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Study of elementary inactivation processes acting during sterilization of procaryotic systems in dielectric barrier discharge
Bittnerová, Zuzana ; Sťahel, Pavel (referee) ; Kozáková, Zdenka (advisor)
Presented master’s thesis is focused on the study of the elementary inactivation processes acting during sterilization of procaryotic systems in dielectric barrier discharge (DBD). Sterilization is an important biomedical and food-industry application and plasma sterilization is one of the methods, which are suitable for sterilization of heat and chemical sensitive materials. Biologically contaminated samples were treated in dielectric barrier discharge operated at atmospheric pressure. The discharge was generated in argon and in nitrogen. The plasma power density was 2725,93 mW cm–3 in argon and 2325,93 mW cm–3 in nitrogen. Gram positive bacteria Bacillus subtilis and gram negative bacteria Escherichia coli were used as a bioindicator. Bacteria were spread onto the surface of Whatman No.1 filtration paper. The influence of UV radiation, reactive species, heat and plasma discharge where the synergistic function of all of the agents was studied. Effects of UV radiation and temperature were studied separately. In order to separate the effect of UV radiation generated by DBD the quartz glass transmitting UV radiation was employed. During the plasma exposition selected samples were covered with the quartz window while other samples were directly exposed to the plasma. Covered samples were exposed to UV radiation and temperature (which cannot be eliminated), samples without quartz window were directly plasma exposed (treated). Results show that for covered samples the lower inactivation was reached than by the samples directly exposed to plasma. When studying the effect of temperature, the temperature between the DBD electrodes was measured by means of a thermocouple. Afterwards the samples were placed in an oven and exposed to the same temperature as was measured between the electrodes. By comparing the results of heat treated samples and plasma treated samples it can be assumed that the influence of the temperature during the sterilization process in DBD is very low. The discharge parameters were studied by means of the Optical Emission Spectroscopy. Plasma treated samples were assessed employing Scanning Electron Microscopy (SEM). Damage of Bacillus subtilis cell wall due to the effect of plasma was observed while no effect of plasma on the structure of filtration paper was detected.
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Study of sterilization effect of dielectric barrier discharge on procaryotic microorganisms
Bittnerová, Zuzana ; Ing.Hana Grossmannová, Ph.D. (referee) ; Kozáková, Zdenka (advisor)
Presented bachelor thesis is focused on sterilization effect of dielectric barrier discharge on procaryotic microorganisms. Sterilization is important biomedical and food-industry application and plasma sterilization is one of the method, which are suitable for sterilization of heat and chemical sensitive materials. Biologicaly contaminated samples were treated in dielectric barrier discharge operated at atmospheric pressure. The discharge was generated in argon and in nitrogen. Gram positive bacteria Bacillus subtilis was used as a bioindicator. Bacteria was spread onto the surface of paper and PET material. Efficiency of sterilization was evaluated according to exposure time, plasma power density and process gas. The positive effect of DBD on inactivation of microorganism was observed. The efficiency of the plasma sterilization increases with increasing treatment time. As regards plasma power density, the higher density was used the more effective the sterilization was and time necessary for inactivation of all microorganisms was shorter. Sterility was observed within 60 s while using plasma power density 2,37 W/cm, when using plasma power density of 1,78 W/cm longer treatment time is neccesary. The sterilization was more effective if argon was used as a process gas. Time necessary for the most reduction of microorganisms in argon was 10 s, while using nitrogen the reduction was only 50 %.
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Study of elementary inactivation processes acting during sterilization of procaryotic systems in dielectric barrier discharge
Bittnerová, Zuzana ; Sťahel, Pavel (referee) ; Kozáková, Zdenka (advisor)
Presented master’s thesis is focused on the study of the elementary inactivation processes acting during sterilization of procaryotic systems in dielectric barrier discharge (DBD). Sterilization is an important biomedical and food-industry application and plasma sterilization is one of the methods, which are suitable for sterilization of heat and chemical sensitive materials. Biologically contaminated samples were treated in dielectric barrier discharge operated at atmospheric pressure. The discharge was generated in argon and in nitrogen. The plasma power density was 2725,93 mW cm–3 in argon and 2325,93 mW cm–3 in nitrogen. Gram positive bacteria Bacillus subtilis and gram negative bacteria Escherichia coli were used as a bioindicator. Bacteria were spread onto the surface of Whatman No.1 filtration paper. The influence of UV radiation, reactive species, heat and plasma discharge where the synergistic function of all of the agents was studied. Effects of UV radiation and temperature were studied separately. In order to separate the effect of UV radiation generated by DBD the quartz glass transmitting UV radiation was employed. During the plasma exposition selected samples were covered with the quartz window while other samples were directly exposed to the plasma. Covered samples were exposed to UV radiation and temperature (which cannot be eliminated), samples without quartz window were directly plasma exposed (treated). Results show that for covered samples the lower inactivation was reached than by the samples directly exposed to plasma. When studying the effect of temperature, the temperature between the DBD electrodes was measured by means of a thermocouple. Afterwards the samples were placed in an oven and exposed to the same temperature as was measured between the electrodes. By comparing the results of heat treated samples and plasma treated samples it can be assumed that the influence of the temperature during the sterilization process in DBD is very low. The discharge parameters were studied by means of the Optical Emission Spectroscopy. Plasma treated samples were assessed employing Scanning Electron Microscopy (SEM). Damage of Bacillus subtilis cell wall due to the effect of plasma was observed while no effect of plasma on the structure of filtration paper was detected.
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Study of sterilization effect of dielectric barrier discharge on procaryotic microorganisms
Bittnerová, Zuzana ; Ing.Hana Grossmannová, Ph.D. (referee) ; Kozáková, Zdenka (advisor)
Presented bachelor thesis is focused on sterilization effect of dielectric barrier discharge on procaryotic microorganisms. Sterilization is important biomedical and food-industry application and plasma sterilization is one of the method, which are suitable for sterilization of heat and chemical sensitive materials. Biologicaly contaminated samples were treated in dielectric barrier discharge operated at atmospheric pressure. The discharge was generated in argon and in nitrogen. Gram positive bacteria Bacillus subtilis was used as a bioindicator. Bacteria was spread onto the surface of paper and PET material. Efficiency of sterilization was evaluated according to exposure time, plasma power density and process gas. The positive effect of DBD on inactivation of microorganism was observed. The efficiency of the plasma sterilization increases with increasing treatment time. As regards plasma power density, the higher density was used the more effective the sterilization was and time necessary for inactivation of all microorganisms was shorter. Sterility was observed within 60 s while using plasma power density 2,37 W/cm, when using plasma power density of 1,78 W/cm longer treatment time is neccesary. The sterilization was more effective if argon was used as a process gas. Time necessary for the most reduction of microorganisms in argon was 10 s, while using nitrogen the reduction was only 50 %.
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