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The biological decontamination and sterilization is a crucial processing step in producing and reprocessing of medical devices. Since polymer-based materials are increasingly used for the production of medical devices, the application of conventional sterilization processes are restricted to a certain extent. Conventional sterilization techniques on the basis of high temperatures, toxic gases, or ionizing radiation can be detrimental to the functionality and performance of polymeric materials. For this reason, alternative, gentle, and efficient decontamination processes are required. One possible approach is the use of non-thermal physical plasmas. Especially atmospheric pressure plasma is receiving great interest due to the absence of vacuum systems which is highly attractive for the practical applicability. Its mechanisms of action enable the efficient killing and inactivation of micro-organisms which are attributed to the interaction of plasma-generated reactive oxygen and nitrogen species (ROS, RNS) as well as plasma-emitted (V)UV radiation. Owing to the moderate gas temperatures (near or at room temperature) so-called cold plasmas are well-suitable for the treatment of heat-sensitive materials, such as polymers, without affecting their bulk properties. The present work focuses on the investigation of atmospheric pressure plasma processes for the biological decontamination of polymers. The objective is to help elucidate on the one hand the impact of varied plasma process parameters on the inactivation of micro-organisms and on the other hand the influence of plasma on the surface properties of the substrate. The investigations were performed by means of a high-frequency driven plasma jet (from the product line kINPen) operated with argon and argon-oxygen mixtures. Three main aspects were analyzed: 1. The effect of plasma on the viability of micro-organisms dependent on working gas, treatment time, and the sample distance (distance between the jet nozzle and the substrate). 2. The plasma-based removal of microbial biofilms. 3. The effects of the plasma treatment on the surface properties of selected polymers. Additionally to the capability of the applied plasma jet in killing microbes the efficacy of this plasma jet for the removal of complex biological systems (e.g. biofilms) is shown. To model cell constituents of bacteria different synthetic polymers were chosen to gain insight into the decomposition process responsible for biofilm degradation. By investigating the impact of atmospheric pressure plasma on physico-chemical surface properties of various synthetic aliphatic and aromatic polymers the interaction mechanisms between plasma and plasma-exposed material are discussed. These studies are accompanied by applying different optical plasma diagnostic techniques (optical emission spectroscopy and two-photon absorption laser induced fluorescence spectroscopy) to obtain information on the plasma gas phase which contributes to the elucidation of the reaction mechanisms occurring during plasma exposure. Moreover, it is presented to which extent the plasma treatment influences the surface properties of polymers during the plasma-based bio-decontamination process and further, the benefits of surface-functionalized polymers for biomedical application is discussed.
In the framework of the current work has been the plasma initiated and surface catalysed species conversion studied in low pressure and atmospheric plasmas. The aim of the work is to improve the understanding of the internal processes in order to increase the energy efficiency as well as the selectivity of the reaction products of future plasma devices. Beside many technical applications of plasmas, air purification shows great potential. Over the last decades, plasma based pollution control has proofed its ability to remove harmful contaminants or annoying odours from an air stream. However, the energy efficiency and the selectivity of the products are a remaining challenge.
Motivated by these issues, a multi stage packed-bed reactor has been used to remove admixed ethylene and toluene from an air stream. It has been found that the maximum toluene destruction has been 60%, whereas ethylene has been nearly completely removed. The specific energy β has been between 120 and 1600 JL-1. Fourier Transform Infrared spectroscopy, FTIR spectroscopy, has been used to identify and quantify the species H2O, CO2, CO, O3, HNO3, HCN, CH2O, CH2O2, N2O and NO2. However, none of these experiments led to the detection of NO.
The embedment of packing material into a plasma volume leads to increased surface effects. In order to study them, the inner side of a tube reactor, made of Pyrex, served as the surface under study and has been exposed to a rf plasma for 1h. The surface effects of the plasma treatment have been investigated indirectly by studying the oxidation of NO into NO2. After the plasma exposure, the reactor has been evacuated and filled with a gas mixture of 1% NO in N2 / Ar. Both species have been measured using quantum cascade laser absorption spectroscopy, QCLAS. It has been found that, using oxygen containing plasmas, the NO concentration decreased whereas the NO2 concentration increased. Therefore, oxygen containing plasmas are able to deposit oxygen on the surface. The filling with NO leads to the oxidation via the Eley-Rideal mechanism. A simplified model calculation supports these assumptions.
For a more comfortable application of the QCLAS, a compact multi channel spectrometer has been developed, TRIPLE Q. It combines the high time resolution with the possibility to measure the concentration of at least three infrared active species simultaneously. Due to the high time resolution, a huge number of spectra have to be analysed. In order to calculate absolute number densities, an algorithm has been developed which automatically treats typical phenomena like pulse jitter, rapid passage effect or variations of the intensity of the laser pulses.
The gas temperature is an important parameter in plasma physics. Using the TRIPLE Q system, the gas temperature has been determined for pulsed dc plasmas. For this case, NO has been used as a probe gas. From the spectra, the temperature has been calculated using the line ratio method. The relative intensity of the absorption structures of NO at 1900.5cm-1 and 1900.08cm-1 depend on the temperature. Therefore, the ratio has been used to calculate the gas temperature with a time resolution in the μs range.
Vibrationally excited nitrogen can be an energy reservoir that plays an important role in plasma chemistry. In N2 / N2O plasmas, vibrationally excited N2 can undergo relaxation via a resonant vibration vibration coupling between vibrationally excited N2 and N2O. Due to such an efficient energy transfer, the method allows one to study the relaxation of vibrationally excited N2. Using this method, molecules, which are not infrared active, can be monitored. This approach has extended the field of scientific and commercial applications of the QCLAS.