Swelling behaviours and mechanical properties of silk fibroin–polyurethane composite hydrogels

Swelling behaviours and mechanical properties of silk fibroin–polyurethane composite hydrogels

Silk fibroin–polyurethane (SF–PU) hydrogels combining advantages of the natural/synthetic materials were fabricated. FTIR was applied to characterize the structure of hydrogels. It was found that cross-linking network formed through chemical reactions between NCO groups on PU chain and NH2, OH group...

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Bibliographic Details
Published in:Composites science and technology Vol. 84; pp. 15 - 22
Main Authors: Huang, Yiping, Zhang, Baoping, Xu, Gewen, Hao, Wentao
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 29-07-2013
Elsevier
Subjects:
A. Polymer–matrix composites
Applied sciences
B. Impact behaviour
B. Thermal properties
C. Elastic properties
Chain reactions
Chains
Crosslinking
Diffusion
Exact sciences and technology
Hydrogels
Natural polymers
Organic polymers
Physicochemistry of polymers
Plutonium
Properties and characterization
Proteins
Silk
Solution and gel properties
Swelling
Swelling behaviours
Swelling behaviours
B. Impact behaviour
B. Thermal properties
C. Elastic properties
A. Polymer–matrix composites
Elastic modulus
Swelling
Property composition relationship
Temperature effect
Mechanical properties
Crosslinking
Compressive strength
Experimental study
Protein
Colloidal gel
Thermal properties
Silk
Ionic strength
Morphology
A. Polymer―matrix composites
Fibroin
Hydrogel
Etherurethane polymer
Hydrogen bond
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Summary:Silk fibroin–polyurethane (SF–PU) hydrogels combining advantages of the natural/synthetic materials were fabricated. FTIR was applied to characterize the structure of hydrogels. It was found that cross-linking network formed through chemical reactions between NCO groups on PU chain and NH2, OH groups on SF chains, in addition to the hydrogen bonding interactions. SEM was taken to observe the morphology of hydrogels, which exhibited a porous structure. Hydrogels demonstrated impressive swelling–deswelling behaviours and good sensitivities to temperature, ionic strength and pH. The swelling ratio of hydrogel could be as high as 4.37 and it decreased with the increase of SF contents. Due to that the diffusion exponent (n) was about 0.45, the initial swelling stage was thought to be controlled by the Fickian diffusion. For the whole swelling process, experimental results well fitted into the Schott second-order kinetic equation. Mechanical tests showed that the elastic modulus of hydrogels were about 0.558MPa. Properties of hydrogels could be finely controlled so as to fulfill these potential biomedical applications, such as in Nucleus Pulposus Replacement or controlled drug release.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0266-3538
1879-1050
DOI:10.1016/j.compscitech.2013.05.007