Biodegradation and thermal stability of bacterial cellulose as biomaterial: The relevance in biomedical applications

Biodegradation and thermal stability of bacterial cellulose as biomaterial: The relevance in biomedical applications

Biodegradable polymeric biomaterial plays a vital role in therapeutic medicine and in the various discipline of biomedical science involving biomaterials. Bacterial cellulose (BC) have attracted much interest in industrial and academic research over the years as a biodegradable biopolymer. In this p...

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Bibliographic Details
Published in:Polymer degradation and stability Vol. 179; p. 109232
Main Authors: Torgbo, Selorm, Sukyai, Prakit
Format: Journal Article
Language:English
Published: London Elsevier Ltd 01-09-2020
Elsevier BV
Subjects:
Bacterial cellulose
Biodegradability
Biodegradable materials
Biodegradation
Biomedical application
Biomedical materials
Biopolymers
Biostability
Cellulose
Cornea
Dental materials
Drug delivery systems
High temperature
Nanoparticles
Oxidation
Physiological effects
Polymeric biomaterial
Prostheses
Regeneration
Soft tissues
Thermal stability
Tissue engineering
Wound healing
Biodegradation
Biostability
Polymeric biomaterial
Bacterial cellulose
Thermal stability
Biomedical application
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Summary:Biodegradable polymeric biomaterial plays a vital role in therapeutic medicine and in the various discipline of biomedical science involving biomaterials. Bacterial cellulose (BC) have attracted much interest in industrial and academic research over the years as a biodegradable biopolymer. In this perspective, we looked at biodegradation of polymeric biomaterials in general, and specifically the factors and mechanisms of BC biodegradation as biomaterial. Also attempt to explore the most recent research advancement in the application of BC in terms of its biodegradability and thermal stability in biomedical science. The medical applications of BC as a biomaterial span a wide range of topics including; hard tissue engineering (bone and dental), wound dressing and skin regeneration, artificial dura mater membrane, facial nerve regeneration, prosthetic hernioplasty, soft tissue reconstruction, diagnosis of cancer, drug delivery, tissue-engineered cornea stroma, neuroendovascular application, and so on. The variation in its application implies material with different properties in terms of degradation and stability. We have identified crystallinity, molecular weight, hydrophilicity and modification strategy as the four main factors which could affect the biodegradation of BC-based material in physiological environment. In terms of in vivo degradation of BC, four main proposed mechanisms were identified, these includes; hydrolysis, enzymatic, oxidation and physical mechanism, which occurs in a tandem. Furthermore, the thermal stability of BC and its relevance in biomedical application have been explained. It was shown in previous studies that, pure BC can thermally degrade as low as 190 °C, and it could be enhanced to a temperature of 580 °C by functionalizing with an inorganic nanoparticle. As a biomaterial, it could be made degradable or stable for an intended application by playing with the key factors, and made thermal stable at high temperature by adding reinforcement agents. The BC related biomaterial still stand to be novel and an excellent development in biomedical science in the new era of green chemistry and biotechnology. •Crystallinity, molecular weight, hydrophilicity and modification strategy affect biodegradation of BC-based biomaterial.•In vivo degradation of BC- based biomaterial occurs through hydrolysis, enzymatic, oxidation and physical mechanisms.•A native BC can thermally degrade at 190 °C, and could be enhanced to a temperature of 580 °C.•BC-based biomaterial could be made degradable or stable for an intended application through modification with an inorganic nanoparticle.
ISSN:0141-3910
1873-2321
DOI:10.1016/j.polymdegradstab.2020.109232