Self-adaptive hydrogels to mineralizationElectronic supplementary information (ESI) available: Microscopy images of the mineralized gels and calculated crystal density distributions, Raman and IR spectroscopy, complementary TGA measurements and analysis, dynamic light scattering measurements, and elastic modulus 2D-maps. See DOI: 10.1039/c7sm01058c
Mineralized biological tissues, whose behavior can range from rigid to compliant, are an essential component of vertebrates and invertebrates. Little is known about how the behavior of mineralized yet compliant tissues can be tuned by the degree of mineralization. In this work, a synthesis route to...
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| creator | Shoaib, Tooba Carmichael, Ariel Corman, R. E Shen, Yun Nguyen, Thanh H Ewoldt, Randy H Espinosa-Marzal, Rosa M |
| description | Mineralized biological tissues, whose behavior can range from rigid to compliant, are an essential component of vertebrates and invertebrates. Little is known about how the behavior of mineralized yet compliant tissues can be tuned by the degree of mineralization. In this work, a synthesis route to tune the structure and mechanical response of agarose gels
via
ionic crosslinking and mineralization has been developed. A combination of experimental techniques demonstrates that crosslinking
via
cooperative hydrogen bonding in agarose gels is disturbed by calcium ions, but they promote ionic crosslinking that modifies the agarose network. Further, it is shown that the rearrangement of the hydrogel network helps to accommodate precipitated minerals into the network -in other words, the hydrogel self-adapts to the precipitated mineral- while maintaining the viscoelastic behavior of the hydrogel, despite the reinforcement caused by mineralization. This work not only provides a synthesis route to design biologically inspired soft composites, but also helps to understand the change of properties that biomineralization can cause to biological tissues, organisms and biofilms.
The hydrogel rearranges its network in order to accommodate the precipitated minerals and maintain its viscoelasticity. |
| doi_str_mv | 10.1039/c7sm01058c |
| format | Article |
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via
ionic crosslinking and mineralization has been developed. A combination of experimental techniques demonstrates that crosslinking
via
cooperative hydrogen bonding in agarose gels is disturbed by calcium ions, but they promote ionic crosslinking that modifies the agarose network. Further, it is shown that the rearrangement of the hydrogel network helps to accommodate precipitated minerals into the network -in other words, the hydrogel self-adapts to the precipitated mineral- while maintaining the viscoelastic behavior of the hydrogel, despite the reinforcement caused by mineralization. This work not only provides a synthesis route to design biologically inspired soft composites, but also helps to understand the change of properties that biomineralization can cause to biological tissues, organisms and biofilms.
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via
ionic crosslinking and mineralization has been developed. A combination of experimental techniques demonstrates that crosslinking
via
cooperative hydrogen bonding in agarose gels is disturbed by calcium ions, but they promote ionic crosslinking that modifies the agarose network. Further, it is shown that the rearrangement of the hydrogel network helps to accommodate precipitated minerals into the network -in other words, the hydrogel self-adapts to the precipitated mineral- while maintaining the viscoelastic behavior of the hydrogel, despite the reinforcement caused by mineralization. This work not only provides a synthesis route to design biologically inspired soft composites, but also helps to understand the change of properties that biomineralization can cause to biological tissues, organisms and biofilms.
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via
ionic crosslinking and mineralization has been developed. A combination of experimental techniques demonstrates that crosslinking
via
cooperative hydrogen bonding in agarose gels is disturbed by calcium ions, but they promote ionic crosslinking that modifies the agarose network. Further, it is shown that the rearrangement of the hydrogel network helps to accommodate precipitated minerals into the network -in other words, the hydrogel self-adapts to the precipitated mineral- while maintaining the viscoelastic behavior of the hydrogel, despite the reinforcement caused by mineralization. This work not only provides a synthesis route to design biologically inspired soft composites, but also helps to understand the change of properties that biomineralization can cause to biological tissues, organisms and biofilms.
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| title | Self-adaptive hydrogels to mineralizationElectronic supplementary information (ESI) available: Microscopy images of the mineralized gels and calculated crystal density distributions, Raman and IR spectroscopy, complementary TGA measurements and analysis, dynamic light scattering measurements, and elastic modulus 2D-maps. See DOI: 10.1039/c7sm01058c |
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