Healthcare is considered one of the most significant domains of nano-biotechnology. The use of metal nanostructures paves the way for numerous applications in this field such as antibacterial paints, antibacterial patches or even antibacterial films. The possibility to synthesize various kind of metallic nanoparticles and the ever-increasing ability to control their size as well as structure to improve antibacterial activity has played an important role. Despite their advantages, leakage of heavy metals represents the major problem responsible of their toxicity[1]. Coating with antimicrobial peptides represents an emerging strategy to reduce toxicity and enhance antibacterial activity.[2] The presence of nanoparticles and released metal ions in the aquatic environment is considered to be amongst the greatest environmental concerns because of their potential harmful effects on both aquatic organisms and humans via direct or indirect exposure. Among freshwater aquatic organisms, the crustacean Daphnia magna is often the best choice for toxicity evaluations thanks to its high sensitivity, short life cycle, easiness of manipulation in laboratory. In addition, it is widely present in diverse freshwater lakes and ponds, and plays a key role in transfer of energy and nutrients to upper food webs, representing also an important ecological sentinel species. In this study we evaluated the ecotoxicity of quantum dots and Au nanoparticles coated with indolicidin, one of most common antibacterial peptide.
Metallic nanoparticles: antibacterial activity and ecotoxicity / Falanga, A.; Mercurio, A.; Lombardi, L.; Leone, M.; Galdiero, E.; Morelli, G.; Galdiero, Stefania. - (2018). (Intervento presentato al convegno 16th Naples Workshop on Bioactive Peptides tenutosi a Naples nel June 7th – 9th, 2018).
Metallic nanoparticles: antibacterial activity and ecotoxicity
A. Falanga;L. Lombardi;E. Galdiero;G. Morelli;S. Galdiero.
2018
Abstract
Healthcare is considered one of the most significant domains of nano-biotechnology. The use of metal nanostructures paves the way for numerous applications in this field such as antibacterial paints, antibacterial patches or even antibacterial films. The possibility to synthesize various kind of metallic nanoparticles and the ever-increasing ability to control their size as well as structure to improve antibacterial activity has played an important role. Despite their advantages, leakage of heavy metals represents the major problem responsible of their toxicity[1]. Coating with antimicrobial peptides represents an emerging strategy to reduce toxicity and enhance antibacterial activity.[2] The presence of nanoparticles and released metal ions in the aquatic environment is considered to be amongst the greatest environmental concerns because of their potential harmful effects on both aquatic organisms and humans via direct or indirect exposure. Among freshwater aquatic organisms, the crustacean Daphnia magna is often the best choice for toxicity evaluations thanks to its high sensitivity, short life cycle, easiness of manipulation in laboratory. In addition, it is widely present in diverse freshwater lakes and ponds, and plays a key role in transfer of energy and nutrients to upper food webs, representing also an important ecological sentinel species. In this study we evaluated the ecotoxicity of quantum dots and Au nanoparticles coated with indolicidin, one of most common antibacterial peptide.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
