Antibiotic resistance is one of the major issues in the medical field and a potential threat to human health.However,newly emerging antimicrobial compounds failed to combat antimicrobial resistance developed by bacter...Antibiotic resistance is one of the major issues in the medical field and a potential threat to human health.However,newly emerging antimicrobial compounds failed to combat antimicrobial resistance developed by bacterial pathogens.Recently,a bismuth-based complex has been developed to eradicate antimicrobial-resistant microorganism infections.The complex is known as organobismuth(III)phosphinate,which is said to be a potential broad-spectrum antimicrobial agent.This complex has been incorporated into the nanocellulose suspension to fabricate a biomedical composite for various applications.The composite can be fabricated by two methods namely vacuum filtration and spray coating.In this paper,the surface and topography of the composite are investigated and discussed in terms of SEM micrographs and their antimicrobial potential.This review focuses on the organo-bismuth nanocellulose composite and its biomedical application in the future.展开更多
Antimicrobial-treated textiles should exhibit efficacy against a broad spectrum of bacterial and fungal species,all while maintaining user safety with a non-toxic profile.Natural antimicrobial compounds play a vital r...Antimicrobial-treated textiles should exhibit efficacy against a broad spectrum of bacterial and fungal species,all while maintaining user safety with a non-toxic profile.Natural antimicrobial compounds play a vital role in textile finishing processes.The proliferation of synthetic antimicrobial agents introduces environmental and consumer safety concerns.Given these potential hazards associated with synthetic agents,the utilization of natural antimicrobial agents is gaining traction,as they tend to have fewer adverse effects on users and are more environmentally sustainable.Numerous natural antimicrobial compounds,sourced from plants such as neem,basil,turmeric,aloe vera,and clove oil,have been developed,showcasing inherent antimicrobial properties.This review article highlights the importance of incorporating bioactive components in the creation of antibacterial textile fabrics.展开更多
文摘Antibiotic resistance is one of the major issues in the medical field and a potential threat to human health.However,newly emerging antimicrobial compounds failed to combat antimicrobial resistance developed by bacterial pathogens.Recently,a bismuth-based complex has been developed to eradicate antimicrobial-resistant microorganism infections.The complex is known as organobismuth(III)phosphinate,which is said to be a potential broad-spectrum antimicrobial agent.This complex has been incorporated into the nanocellulose suspension to fabricate a biomedical composite for various applications.The composite can be fabricated by two methods namely vacuum filtration and spray coating.In this paper,the surface and topography of the composite are investigated and discussed in terms of SEM micrographs and their antimicrobial potential.This review focuses on the organo-bismuth nanocellulose composite and its biomedical application in the future.
文摘Antimicrobial-treated textiles should exhibit efficacy against a broad spectrum of bacterial and fungal species,all while maintaining user safety with a non-toxic profile.Natural antimicrobial compounds play a vital role in textile finishing processes.The proliferation of synthetic antimicrobial agents introduces environmental and consumer safety concerns.Given these potential hazards associated with synthetic agents,the utilization of natural antimicrobial agents is gaining traction,as they tend to have fewer adverse effects on users and are more environmentally sustainable.Numerous natural antimicrobial compounds,sourced from plants such as neem,basil,turmeric,aloe vera,and clove oil,have been developed,showcasing inherent antimicrobial properties.This review article highlights the importance of incorporating bioactive components in the creation of antibacterial textile fabrics.
