Highly deformable and strongly magnetic semi-interpenetrating hydrogels based on alginate or cellulose

The effective implementation of many of the applications of magnetic hydrogels requires the development of innovative systems capable of withstanding a substantial load of magnetic particles to ensure exceptional responsiveness, without compromising their reliability and stability. To address this c...

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Veröffentlicht in:	International journal of biological macromolecules 2024-03, Vol.260 (Pt 1), p.129368-129368, Article 129368
Hauptverfasser:	Leon-Cecilla, Alberto, Gila-Vilchez, Cristina, Vazquez-Perez, Francisco J., Capitan-Vallvey, Luis F., Martos, Vanesa, Fernandez-Ramos, María D., Álvarez de Cienfuegos, Luis, Medina-Castillo, Antonio L., Lopez-Lopez, Modesto T.
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Sprache:	eng
Schlagworte:	Carbohydrate biopolymers Magnetic hydrogels Semi-interpenetrating polymer network
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container_end_page	129368
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container_title	International journal of biological macromolecules
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creator	Leon-Cecilla, Alberto Gila-Vilchez, Cristina Vazquez-Perez, Francisco J. Capitan-Vallvey, Luis F. Martos, Vanesa Fernandez-Ramos, María D. Álvarez de Cienfuegos, Luis Medina-Castillo, Antonio L. Lopez-Lopez, Modesto T.
description	The effective implementation of many of the applications of magnetic hydrogels requires the development of innovative systems capable of withstanding a substantial load of magnetic particles to ensure exceptional responsiveness, without compromising their reliability and stability. To address this challenge, double-network hydrogels have emerged as a promising foundation, thanks to their extraordinary mechanical deformability and toughness. Here, we report a semi-interpenetrating polymer networks (SIPNs) approach to create diverse magnetic SIPNs hydrogels based on alginate or cellulose, exhibiting remarkable deformability under certain stresses. Achieving strong responsiveness to magnetic fields is a key objective, and this characteristic is realized by the incorporation of highly magnetic iron microparticles at moderately large concentrations into the polymer network. Remarkably, the SIPNs hydrogels developed in this research accommodate high loadings of magnetic particles without significantly compromising their physical properties. This feature is essential for their use in applications that demand robust responsiveness to applied magnetic fields and overall stability, such as a hydrogel luminescent oxygen sensor controlled by magnetic fields that we designed and tested as proof-of-concept. These findings underscore the potential and versatility of magnetic SIPNs hydrogels based on carbohydrate biopolymers as fundamental components in driving the progress of advanced hydrogels for diverse practical implementations. [Display omitted]
doi_str_mv	10.1016/j.ijbiomac.2024.129368
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To address this challenge, double-network hydrogels have emerged as a promising foundation, thanks to their extraordinary mechanical deformability and toughness. Here, we report a semi-interpenetrating polymer networks (SIPNs) approach to create diverse magnetic SIPNs hydrogels based on alginate or cellulose, exhibiting remarkable deformability under certain stresses. Achieving strong responsiveness to magnetic fields is a key objective, and this characteristic is realized by the incorporation of highly magnetic iron microparticles at moderately large concentrations into the polymer network. Remarkably, the SIPNs hydrogels developed in this research accommodate high loadings of magnetic particles without significantly compromising their physical properties. This feature is essential for their use in applications that demand robust responsiveness to applied magnetic fields and overall stability, such as a hydrogel luminescent oxygen sensor controlled by magnetic fields that we designed and tested as proof-of-concept. These findings underscore the potential and versatility of magnetic SIPNs hydrogels based on carbohydrate biopolymers as fundamental components in driving the progress of advanced hydrogels for diverse practical implementations. 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This feature is essential for their use in applications that demand robust responsiveness to applied magnetic fields and overall stability, such as a hydrogel luminescent oxygen sensor controlled by magnetic fields that we designed and tested as proof-of-concept. These findings underscore the potential and versatility of magnetic SIPNs hydrogels based on carbohydrate biopolymers as fundamental components in driving the progress of advanced hydrogels for diverse practical implementations. 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title	Highly deformable and strongly magnetic semi-interpenetrating hydrogels based on alginate or cellulose
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