| Literature DB >> 30970696 |
Vu Khac Hoang Bui1, Duckshin Park2, Young-Chul Lee3.
Abstract
Chitosan is a natural polymer that has been widely utilized for many purposes in the food, textile, agriculture, water treatment, cosmetic and pharmaceutical industries. Based on its characteristics, including biodegradability, non-toxicity and antimicrobial properties, it has been employed effectively in wound healing applications. Importantly, however, it is necessary to improve chitosan's capacities by combination with zinc oxide (ZnO), titanium dioxide (TiO₂) and silver (Ag) nanoparticles (NPs). In this review of many of the latest research papers, we take a closer look at the antibacterial effectiveness of chitosan combined with ZnO, TiO₂ and Ag NPs and also evaluate the specific wound healing application potentials.Entities:
Keywords: antimicrobial ability; chitosan; metal (oxide) nanoparticles; nanocomposites; wound healing
Year: 2017 PMID: 30970696 PMCID: PMC6432267 DOI: 10.3390/polym9010021
Source DB: PubMed Journal: Polymers (Basel) ISSN: 2073-4360 Impact factor: 4.329
Figure 1Structure of chitosan.
Figure 2Deacetylation of chitin to chitosan.
Figure 3Chemical synthesis of Ag NPs. Reproduced with permission from Dovepress, 2014 [105].
Figure 4Biological synthesis of Ag NPs. Reproduced with permission from Dovepress, 2014 [105].
Summary of chitosan combined with ZnO, TiO2 and Ag NPs for antimicrobial wound healing applications.
| Authors | Materials | Products | Remarkable Results |
|---|---|---|---|
| Kumar et al. (2012) [ | Chitosan + ZnO NPs | Bandages | High antimicrobial activity against Good swelling, blood clotting ability. No cytotoxicity on normal human dermal fibroblast (nHDF) cells and fast wound healing process. |
| Vicentini et al. (2009) [ | Chitosan + ZnO NPs + poly(vinyl alcohol) + Tween 80 | Films | Compared to chitosan/PVA: chitosan/PVA/ZnO NPs have higher thermal stability; the reduction of tensile strength and elongation at break reduced; the degradation and swelling ratio increased; and they have stronger antimicrobial activity against |
| Samzadeh-Kermani and Miri (2014) [ | Chitosan + polyaniline + montmorillonite + ZnO NPs | Films | High antimicrobial activity against |
| Petkova et al. (2014) [ | Chitosan + ZnO NPs | Textiles | High antimicrobial activity against Chitosan + ZnO NPs showed 87% improvement in biocompatibility, and cell viability was steady decreased after 1 week. |
| Karahaliloglu et al. (2016) [ | Chitosan + ZnO NPs + silk sericin | Scaffolds | Higher antimicrobial activity against |
| Jayakumar et al. (2011) [ | Chitin/chitosan + TiO2 NPs | Scaffolds | The presence of TiO2 NPs increases thermal stability and decreases pore size and swelling degradation. No cytotoxicity on an array of MG-63, fibroblast cells (L929) and human mesenchymal stem cells (hMSCs). |
| Archana et al. (2013) [ | Chitosan + pectin + TiO2 NPs | Films | High antimicrobial activity against a wide spectrum of bacteria. The presence of TiO2 NPs increased tensile strength, induced blood coagulation, good hemostatic ability, no toxicity on L929 and NIH3T3 fibroblast cells and faster healing. |
| Woo et al. (2015) [ | Chitosan + TiO2 NPs | Bilayer composite | High antimicrobial activity, proper physiochemical, good biocompatibility and faster wound healing. |
| Hang et al. (2010) [ | Chitosan + poly(vinyl alcohol) + Ag NPs | Fiber mats | The presence of Ag NPs increased electrospinning activity, showed no beads and a uniform fiber structure. Higher antimicrobial against |
| Abdelgawad et al. (2012) [ | Chitosan + poly(vinyl alcohol) + Ag NPs | Fiber mats | The presence of Ag NPs improved electrospinnability, decreased the diameter of fibers and enhanced antimicrobial activity against |
| Ong et al. (2008) [ | Chitosan + polyphosphate + Ag NPs | Films | The presence of Ag NPs increased antimicrobial activity against |
| Lu et al. (2008) [ | Chitosan + Ag NPs | Films | The presence of Ag NPs increased the wound healing process; silver content in rat organs was lower than silver sulfadiazine. |
| Anisha et al. (2013) [ | Chitosan + poly(vinyl alcohol) + Ag NPs | Sponges | The presence of Ag NPs lowered the growth of a wide spectrum of harmful bacteria. Higher concentration of Ag NPs leads to the reduction of fibroblast cell viability. |
| Celebi et al. (2013) [ | Chitosan + poly(vinyl alcohol) + hydroxyapatite | Fiber mats | No growth of |
| Hebeish et al. (2014) [ | Chitosan + poly acrylonitrile + Ag NPs | Graft nanocomposite | High antimicrobial activity against |
| Thomas et al. (2012) [ | Chitosan + Ag NPs | Films | The presence of Ag NPs increased the antimicrobial ability against |
| Li et al. (2010) [ | Chitosan + Ag NPs + ZnO NPs | Films | Chitosan/Ag NPs/ZnO NPs have high antimicrobial activity against a wide range of spectrum bacteria and stronger than chitosan/Ag NPs and chitosan/ZnO NP films. |
| Levi-Polyachenko et al. (2016) [ | Chitosan + Ag NPs | Films | The number of peripheral blood mononuclear, keratinocyte and fibroblast cells was maintained or increased when contacted with chitosan/Ag NP films. The presence of Ag NPs induced cell proliferation, increased antimicrobial activity and generated mild hyperthermia for the delivery of small molecules. |