Simultaneous Orthogonal Dual-Click Approach to Tough, In Situ-Forming Hydrogels for Cell Encapsulation

Vinh X Truong; Matthew P Ablett; Stephen M Richardson; Judith Hoyland; Andrew P Dove

doi:10.1021/ja511681s

Simultaneous Orthogonal Dual-Click Approach to Tough, In Situ-Forming Hydrogels for Cell Encapsulation

Vinh X Truong, Matthew P Ablett, Stephen M Richardson, Judith Hoyland, Andrew P Dove

Research output: Contribution to journal › Article › peer-review

Abstract

The use of tough hydrogels as biomaterials is limited as a consequence of time-consuming fabrication techniques, toxic starting materials, and large strain hysteresis under deformation. Herein, we report the simultaneous application of nucleophilic thiol-yne and inverse electron-demand Diels-Alder additions to independently create two interpenetrating networks in a simple one-step procedure. The resultant hydrogels display compressive stresses of 14-15 MPa at 98% compression without fracture or hysteresis upon repeated load. The hydrogel networks can be spatially and temporally postfunctionalized via radical thiylation and/or inverse electron-demand Diels-Alder addition to residual functional groups within the network. Furthermore, gelation occurs rapidly under physiological conditions, enabling encapsulation of human cells.

Original language	English
Pages (from-to)	1618-1622
Number of pages	4
Journal	American Chemical Society. Journal
Volume	137
Issue number	4
DOIs	https://doi.org/10.1021/ja511681s
Publication status	Published - 15 Jan 2015

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abstract = "The use of tough hydrogels as biomaterials is limited as a consequence of time-consuming fabrication techniques, toxic starting materials, and large strain hysteresis under deformation. Herein, we report the simultaneous application of nucleophilic thiol-yne and inverse electron-demand Diels-Alder additions to independently create two interpenetrating networks in a simple one-step procedure. The resultant hydrogels display compressive stresses of 14-15 MPa at 98% compression without fracture or hysteresis upon repeated load. The hydrogel networks can be spatially and temporally postfunctionalized via radical thiylation and/or inverse electron-demand Diels-Alder addition to residual functional groups within the network. Furthermore, gelation occurs rapidly under physiological conditions, enabling encapsulation of human cells.",

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AU - Truong, Vinh X

AU - Ablett, Matthew P

AU - Richardson, Stephen M

AU - Hoyland, Judith

AU - Dove, Andrew P

PY - 2015/1/15

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N2 - The use of tough hydrogels as biomaterials is limited as a consequence of time-consuming fabrication techniques, toxic starting materials, and large strain hysteresis under deformation. Herein, we report the simultaneous application of nucleophilic thiol-yne and inverse electron-demand Diels-Alder additions to independently create two interpenetrating networks in a simple one-step procedure. The resultant hydrogels display compressive stresses of 14-15 MPa at 98% compression without fracture or hysteresis upon repeated load. The hydrogel networks can be spatially and temporally postfunctionalized via radical thiylation and/or inverse electron-demand Diels-Alder addition to residual functional groups within the network. Furthermore, gelation occurs rapidly under physiological conditions, enabling encapsulation of human cells.

AB - The use of tough hydrogels as biomaterials is limited as a consequence of time-consuming fabrication techniques, toxic starting materials, and large strain hysteresis under deformation. Herein, we report the simultaneous application of nucleophilic thiol-yne and inverse electron-demand Diels-Alder additions to independently create two interpenetrating networks in a simple one-step procedure. The resultant hydrogels display compressive stresses of 14-15 MPa at 98% compression without fracture or hysteresis upon repeated load. The hydrogel networks can be spatially and temporally postfunctionalized via radical thiylation and/or inverse electron-demand Diels-Alder addition to residual functional groups within the network. Furthermore, gelation occurs rapidly under physiological conditions, enabling encapsulation of human cells.

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JO - American Chemical Society. Journal

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ER -

Simultaneous Orthogonal Dual-Click Approach to Tough, In Situ-Forming Hydrogels for Cell Encapsulation

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