Browsing by Subject "desorption"

Lipids are fat soluble compounds that are derived from living tissues. Lipids have many important physiological functions. Developing methods for efficient lipid analysis is important since lipids can function as biomarkers in diseases. Additionally these methods can be used for the discovery of the biological processes of disease development. Lipids comprise of molecules with different polarity and structure. Several mass spectrometric ionization methods have been used in the analysis of lipids but they usually require sample preparation prior to the analysis. Desorption electrospray ionization-mass spectrometry (DESI-MS) and desorption photoionization-mass spectrometry (DAPPI-MS) are novel ionization methods that allow sample analysis straight from the matrix, such as tissue, usually without any sample preparation. DESI-MS has already been used in the analysis of different lipids, but DAPPI-MS has only been used in the analysis of steroids. The ionization of a range of lipid compounds (phospholipids, triglycerides, fat soluble vitamins, fatty acids, and steroids) by DAPPI-MS and DESI-MS was studied. Analysis conditions were optimized for all the different lipid classes with both DAPPI and DESI using standard samples. Some lipids were also analysed straight from pharmaceutical preparations. There were differences in the suitabilities of DAPPI-MS and DESI-MS for the ionization of different lipid classes. DAPPI-MS worked well for the ionization of nonpolar lipids like triglycerides, vitamins and fatty acids, but the phospholipids fragmented in the DAPPI-MS process and showed no molecular ion. Previous studies have shown that DESI-MS works well in the ionization of phospholipids, and this study showed that it works reasonably well for other lipid groups as well, with the exception of some of the nonpolar lipids. New knowledge was acquired especially about the suitability of DAPPI-MS for the analysis of different lipids. Based on the results it can be said that DAPPI-MS works equally well or better than DESI-MS in the ionization of most lipid classes. The DAPPI method should still be further developed so that phospholipids, which are very important lipids in human physiology, could be analysed by DAPPI-MS. As lipids were not analysed straight from a tissue sample, there are no conclusions about the suitability of DAPPI-MS for the analysis of lipids straight from tissue samples.

Ambient mass spectrometry includes methods where ions are produced outside of the mass spectrometry in atmospheric pressure direct from the surface of the sample without sample preparation. The first and most popular ambient ionization methods are DESI, desorption electrospray ionization and DART, direct analysis in real time. DAPPI, desorption atmospheric pressure photoionization is an ionization method where samples are desorbed with hot vapor from surface and then ionized by photoionization. The aim of this study was to develop desorption atmospheric pressure photoionization method in transmission geometry. In transmission geometry hot vapor for microchip is directed through metal or polymer meshes to mass spectrometer inlet. Liquid samples can be analyzed either by soaking the mesh to liquid sample or apply a sample droplet to the mesh. Hot vapor desorbs analytes from the mesh and analytes are ionized in a gas phase by photoionization using VUV lamp. In this method optimal positioning of the mesh and the microchip was determined. Additionally optimal microchip heating power, dopant flow rate, nebulizer gas flow rate, capillary voltage and drying gas parameters were determined. Optimized method was applied for analyzing standard samples, vitamin juice samples and milk samples. According the analysis with authentic samples, transmission mode DAPPI can be applied for analyzing liquid samples without sample preparation. According the analysis with standard samples, transmission mode DAPPI can be applied for extraction of hydrophobic analytes from water samples. Comparing to conventional DAPPI, in transmission mode DAPPI spectra, intensities of the background ions are lower resulting higher signal-to-noise ratios with transmission mode DAPPI.