Innovative Approach to Accelerate Wound Healing: Synthesis and Validation of Enzymatically Cross-Linked COL-rGO Biocomposite Hydrogels

Innovative Approach to Accelerate Wound Healing: Synthesis and Validation of Enzymatically Cross-Linked COL-rGO Biocomposite Hydrogels

In this study, an innovative conductive hybrid biomaterial was synthetized using collagen (COL) and reduced graphene oxide (rGO) in order for it to be used as a wound dressing. The hydrogels were plasticized with glycerol and enzymatically cross-linked with horseradish peroxidase (HRP). A successful...

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Bibliographic Details
Published in:Gels Vol. 10; no. 7; p. 448
Main Authors: González, Luisbel, Espinoza, Víctor, Tapia, Mauricio, Aedo, Valentina, Ruiz, Isleidy, Meléndrez, Manuel, Aguayo, Claudio, Atanase, Leonard I, Fernández, Katherina
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 01-07-2024
Subjects:
Biodegradation
Biological products
Biomedical materials
Carbon
Charge density
Collagen
Composite materials
Crosslinking
Dopamine
Electric properties
enzymatic cross-linking
Enzymes
Glycerin
Glycerol
Graphene
Hydrogels
Hydrogen bonds
Morphology
Oxidation
Peroxidase
Polymerization
rGO
Scanning electron microscopy
Spectrum analysis
Stability
Vibration
Wound healing
collagen
enzymatic cross-linking
wound healing
rGO
dopamine
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Summary:In this study, an innovative conductive hybrid biomaterial was synthetized using collagen (COL) and reduced graphene oxide (rGO) in order for it to be used as a wound dressing. The hydrogels were plasticized with glycerol and enzymatically cross-linked with horseradish peroxidase (HRP). A successful interaction among the components was demonstrated by FTIR, XRD, and XPS. It was demonstrated that increasing the rGO concentration led to higher conductivity and negative charge density values. Moreover, rGO also improved the stability of hydrogels, which was expressed by a reduction in the biodegradation rate. Furthermore, the hydrogel's stability against the enzymatic action of collagenase type I was also strengthened by both the enzymatic cross-linking and the polymerization of dopamine. However, their absorption capacity, reaching values of 215 g/g, indicates the high potential of the hydrogels to absorb fluids. The rise of these properties positively influenced the wound closure process, achieving an 84.5% in vitro closure rate after 48 h. These findings clearly demonstrate that these original composite biomaterials can be a viable choice for wound healing purposes.
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ISSN:2310-2861
2310-2861
DOI:10.3390/gels10070448