Doctoral Thesis
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The here presented dissertation investigated the molecular mechanisms, by which the food industry model bacteria Pseudomonas fluorescens and Listeria monocytogenes, grown either as planktonic cultures, were inhibited by plasma treated water (PTW) produced by a microwave-induced plasma source (MidiPLexc). As a starting point, optimal operating parameters were determined with 5 standard liters per minutes(slm)compressed air during the treatment of 10 ml deionized water within a treatment time of up to 15 min (pre-treatment time). Treatment times of 1, 3 and 5 min were selected (post-treatment time). In addition to physical parameters, i.e. temperature measurements at different spots at the plasma source during the production of the PTW, the chemical composition of PTW was determined by pH measurements, chronoamperometry (determination of the H2O2 concentration), ion chromatography (determination of the NO2-, NO3- and ONOO- concentrations) and mass spectrometry (qualitative determination of the molecules). In addition, concentration changes of reactive species over a period of 3 h indicated a decrease of the NO2- concentration as well as an increase of the NO3- and ONOO- concentration in the PTW. Microbiological assays, i.e. quantification of colony-forming units (CFU), fluorescence and XTT assays, revealed a significant reduction of the proliferation ability of the cells, membrane damages and metabolic activity have been demonstrated for planktonic cultures as well as mono- and multispecies biofilms. PTW effects on biofilm structures were investigated using microscopic methods such as fluorescence microscopy, confocal laser scanning microscopy (CLSM), atomic force microscopy (AFM), and scanning electron microscopy (SEM), as well as physical methods such as contact angle measurements. Significant changes in the biofilm structure have been shown, which indicate an ablation of the biofilm mass from top to bottom by approximately 2/3 of the biofilm mass and a destruction of the extracellular matrix (ECM) by the reactive species within the PTW. Subsequently, fresh-cut lettuce has been treated with PTW produced by up-scaled plasma sources. Apart from qualitative parameters of the lettuce after PTW treatment such as texture and color, the concentration of PTW reactive species have been determined. These experiments showed that the composition of the reactive species were slightly different from that of the laboratory-scaled plasma source MidiPLexc. Notably, the PTW treatment did not cause significant changes in texture and color of the fresh-cut lettuce. Finally, a synergistic effect of PTW treatment followed by plasma-processed air (PPA) drying was demonstrated application-specific.
In this study we investigated the synergistic antimicrobial effect of a dual protocol combining cold atmospheric pressure plasma (CAP) and antimicrobial photodynamic therapy (aPDT) against different planktonic bacterial and yeast species including methicillin-sensitive and methicillin-resistant Staphylococcus aureus, Escherichia coli, extended-spectrum β-lactamase-positive Escherichia coli and Candida albicans. A DBD plasma device was used for CAP treatment while for aPDT, toluidine blue O (TBO) was the photosensitizer (PS) of choice and a radiator emitting visible and water-filtered-Infrared A light (VIS-wIRA) was used as irradiation source.
Microbial suspensions were either exposed to CAP treatment alone, aPDT treatment alone or aPDT followed by CAP exposure in a dual treatment protocol. Aliquots from each suspension were plated on agar plates and the number of colonies surviving after each treatment was counted. Under the experimental conditions conducted in this study, combining sub-lethal exposure doses of CAP and aPDT treatment showed significantly higher antimicrobial efficacy (P<0.0001) compared to single treatments against all tested microorganisms suggesting a synergistic effect which yielded at least 3.3 log microbial reduction corresponding to 99.6 % microbial death. In the dual CAP-aPDT approach, aPDT did not interfere with CAP-induced acidification of solution, a crucial feature for CAP antimicrobial efficiency, which further confirms the promising clinical potential of this combination regime.
We believe that the CAP-aPDT dual approach described in this study holds great potential as a successful novel antimicrobial and healing-supporting strategy especially when directed for the management of acute and chronic wounds and possibly other skin and soft tissue infections. The use of a VIS-wIRA light source in treating skin infections is preferential, due to the additional therapeutic effects of wIRA in wound healing. Furthermore, the enhanced antimicrobial effects of aPDT when combined with CAP as shown in this study may grant for a reduction in treatment times and costs as well as improving patient compliance.