Model Sentetik Polimerlerin Ve Komplekslerinin Gaz Fazı Karakteristiklerinin İncelenmesi
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Date
2016Author
Atakay, Mehmet
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Mass spectrometry is the most convenient technique for obtaining useful information
about the formation parameters of noncovalent complexes in both solution and gas
phases with high accuracy and sensitivity. Ion mobility-mass spectrometry (IM-MS)
additionally gives conformational data about the analyzed molecules. From the drift
time data obtained from the IM-MS analyses, the collision cross sections (CCS) of ions
can be determined, which is a size parameter related to the averaged momentum
transfer impact area of the ions. At the beginning of the studies, poly-L-lysine (PLL)
and polystyrene sulfonic acid (PSS) were analyzed using MALDI tandem time-of-flight
(ToF/ToF) mass spectrometer. The end groups of their chains could be determined by
evaluating data obtained from MALDI mass spectra. Mixtures of PLL and PSS were
prepared in various molar ratios and the signals of their noncovalent complexes could
be detected in the negative ion mode MALDI-MS analysis. The MALDI-MS/MS spectra
confirmed the proposed stoichiometries of the observed noncovalent complexes of
PLL and PSS. Noncovalent complexes of PLL and PSS could also be detected in both
positive and negative ion mode using ESI-Q/ToF-MS with ion mobility capabilities.
Complexes with various charge states and stoichiometries could be identified easily
utilizing ion mobility separation. Most of the noncovalent complex ions obtained in
positive and negative ion modes were fragmented upon collisionally activated
dissociation in the transfer cell unit of the instrument. ESI-MS/MS spectra obtained for
both positive and negative ion modes correlated well with the stoichiometry of the
complexes. Another polyanion, polyacrylic acid (PAA) sample was analyzed by itself
in detail and six different types of PAA series with various end groups were detected
in the sample. It was determined that some of the series must have been present in
the PAA sample solution while the other series were probably generated in gas phase
during the MS experiment. CCS of PLL-PAA complex ions with different PAA series
were derived separately for comparison of their compactness. The results prove that
the sizes of end groups of each species affect the conformation of the noncovalent
complex in the gas phase. When the poly-L-glutamic acid (PGA) was analyzed, it was
determined that its sample contains linear and cyclic forms of PGA. A mixture of PLL
and PGA was also analyzed in order to monitor the complexes formed between these
polyelectrolytes. The CCS of polyelectrolyte ions were derived individually for
comparing their compactness. It was obtained that the gas-phase conformations of the
polyelectrolytes depend on the nature of functional groups located in their repeating
unit. The CCS values of polyelectrolyte complex ions were also derived. Comparison
of the CCS values of the complexes indicated that differences in complex ion formation
may be caused by reducing repulsion forces between charged groups or forming more
extended structures. Noncovalent complexes of lysozyme formed with PSS oligomers
were also examined in the dissertation to determine how the CCS of protein changed
with the stoichiometry of the PSS chains in the complex.