ascorbic-acid and silver-acetate

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 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 acetate exposure resulting in the rescue of these cells from silver-associated toxicity. Further, this protective effect directly translated to preservation of metabolic activity, as demonstrated by the normal levels of citric acid cycle metabolites in NAC-pretreated silver acetate-exposed cells. Because the citric acid cycle remained functional, silver-exposed cells pre-incubated with NAC demonstrated significantly higher levels of adenosine triphosphate levels compared with NAC-free controls. Moreover, we found that this prodigious capacity of NAC to rescue silver acetate-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 acetate.

Topics: Acetates; Acetylcysteine; Adenosine Triphosphate; Anti-Bacterial Agents; Ascorbic Acid; Cell Line; Free Radical Scavengers; Gas Chromatography-Mass Spectrometry; Glutathione; Humans; Melatonin; Microbial Sensitivity Tests; Reactive Oxygen Species; Silver; Silver Compounds; Superoxides

A systematic investigation of the effects of different DNA sequences on the morphologies of silver nanoparticles (AgNPs) grown from Ag nanocube seeds is reported. The presence of 10-mer oligo-A, -T, and -C directed AgNPs growth from cubic seeds into edge-truncated octahedra of different truncation extents and truncated tetrahedral AgNPs, while AgNPs in the presence of oligo-G remained cubic. The shape and morphological evolution of the nanoparticle growth for each system is investigated using SEM and TEM and correlated with UV-vis absorption kinetic studies. In addition, the roles of oligo-C and oligo-G secondary structures in modulating the morphologies of AgNPs are elucidated, and the morphological evolution for each condition of AgNPs growth is proposed. The shapes were found to be highly dependent on the binding affinity of each of the bases and the DNA secondary structures, favoring the stabilization of the Ag{111} facet. The AgNPs synthesized through this method have morphologies and optical properties that can be varied by using different DNA sequences, while the DNA molecules on these AgNPs are also stable against glutathione. The AgNP functionalization can be realized in a one-step synthesis while retaining the biorecognition ability of the DNA, which allows for programmable assembly.

Topics: Acetates; Ascorbic Acid; Base Sequence; DNA; Metal Nanoparticles; Nanotechnology; Nucleic Acid Hybridization; Optical Phenomena; Silver; Silver Compounds

The interaction between silver ion and DNA has been followed by submarine gel electrophoresis. When pBR322 plasmid DNA was allowed to interact with silver(I) acetate, it was found to contain Form I and Form II bands whose intensity remained unchanged as the concentration of Ag(+) was increased from 0 to 50 mM. However, the mobility of the bands decreased as the concentration of Ag(+) was increased, indicating the occurrence of increased covalent binding of the metal ion with DNA. When 1:1 mixtures of silver(I) acetate and ascorbate were allowed to interact with plasmid and genomic DNAs, it was found that the mixtures were much more damaging to plasmid as well as genomic DNAs than silver(I) acetate or ascorbate alone. In the case of pBR322 plasmid DNA, the mixture at 12.5 mM concentration was found to be more damaging than the mixtures at both higher and lower concentrations. The increased DNA damage is believed to be due to free radicals produced from the oxidation of ascorbate by molecular oxygen where the metal ion was playing a catalytic role.

Topics: Acetates; Animals; Ascorbic Acid; Cattle; DNA, Single-Stranded; Electrophoresis; Plasmids; Silver Compounds