Study of Mechanisms Used by Algae to Decrease The Silver Toxicity in Aquatic Environment

In the study SEM, EDS, TEM and UV-vis analysis were used to investigate the biosorption, bioaccumulation and bioprecipitation/bioreduction of silver by freshwater green alga Parachlorella kessleri and to shed light on the reasons of biological silver nanoparticleproduction. When dead biomass of P. kessleri was used for silver removal, majority of silver (75%) was removed within2 min. Biosorption was probably the main mechanisms responsible for Ag+ ions removal from aqueous solutions. However, whenbehaviour of living biomass in the presence of silver ions was studied, the decrease of silver concentration was slower (68% within24 hours) with subsequent increase of silver concentration in the solution and extracellular formation of silver nanoparticles. Theformed AgNPs exhibited a lower toxicity against tested organisms. Algal cells probably used the formation of nanoparticles combinedwith rapid biosorption as detoxification mechanisms against silver toxicity. Bioaccumulation inside the cells played only aminor role in the detoxification process.

N-Acetyl Cysteine Abrogates Silver-Induced Reactive Oxygen Species in Human Cells Without Altering Silver-based Antimicrobial Activity

Silver-based antimicrobials are widely used topically to treat infections associated with multi-drug resistant (MDR) pathogens. Expanding this topical use to aerosols to treat lung infections requires understanding and preventing silver toxicity in the respiratory tract. A key mechanism resulting in silver-induced toxicity is the production of reactive oxygen species (ROS). In this study, we have verified ROS generation in silver-treated bronchial epithelial (16HBE) cells prompting evaluation of three antioxidants, N-acetyl cysteine (NAC), ascorbic acid, and melatonin, to identify potential prophylactic agents. Among them, NAC was the only candidate that abrogated the ROS generation in response to silver exposure resulting in the rescue of these cells from silver-associated toxicity. Further, this protective effect directly translated to restoration of metabolic activity, as demonstrated by the normal levels of citric acid cycle metabolites in NAC-pretreated silver-exposed cells. As a result of the normalized citric acid cycle, cells pre-incubated with NAC demonstrated significantly higher levels of adenosine triphosphate (ATP) levels compared with NAC-free controls. Moreover, we found that this prodigious capacity of NAC to rescue silver-exposed cells was due not only to its antioxidant activity, but also to its ability to directly bind silver. Despite binding to silver, NAC did not alter the antimicrobial activity of silver.ImportanceAlthough silver is a potent, broad-spectrum antibiotic, silver-induced toxicity, primarily due to generation of ROS, remains a concern limiting its use beyond treatment of wounds. NAC has been widely used as an antioxidant to rescue eukaryotic cells from metal-associated toxicity. Thus, we have evaluated the capacity of NAC to abrogate silver toxicity in a human bronchial epithelial cell line (16HBE) as a step towards expanding the use of silver-based antimicrobials to treat lung infections. We found that NAC pre-incubation resurrects a healthy metabolic state in bronchial epithelial cells exposed to silver ions via a combination of its antioxidant and metal-binding properties. Finally, this ability of NAC to rescue silver-exposed eukaryotic cells does not alter the antimicrobial activity of silver. Thus, a silver-NAC combination holds tremendous potential as a future, non-toxic antimicrobial agent.

Reduction of silver nanoparticle toxicity affecting ammonia oxidation using cell entrapment technique

Occurrence of silver nanoparticles (AgNPs) in wastewater treatment systems could impact the ammonia oxidation (AO). This study investigated the reduction of AgNPs and dissociated silver ion (Ag+) toxicity on nitrifying sludge using cell entrapment technique. Three entrapment materials, including barium alginate (BA), polyvinyl alcohol (PVA), and a mixture of polyvinyl alcohol and barium alginate (PVA-BA), were applied. The BA beads provided the highest reduction of silver toxicity (up to 90%) and durability. Live/dead assays showed fatality of entrapped cells after exposure to AgNPs and Ag+. The maximum AO rate of the BA-entrapped cells was 5.6 mg-N/g-MLSS/h. The AO kinetics under the presence of silver followed an uncompetitive inhibition kinetic model. The experiments with AgNPs and Ag+ gave the apparent maximum AO rates of 4.2 and 4.8 mg-N/g-MLSS/h, respectively. The apparent half-saturation constants of the BA-entrapped cells under the presence of silver were 10.5 to 13.4 mg/L. Scanning electron microscopic observation coupled with energy-dispersive X-ray spectroscopy indicated no silver inside the beads. This elucidates that the silver toxicity can be reduced by preventing silver penetration through the porous material, leading to less microbial cell damage. This study revealed the potential of the entrapment technology for mitigating the effect of silver species on nitrification.