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- Mikkonen, Saara
(author)
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Electrophoretic focusing in microchannels combined with mass spectrometry : Applications on amyloid beta peptides
- 2016
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Doctoral thesis (other academic/artistic)abstract
- Analysis of low-abundance components in small samples remains a challenge within bioanalytical chemistry, and new techniques for sample pretreatments followed by sensitive and informative detection are required. In this thesis, procedures for preconcentration and separation of proteins and peptides in open microchannels fabricated on silicon microchips are presented. Analyte electromigration was induced by applying a voltage along the channel length, and detection was performed either by matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) within the open channel, or by sampling a nL fraction containing the preconcentrated analytes from the channel for subsequent nano-electrospray ionization- (nESI-) or MALDI-MS. Utilizing solvent evaporation from the open system during sample supply, sample volumes exceeding the 25-75 nL channel volume could be analyzed. For preconcentration/separation of components in the discrete channel volume a lid of inert fluorocarbon liquid was used for evaporation control.In Papers I and II, aqueous, carrier-free solutions of proteins and peptides were analyzed, and the method was successfully applied for fast and simple preconcentration of amyloid beta (Aβ) peptides, related to Alzheimer’s disease.The impact of possible impurities in the analysis of carrier-free solutions was investigated in Paper III with the 1D simulation software GENTRANS, and a method for open-channel isoelectric focusing in a tailor-made pH gradient was developed. The latter approach was used in Paper IV for preconcentration and purification of Aβ peptides after immunoprecipitation from cerebrospinal fluid and blood plasma, followed by MALDI-MS from a micropillar chip.Paper V includes simulations of an isotachophoretic strategy for selective enrichment of Aβ peptides. GENTRANS simulations were used to select the electrolyte composition, and 2D simulations in a geometry suitable for on-chip implementation were performed using COMSOL Multiphysics.
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| 2. |
- Ek, Patrik, 1980-
(author)
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Mass Spectrometry with Electrospray Ionization from an Adjustable Gap
- 2008
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Licentiate thesis (other academic/artistic)abstract
- In this thesis the fabrication and analytical evaluation of two new electrospray emitters utilized for mass spectrometry analysis is presented. The emitters are based on a new concept, where the spray orifice can be varied in size. The thesis is based on two papers. All present-day nanoelectrospray emitters have fixed dimensions. The range of the applicable flow rate for such an emitter is therefore rather limited and exchange of emitters may be necessary from one experiment to another. Optimization of the signal of the analyte ions is also limited to adjustments of the applied voltage or the distance between the emitter and the mass spectrometer inlet. Furthermore, clogging can occur in emitters with fixed dimensions of narrow orifice sizes. In this thesis, electrospray emitters with a variable size of the spray orifice are proposed. An open gap between two thin substrates is filled with sample solution via a liquid bridge from a capillary. Electrospray is generated at the end point of the gap, which can be varied in width. In Paper I, electrospray emitters fabricated in polyethylene terephthalate have been evaluated. Triangular tips are manually cut from the polymer film. The tips are mounted to form a gap between the edges of the tips. The gap wall surfaces are subjected to a hydrophilic surface treatment to increase the wetting of the gap walls. In Paper II, silicon electrospray chips with high precision are fabricated and evaluated. A thin beam, elevated from the bulk silicon chip is fabricated by means of deep reactive ion etching. The top surfaces of the beams of two chips act as a sample conduit when mounted in the electrospray setup. An anisotropic etching step with KOH of the intersecting <100> crystal planes results in a very sharp spray point. The emitters were given a hydrophobic surface treatment except for the hydrophilic gap walls. For both emitter designs, the gap width has been adjusted during the experiments without any interruption of the electrospray. For a continuously applied peptide mixture, a shift towards higher charge states and increased signal to noise ratios could be observed when decreasing the gap width. The limit of detection has been investigated and the silicon chips have been interfaced with capillary electrophoresis.
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| 3. |
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| 4. |
- Redeby, Theres, 1973-
(author)
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Improved Techniques for Protein Analysis Focusing on Membrane Proteins and Hydrophobic Peptides
- 2006
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Doctoral thesis (other academic/artistic)abstract
- In this thesis, the vital cell functions performed by integral membrane proteins (IMPs) are briefly discussed. Such proteins are under-represented in most protein studies due to the hydrophobic nature of IMPs, which seriously complicate their solubilization, sample handling, preparation, separation and analysis. Conventional analytical techniques include for example matrix-assisted laser desorption/ionization mass spectrometry (MALDIMS), capillary electrophoresis (CE) and reversed phase high-performance liquid chromatography (RP-HPLC). Presented here are methods and protocols, which have been developed especially for IMP and hydrophobic peptide analysis, using the abovementioned techniques. The fluorinated organic solvent hexafluoroisopropanol (HFIP) has previously been shown beneficial as an additive for solubilization of hydrophobic analytes, which are poorly soluble in commonly used organic solvents or water. In Papers I-IV, HFIP is successfully exploited as solvent for the investigated IMPs and peptides. The simple fabrication and the focusing effect of a new structured MALDI target plate are presented in Paper I. This target plate contains concentrating sample spots, specifically designed to provide increased sensitivity for hydrophobic protein and peptide MALDI-MS analysis. When replacing a regular steel target with this new structured MALDI plate, more than a five-fold increase in average sensitivity is achieved for HFIP solubilized hydrophobic peptides. The full-length IMP bacteriorhodopsin (BR) and a cyanogen bromide digest thereof are used as model samples for the development of sample handling procedures in Paper II, and the peptides were used for evaluation of the MALDI-target plate in Paper I. Furthermore, the CE separation of the peptides, fractionation onto the structured MALDI plate and following MS analysis is presented in Paper III. Nine of the ten theoretical BR peptides were detected using this method. A protocol for the purification and analysis of chloroplast membrane proteins from the green macroalga Ulva lactuca has been described in Paper IV. The highest protein yield was achieved when proteins were extracted in HFIP, directly from the chloroplasts. The MALDI-MS analysis of samples with and without previous RP-HPLC fractionation revealed proteins with molecular weights ranging between 1 and 376 kDa. In Paper V, a closed-open-closed CE system is presented, containing an open microchannel for off-line MALDI detection. The electroosmotic flow and band broadening of this system has been evaluated.
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