Gliding Arc Discharge in the Potato Pathogen<i>Erwinia carotovora</i>subsp.<i>atroseptica</i>: Mechanism of Lethal Action and Effect on Membrane-Associated Molecules

Moreau, Morgane J. J.; Feuilloley, Marc; Véron, Wilfried; Meylheuc, Thierry; Chevalier, Sylvie; Brisset, Jean‐Louis; Orange, Nicole

doi:10.1128/aem.00662-07

Cited by 69 publications

(43 citation statements)

References 29 publications

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“…[20][21][22][23] It has been reported that water treated by various plasma discharges becomes acidic, [9][10][11][20][21][22][23][24] which leads to antimicrobial effects. [9][10][11][24][25][26][27] The important question is which acid is created in water treated by plasma. Oehmigen et al [28] suggested that the acid created in water is nitric/nitrous acid and the antimicrobial properties observed are the result of synergetic action between H 2 O 2 and nitric/nitrous acid.…”

mentioning

confidence: 99%

Retraction: Plasma Acid: Water Treated by Dielectric Barrier Discharge

Shainsky

Dobrynin

Ercan

et al. 2012

Plasma Processes & Polymers

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It is demonstrated that direct exposure of deionized water to a dielectric barrier discharge (DBD) plasma creates an acid (pH % 2) and is in fact, a strong oxidizer (providing, e.g., peroxidation of a cell membrane). This study addresses the question: which acid is created in water by plasma treatment. Two major possibilities are considered: nitric/nitrous acid and an acid which consist of a hydrogen cation (H þ ) and a superoxide anion (O À 2 ), which, for the lack of a better term, we call plasma acid. The presence of nitric/nitrous acid in the water after plasma treatment in air is confirmed, although the observed pH % 2 cannot be completely explained by the production of nitric acid. Moreover, experiments with oxygen-plasma treatment of water also lead to high acidity, without production of nitrogen based acids at all. Therefore, O À 2 , the conjugate base of the plasma acid, is at least partially responsible for both lowering of the pH and the increase in the oxidizing power of the solution. Experiments indicate that peroxides such as H 2 O 2 and O À 2 , together with an acidic environment are likely to be responsible for the oxidation properties of the plasma treated water. This plasma acid remains stable for at least a day, depending on the gas where plasma is generated, but the effect is temporal. Existence of a temporal and stable oxidizer created using the plasma treatment of pure water not only raises interesting scientific questions and possibilities, but is also likely to provide many applications in situations where direct plasma treatment may be difficult to achieve. Plasma Process. Polym. 2012,

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confidence: 99%

Retraction: Plasma Acid: Water Treated by Dielectric Barrier Discharge

Shainsky

Dobrynin

Ercan

et al. 2012

Plasma Processes & Polymers

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“…However, since EthD-2 carries a net positive charge, we cannot rule out the possibility that EthD-2 may be recruited to the cell surface via electrostatic interaction with negatively charged species deposited by plasma (15). Alternatively, EthD-2 may stain nucleic acids leaking from the periphery of NTP-treated cells, as we and others have shown that plasma rapidly permeabilizes cell membranes and extracts intracellular nucleic acids (18). Prior to the onset of visible membrane damage, we observed only minor increases in DNA damage and protein oxidation, indicating that genetic damage and oxidative stress do not play primary roles in NTP-mediated microbial sterilization, consistent with the findings of other groups (7,26,27).…”

Section: Discussionmentioning

confidence: 99%

Nonthermal Atmospheric Plasma Rapidly Disinfects Multidrug-Resistant Microbes by Inducing Cell Surface Damage

Kvam

Davis

Mondello

et al. 2012

Antimicrob Agents Chemother

160

111

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Plasma, a unique state of matter with properties similar to those of ionized gas, is an effective biological disinfectant. However, the mechanism through which nonthermal or "cold" plasma inactivates microbes on surfaces is poorly understood, due in part to challenges associated with processing and analyzing live cells on surfaces rather than in aqueous solution. Here, we employ membrane adsorption techniques to visualize the cellular effects of plasma on representative clinical isolates of drug-resistant microbes. Through direct fluorescent imaging, we demonstrate that plasma rapidly inactivates planktonic cultures, with >5 log 10 kill in 30 s by damaging the cell surface in a time-dependent manner, resulting in a loss of membrane integrity, leakage of intracellular components (nucleic acid, protein, ATP), and ultimately focal dissolution of the cell surface with longer exposure time. This occurred with similar kinetic rates among methicillin-resistant Staphylococcus aureus (MRSA), Pseudomonas aeruginosa, and Candida albicans. We observed no correlative evidence that plasma induced widespread genomic damage or oxidative protein modification prior to the onset of membrane damage. Consistent with the notion that plasma is superficial, plasma-mediated sterilization was dramatically reduced when microbial cells were enveloped in aqueous buffer prior to treatment. These results support the use of nonthermal plasmas for disinfecting multidrug-resistant microbes in environmental settings and substantiate ongoing clinical applications for plasma devices. P lasmas are ionized gases that exhibit a plethora of applied temperature and physical properties. In biomedical applications, plasmas are supported by an electric field such that electrons receive external energy more rapidly than surrounding ions (5). Plasmas generate thermal energy (heat) when heavy particle temperatures equilibrate with electron temperature but are considered "nonthermal" when the cooling of ions and uncharged molecules is more effective than the energy transfer from electrons to gas (5). Nonthermal or "cold" plasmas produce a variety of shortlived and long-lived reactive components, including charged particles and UV radiation, without significantly raising temperature (25). Nonthermal plasmas (NTPs) are applied extensively in materials science to modify the properties of carbon-based materials but have also shown promise for applications in biology and med-

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“…The hydroxyl radicals generated from APACP may contribute to membrane lipid peroxidation, causing an increase in membrane permeability (Ryu et al, 2013;Mai-Prochnow et al, 2014). It is evident from several related studies that the direct permeabilization of the cell membrane or wall is one of the modes of action in the toxicity of cold plasma for microbial cells (Kvam et al, 2012;Moreau et al, 2007).…”

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confidence: 99%

Inhibitory effect of silver nanoparticles mediated by atmospheric pressure air cold plasma jet against dermatophyte fungi

Ouf

El-Adly

Mohamed

2015

Journal of Medical Microbiology

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In an in vitro study with five clinical isolates of dermatophytes, the MIC 50 and MIC 100 values of silver nanoparticles (AgNPs) ranged from 5 to16 and from 15 to 32 mg ml 21, respectively. The combined treatment of AgNPs with atmospheric pressure-air cold plasma (APACP) induced a drop in the MIC 50 and MIC 100 values of AgNPs reaching 3-11 and 12-23 mg ml 21, respectively, according to the examined species. Epidermophyton floccosum was the most sensitive fungus to AgNPs, while Trichophyton rubrum was the most tolerant. AgNPs induced significant reduction in keratinase activity and an increase in the mycelium permeability that was greater when applied combined with plasma treatment. Scanning electron microscopy showed electroporation of the cell walls and the accumulation of AgNPs on the cell wall and inside the cells, particularly when AgNPs were combined with APACP treatment. An in vivo experiment with dermatophyte-inoculated guinea pigs indicated that the application of AgNPs combined with APACP was more efficacious in healing and suppressing disease symptoms of skin as compared with the application of AgNPs alone. The recovery from the infection reached 91.7 % in the case of Microsporum canis-inoculated guinea pigs treated with 13 mg ml 21 AgNPs combined with APACP treatment delivered for 2 min. The emission spectra indicated that the efficacy of APACP was mainly due to generation of NO radicals and excited nitrogen molecules. These reactive species interact and block the activity of the fungal spores in vitro and in the skin lesions of the guinea pigs. The results achieved are promising compared with fluconazole as reference antifungal drug.

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Gliding Arc Discharge in the Potato PathogenErwinia carotovorasubsp.atroseptica: Mechanism of Lethal Action and Effect on Membrane-Associated Molecules

Cited by 69 publications

References 29 publications

Retraction: Plasma Acid: Water Treated by Dielectric Barrier Discharge

Retraction: Plasma Acid: Water Treated by Dielectric Barrier Discharge

Nonthermal Atmospheric Plasma Rapidly Disinfects Multidrug-Resistant Microbes by Inducing Cell Surface Damage

Inhibitory effect of silver nanoparticles mediated by atmospheric pressure air cold plasma jet against dermatophyte fungi

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