herynek, Oleg V. Petrov, Jan Lang, David J. Dunlop, Laurens Parmentier, Anna Szabó, David Schaubroeck, Peter Adriaensens, Sandra Van Vlierberghe

2023Chemistry of Materials10 citationsDOIOpen Access PDF

Abstract

Cross-linked gelatin-based hydrogels are highly promising cell-interactive, biocompatible, and biodegradable materials serving tissue engineering. Moreover, gelatins with covalently bound methacrylamide (gel-MA) and 2-aminoethyl methacrylate moieties (gel-AEMA) can be cross-linked through ultraviolet (UV) irradiation, which allows light-based three-dimensional (3D)-printing of such hydrogels. Furthermore, the physicochemical and biological properties of these hydrogels can be broadly tuned by incorporating various comonomers into the polymer chains, which makes these hydrogels a widely applicable platform in tissue engineering and reconstructive surgery. However, monitoring the degradation rate of hydrogel-based implants in vivo is challenging, thereby prohibiting their broad clinical transition and further research. Therefore, herein, we describe the synthesis of 3D-printable gelatin-based hydrogels with N -(2,2-difluoroethyl)acrylamide (DFEA), detectable with the chemical shift of −123 ppm, which enables us to monitor these implants in vivo with 19 F magnetic resonance imaging (MRI) and assess their degradation kinetics. Next, we describe the physicochemical and biological properties of these hydrogels. Adding DFEA monomers into the reaction mixture accelerates their cross-linking kinetics. Moreover, increasing the DFEA content within the hydrogels increases their swelling ratio and 19 F MRI signal. All hydrogels were detectable at small quantities (<16 mg) using 19 F MRI. Moreover, our hydrogels supported the cell proliferation of adipose tissue-derived stem cells (ASCs) and had tunable biodegradation rates. Finally, we present a strategy for increasing the DFEA content without affecting the mechanical properties. Our results may be implemented in the future development of hydrogel implants, whose fate and biodegradation rate can be monitored via 19 F MRI.

Topics & Concepts

Self-healing hydrogelsGelatinTissue engineeringBiodegradationMethacrylateSwellingBiomedical engineeringChemistryIn vivoMethacrylamideMaterials scienceAcrylamideChemical engineeringMonomerPolymer chemistryPolymerOrganic chemistryComposite materialEngineeringBiotechnologyMedicineBiologyHydrogels: synthesis, properties, applicationsAdvanced MRI Techniques and ApplicationsLanthanide and Transition Metal Complexes
Cell-Interactive Gelatin-Based <sup>19</sup>F MRI Tracers: An <i>In Vitro</i> Proof-of-Concept Study | Litcius