Composite Bioprinted Hydrogels Containing Porous Polymer Microparticles Provide Tailorable Mechanical Properties for 3D Cell Culture

Mclean, Bonnie; Ratcliffe, Julian; Parker, Bradyn J.; Field, Emily H.; Hughes, Sarah J.; Cutter, Sean W.; Iseppi, Kyle J.; Cameron, Neil R.; Binger, Katrina J.; Reynolds, Nicholas P.

doi:10.1021/acs.biomac.3c01013

Cited by 2 publications

(1 citation statement)

References 38 publications

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“…The mechanical properties of cellulose hydrogels are critical in a variety of applications [ 100 , 101 , 102 ], particularly in biomedical [ 103 ] and engineering [ 69 ] applications where materials must exhibit specific strengths and elasticity. Mechanical properties are evaluated using methods such as compression [ 104 ], tension, and shear characterization.…”

Section: Performance Evaluation Of Cellulose Hydrogelsmentioning

confidence: 99%

Exploring Applications and Preparation Techniques for Cellulose Hydrogels: A Comprehensive Review

Tang,

Fang,

Lee

2024

Gels

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Cellulose hydrogels, formed either through physical or chemical cross-linking into a three-dimensional network from cellulose or its derivatives, are renowned for their exceptional water absorption capacities and biocompatibility. Rising demands for sustainable materials have spurred interest in cellulose hydrogels, attributed to their abundant supply, biodegradability, and non-toxic nature. These properties highlight their extensive potential across various sectors including biomedicine, the food industry, and environmental protection. Cellulose hydrogels are particularly advantageous in applications such as drug delivery, wound dressing, and water treatment. Recent large-scale studies have advanced our understanding of cellulose preparation and its applications. This review delves into the fundamental concepts, preparation techniques, and current applications of cellulose hydrogels in diverse fields. It also discusses the latest advances in nano-lignin-based hydrogels, providing a comprehensive overview of this promising material and offering insights and guidance for future research and development.

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Section: Performance Evaluation Of Cellulose Hydrogelsmentioning

confidence: 99%

Exploring Applications and Preparation Techniques for Cellulose Hydrogels: A Comprehensive Review

Tang,

Fang,

Lee

2024

Gels

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Self-healing, biocompatible bioinks from self-assembled peptide and alginate hybrid hydrogels

Field,

Ratcliffe,

Johnson

et al. 2024

Preprint

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1.AbstractThere is a pressing need for new biomaterials that are printable, stiff and highly biocompatible. This is primarily due to the inverse relationship between the printability and viscosity of hydrogels. Cell-laden, printable, rigid biomaterials are needed for replicating stiffer tissues such as cartilage in regenerative medicine, modelling the fibrosis of tissue and cancer microenvironments, as well as in non-cellular research fields such as biosensors. Here, we have designed a hybrid material compromised of self-assembled Fmoc-FF peptide assemblies dispersed throughout a sodium alginate matrix. The resultant hybrid bioink has a stiffness up to 10 times greater than sodium alginate alone but remains highly printable, even when laden with high concentrations of cells. In addition, the thixotropic self-assembled peptide assemblies gave the hybrid bioinks highly desirable self-healing capabilities. The choice of solvent used to initially dissolve the peptides made significant differences to both the physical properties and the biocompatibility of the bioinks, with the best performing able to support the growth of encapsulated macrophages over 5 days. Our developed hybrid materials allow the bioprinting of materials previously considered too stiff to extrude without causing shear induced cytotoxicity with applications in tissue engineering and biosensing.

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Composite Bioprinted Hydrogels Containing Porous Polymer Microparticles Provide Tailorable Mechanical Properties for 3D Cell Culture

Cited by 2 publications

References 38 publications

Exploring Applications and Preparation Techniques for Cellulose Hydrogels: A Comprehensive Review

Exploring Applications and Preparation Techniques for Cellulose Hydrogels: A Comprehensive Review

Self-healing, biocompatible bioinks from self-assembled peptide and alginate hybrid hydrogels

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