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Browsing by master's degree program "Kemian ja molekyylitieteiden maisteriohjelma"

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  • Peltoniemi, Martta (2023)
    The glymphatic system is a waste clearance system in the brain to prevent protein accumulation that negatively affects neural functions, leading to neurogenerative diseases such as Alzheimer's. Perivascular spaces surround the brain vasculature allowing cerebrospinal fluid (CSF) inflow into the brain parenchyma during NREM sleep. The CSF moves from perivascular spaces into the white matter through AQP4 water channels, and flows towards the efflux routes, from where the interstitial solutes are drained into the lymphatic system. The existence and functions of the glymphatic system raise controversies due to the lack of quantitative data. Imaging tools that do not negatively affect the flow are required to visualize the glymphatic system in health and disease. If the glymphatic flow could be intensified in a preventive or therapeutic manner or harness for CNS drug delivery, it would be revolutionary. Positron emission tomography (PET) is a rising imaging modality in glymphatic research. It provides an efficient and non-invasive method, even with nanomolar tracer concentrations, to follow the CSF within the entire animal, being also fully translatable for human studies. Albumin is the dominant protein the CSF and can act as a carrier for tracers extending the circulation time. More recently, truncated Evans Blue (EB) and 4-(p-iodophenyl)butyric acid (IP) have shown promising results in modulating the pharmacokinetics of radiopharmaceuticals through albumin-binding. This study aimed to develop and evaluate six new albumin- binding tracers ( three NODAGA conjugated and three DFO conjugated) for the PET imaging of the glymphatic fluid flow via binding of endogenous albumin in the CSF. The precursors were synthesized using coupling reactions and radiolabeled with [68Ga]GaCl3 (0.2M sodium acetate buffer, pH=4, 95°C or 25°C, 15 min). Radiochemical purities were determined by radio-TLC and radio-HPLC and LogD (octanol:PBS) with shake-flask method. The in vitro stability assays were done in rat serum, rat CSF, 2 mM EDTA, and 0.2 mM FeCl3 solutions at 37°C over 6 h of incubation. The in vitro albumin binding affinities were investigated at physiological rat CSF albumin concentration at 37°C over 1 h of incubation using radio-SEC- HPLC. The in vivo and ex vivo experiments of the three most stable tracers were done using healthy female Swiss mice, and the experiments included blood kinetic studies, ex vivo biodistribution studies, and analysis of urine, bile, and blood fractions (plasma, blood cells, proteins) for in vivo stability. The precursors were synthesized with high yields (69–96%) and radiolabeled with high radiochemical yield (64– 82%), radiochemical purity (97–99.5%), and molar activities sufficient for low-volume infusion into the CSF (9.2– 17.2MBq/nmol). The NODAGA conjugated tracers had higher radiochemical yield and molar activity than the DFO conjugated tracers. The radiolabeled DFO conjugated products were stable in rat serum and rat CSF, but stability assays with EDTA and FeCl3 showed major transchelation. The NODAGA conjugated tracers were stable in each medium, maintaining the percent of intact labeled compound above 97%. The albumin binding affinity studies showed full binding from the first time point of 5 min incubation until the last time point of 1 h. The blood kinetic studies of the three stable NODAGA conjugates showed decreasing %ID/g with varying biological half- lives depending on the tracers’ lipophilic properties. The ex vivo analysis of urine and bile showed eliminated free tracer or some metabolite of the free tracer with similar retention time with radio-HPLC, no free gallium was observed. The analysis of blood samples after fractionation showed that each tracer had the most significant %ID/g in the protein fraction, and no activity was observed in the plasma. The in vivo investigated tracers showed promising properties for possible future use as CSF tracer due to high radiolabel stability and rapid stable binding to albumin in vivo.
  • Suuronen, Markus (2021)
    People spend more than 90% of time indoors. That has made the analysis of indoor air quality an subject of interest. There is a growing popularity of miniaturized sample extraction techniques utilizing solid adsorbent materials and thermal desorption allowing direct sample introduction for analysis. This approach is solvent free and there is possibility for reusing adsorbent materials depending of adsorbent properties. This thesis covers the basics of adsorption-desorption process and takes detailed look on different adsorbent materials such as activated carbon (AC), metal-organic framework (MOF) and carbon nanotubes (CNT) and evaluates the effect of surface functionality and pore size distribution for adsorption process. In experimental part, a self-made autosampler functionality and its injection parameters were optimized. The autosampler is able to independently inject up to six in-tube extraction (ITEX) needles with complete desorption. The ITEX was constructed during this experiment with TENAX-GR adsorbent and the repeatability of autosampler and ITEXs were tested and compared to commercial system with extraction of different amines. The effectiveness of this system was also demonstrated for indoor volatile organic compound (VOC) analysis.
  • Sachan, Sinivuokko (2021)
    At low concentrations, biogenic amines (BA) promote natural physiological activity, but at higher concentrations they can cause a wide variety of health hazards, especially for more sensitive individuals. The BA determination in wine is challenging due to the variation in physicochemical properties and the potential matrix effects of other compounds in the sample. It is important to develop efficient sample purification methods to minimize matrix interference. Derivatization is required for most biogenic amines due to the absence of chromophores. The conditions that promote the origin or formation of biogenic amines in wines are not yet fully understood, as many factors contribute to their formation. The main sources or stages of BA formation during wine-making should be identified in order to reduce BA levels by corrective measures. Currently, the analytical community is striving for more environmentally friendly methods. The literature review examines methods for determination of biogenic amines in wines from 2005 until 2020. The methods are high-performance liquid chromatography, ultra-high-performance liquid chromatography, high-temperature liquid chromatography, nano-liquid chromatography, micellar liquid chromatography, capillary electrophoresis, micromachined capillary electrophoresis, gas chromatography, immunoassay, sensor, colorimetric method, thin-layer chromatography and ion chromatography. The health disadvantages of biogenic amines and the problem areas associated with their determination from a complex wine matrix, such as matrix effect and derivatization, are also surveyed. In addition, changes in the BA profile during different stages of winemaking and storage, as well as the effect of the grape variety and lactic acid bacterial strain on the BA profile, are surveyed. Validation determines the suitability of a method for its intended use. In the methods for determining the literature review, measurement uncertainty - possibly the most important validation parameter - had not been determined in any of the validations. The aim of the research project was to obtain a functional and validated method for the determination of biogenic amines in wines for the Alcohol Control Laboratory at Alko Inc. In the method tested, histamine, tyramine, putrescine, cadaverine, phenylethylamine and isoamylamine derivatized with diethyl ethoxymethylene malonate were determined by high-performance liquid chromatography and diode array detector. The method was not sufficiently reliable, so a competitive enzyme-linked immunosorbent assay for the determination of histamine in wines was introduced, which provided a useful method for the Alcohol Control Laboratory. The validation determined specificity/selectivity, recovery, repeatability, systematic error, estimation of random error, measurement uncertainty, expanded measurement uncertainty, limit of detection and limit of quantification. The European Food Safety Authority has confirmed histamine and tyramine as the most toxic amines. The International Organization of Vine and Wine has not set legal limits for BA levels, but some European countries have had recommended maximum levels for histamine. Many wine importers in the European Union require a BA analysis even in the absence of regulations. Based on the literature review, high BA levels were found in the wines under study, including levels of histamine, tyramine, and phenylethylamine that exceeded the toxicity limits. Some wines had biogenic amines below the detection limit, so the production of low-amine wines is possible. In addition, certain strains of lactic acid bacteria were found to significantly reduce the BA levels in wine. High-performance liquid chromatography is the most widely used determination method. An increasing trend is to develop simpler methods such as the portable sensor-based method.
  • Grönfors, Helle (2023)
    The literature review focused on liquid chromatographic-mass spectrometric (LC-MS) methods used to quantify B12 vitamers in food matrices. Various MS methods have been used for the detection of B12, offering more specificity than other commonly used analysis techniques. This thesis aimed to develop a method for quantifying the native forms of B12 in different food matrices and avoiding the commonly used conversion to cyanocobalamin during extraction. In the experimental study, an ultra-high-performance LC-tandem MS (UHPLC-MS/MS) method was developed and validated for selectivity, specificity, recovery, repeatability, reproducibility, trueness, and measurement uncertainty to determine B12 vitamers in fermented plant-based foods and microbial cell supernatants. The development was initiated by setting up mass spectrometer conditions and selecting transitions for multiple reaction monitoring (MRM) to achieve selective and sensitive detection method for individual B12 vitamers. This was followed by developing the UHPLC method utilizing a reversed-phased C18 column and gradient elution with 0.5% formic acid and 0.5% FA in methanol. The vitamers were ionized using electrospray ionization in a positive ion mode and detected in an MRM mode using hydroxocobalamin, cyanocobalamin, adenosylcobalamin, and methylcobalamin. All B12 vitamers were detected and separated with the developed and optimized UHPLC-MS/MS method. The internal standard calibration method was necessary to overcome matrix effects when analyzing food samples. The calibration curve content range was 0.2–200 pg/µL, and the results showed good linearity. The instrumental method was selective, precise, repeatable, and reproducible with detection and quantitation limits of 0.03–0.4 pg/µL and 0.2–2 pg/µL, respectively. The measurement uncertainty of the instrumental method varied between 10% and 20%. For the entire method, recoveries for the B12 vitamers ranged from 40% to 200%, and measurement uncertainties from 40% to 60%. Results for the total B12 content in food samples deviated from those determined using a conventional UHPLC-PDA method: Recovery for tempeh was over 90%, but for fortified bread only 20%. These results indicate the need for further development of sample pretreatment. The instrumental method was successfully validated and separated matrix compounds from B12 vitamers in food samples to some extent. The developed sample pretreatment method is a good starting point for developing more effective sample pretreatment methods in the future.
  • Meriläinen, Veronika (2022)
    As nuclear reactors come to the end of their lifetime, they undergo decommissioning. All the construction materials and spend nuclear fuel must be characterized according to their activities before final disposal. For the analysis of difficult to measure radionuclides, such as beta emitters, sample decomposition methods are used. Acid digestion, alkaline fusion and thermal combustion are examples of sample decomposition methods. In this work, alkaline fusion methods were tested to gain knowledge on the suitability of the method for volatile and non-volatile radionuclides in decommissioning waste. The sample materials tested were concrete and two difficult to dissolve reference materials: soil and coal fly ash. Results obtained with alkaline fusion were compared with that of routinely used acid digestion method. In addition, activated graphite was studied to familiarize with the analysis of difficult to measure radionuclides. Non-volatile 63Ni and 55Fe and volatile 3H and 14C were studied. The results were compared with modelled activities. Alkaline fusions were performed with a borate flux in an automated fusion oven as well as with a carbonate flux in a muffle furnace. Acid digestion was performed in an open vessel with aqua regia. The dissolved samples were analysed with ICP-OES and ICP-MS for determination of elemental concentrations. Borate fusion seemed to be the most effective method, as it was suitable for all the sample materials and released even refractory elements. Some of the volatile elements were lost during the fusion methods (Cd and Zn), while some were not affected by the high temperatures used (Pb). Alkaline fusion methods appeared to be suitable for decommissioning studies, however further research is needed. In analysis of graphite, non-volatile elements were analysed by acid digestion. 55Fe and 63Ni were separated from the matrix by hydroxide precipitation and from each other by ion exchange in an AG-resin. Ni fraction was further purified by extraction chromatography with a Ni-resin. Volatile elements were analysed by thermal combustion in a pyrolyser. The activities of 55Fe, 63Ni, 3H and 14C were measured with liquid scintillation counting. The measured activity concentrations of 63Ni were partially in agreement with the modelled values, but some samples gave higher activities. No 55Fe activities were found in any samples, as was expected based on the modelled values and the short half-life of the radionuclide. Activities of the volatile 3H and 14C were accurate and close to the modelled values. In the future, the determined activity results will be used for improving scaling factors, for the assessment of radionuclide concentrations in graphite.
  • Niskala, Iiro (2023)
    This study focuses on analyzing dust samples with gas chromatography coupled with mass spectrometer. Humans get exposed to dust daily and it is important to know the risks this exposure brings. Dust is a complex, mainly organic matrix, which absorbs compounds easily. Some of these absorbed compounds have adverse effects on human health. To identify these harmful compounds from samples, they must be extracted into a solvent and possibly cleaned, so that they can be analyzed with gas chromatography coupled with a mass spectrometer system. Analysis of dust samples requires the right gas chromatography column, which can separate analytes of interest and a mass spectrometer with an ion source that can be used to analyze the sample qualitatively and/or quantitatively depending on the depth and type of the study. Along with samples, standards are used in quality control of the analysis method and in finding limitations of the method. Methods and results of the studies used in this thesis are compiled into tables. Sources and health effects of found compounds are discussed. In the experimental part of the thesis, analysis of dust samples from Finnish museums was done for the Finnish Institute of Occupational Health. These samples were concentrated and analyzed with gas chromatography coupled with a mass spectrometer system. The system had calibration issues, which had to be solved before the data it provided was usable. After the calibration issue was fixed, the analysis results were obtained and studied. In these results many harmful compounds were found, of which many were related to the preservation of the items housed in the museums. The compounds' health effects were studied and tabulated. These results show that further studies are required for dust samples to avoid exposure to compounds found in them.
  • Kyökari, Mikko Matias (2023)
    The literature part of the thesis gives an overview of the occurrence, properties, biological activities, and analytical approaches used for the quantification of resin acids and their derivatives in tree resins, with the emphasis being on a balanced discussion of specific analytical merits and limitations. The quantification of resin acids is challenging due to their isomeric nature and limited stability, with these marker compounds being sensitive to light, oxygen, and strong acids. Methods employing reversed phase liquid chromatographic (LC) approaches in combination with UV/Vis, fluorescence, and mass spectrometric (MS) detection are covered. Gas chromatographic (GC) approaches, involving various derivatization schemes, are discussed, with detection being typically achieved by flame ionization (FI) and MS. Less frequently employed protocols, utilizing zone capillary electrophoresis with cyclodextrin additives and UV and/or fluorescence detection (FLD) are reviewed. Finally, emerging protocols employing supercritical fluid chromatography in combination with FI and MS detection are outlined. Baseline resolution of all major resin acids can only be readily achieved with GC and supercritical fluid chromatography (SFC) methods, while LC and CE protocols suffer from partial peak overlap. In terms of practical convenience, SFC may provide currently the most favorable analytical approach, obviating the need for derivatization and allowing for superior sample throughput. The objective of the experimental part of the thesis was to develop robust and expediate HPLC/UV methods for the detection and quantification of selected active marker compounds, i.e., vanillin, p-coumaric acid, pinoresinol and dehydroabietic acid, in Norwegian spruce resin extracts. Emphasis was placed on obtaining protocols characterized by operational simplicity and ready transferability to production settings. The developed methods involved continuous hot extraction of milled resin samples with 96% EtOH, followed by a simple filtration step and isocratic reversed phase HPLC/UV analysis. A preliminary validation of the developed reversed phase HPLC/UV methods was carried out to assess the limits of detection and quantification (LOD and LOQ); calibration linearity/range; precision and accuracy. LOD and LOQ values were lower than 3 µg/mL and 8.5 µg/mL for all quantified active marker compounds, respectively. To demonstrate the applicability of the developed methods, two batches of Norwegian spruce resin samples were analyzed in three replicate samples.
  • Heiskanen, Ilmari (2021)
    Interest towards indoor air quality has increased for several decades from human health perspective. In order to evaluate the quality of indoor air in terms of volatile organic compound (VOC) levels, robust analytical procedures and techniques must be used for indoor air VOC measurements. Since indoor building materials are the greatest source of indoor VOC emissions, same kind of procedures must be used for analysis of emission rates from building materials and their surfaces. Theory part of this thesis reviews background of VOCs and human health, legislation and guideline values, common building materials with emissions and used sampling techniques/approaches for indoor air sampling and surface material emission rate sampling & analysis. Discussed sampling techniques include, for example, material emission test chambers, field and laboratory test emission cells, solid phase microextraction (SPME) fibre applications and Radiello passive samplers. Also new innovative approaches are discussed. Used common analysis instruments are Gas Chromatography (GC) with Mass Spectrometer (MS) or Flame Ionization Detector (FID) for VOCs and High-Performance Liquid Chromatography-Ultraviolet/Visible light detector (HPLC-UV/VIS) for carbonyl VOCs (e.g. formaldehyde) after suitable derivatization. Analytical procedures remain highly ISO 16000 standard series orientated even in recent studies. In addition, potential usage of new modern miniaturized sample collection devices SPME Arrow and In-tube extraction (ITEX) used in experimental part of this thesis are discussed as an addition to indoor air and VOC emission studies. The aim of the experimental part of this thesis was to develop calibrations for selected organic nitrogen compounds with SPME Arrow and ITEX sampling techniques and test the calibration with indoor and outdoor samples. A calibration was successfully carried out with SPME Arrow (MCM-41 sorbent), ITEX (MCM-TP sorbent) and ITEX (Polyacrylonitrile (PAN) 10 % sorbent) with permeation system combined with GC-MS for the following selected organic nitrogen compounds: triethylamine, pyridine, isobutyl amine, allylamine, trimethylamine, ethylenediamine, dipropyl amine, hexylamine, 1,3-diaminopropane, 1-methyl-imidazole, N, N-dimethylformamide, 1,2-diaminocyclohexane, 1-nitropropane and formamide. The overall quality of the calibration curves was evaluated, and the calibrations were compared in terms of linear range, relative standard deviation (RSD) % for accepted calibration levels and obtained Limits of Detection (LOD) values. Also, ways to improve the calibrations were discussed. The calibration curves were tested with real indoor and outdoor samples and quantitative, as well as semi-quantitative, results were obtained.
  • Kivinen, Anssi (2020)
    The analysis of volatile organics is growing by the year and there is a great interest in fast and simple sample preparation techniques. With solid phase micro-extraction, samples can be extracted non-destructively without a need for solvents. This is both cost effective and ecological, because even most eco-friendly solvents still cause strain on the environment. This thesis focused on studying the effect of extraction conditions on the extraction efficiency. The effect of different sorptive phase materials was tested as well. New single-step sample extraction and preparation method was developed for gas chromatographic mass spectrometric analysis. Three different sorptive phase materials were compared and the extraction conditions were optimized for each. The method developed was used to extract, analyze and determine unknown compounds from a butterfly specimen. Multiple extractions were performed from both headspace and with direct immersion. By progressively changing the extraction conditions, properties of the compounds such as volatility and polarity could be determined by their presence alone. Analysis was performed using with gas chromatography mass-spectrometer using electron ionization quadrupole mass detector in full scan mode.
  • Ilmarinen, Jenni (2023)
    Sizing agents are chemical additives used in paper and board making to improve hydrophobicity and to control the water penetration into the fiber network. This thesis reviews various analytical methods that have been reported to analyze three sizing agents: alkyl ketene dimer (AKD), alkenyl succinic anhydride (ASA), and rosin. Overview of the analytical methods includes gas chromatography, high-performance liquid chromatography, and Fourier transform infrared spectroscopy, along with newer techniques like ultraviolet-visible absorption spectroscopy and near infrared spectroscopy. These agents are analyzed from various paper products, like paper, process waters and dispersion. While the goal is to retain all added sizing agents within the paper or board, complete retention is not achievable, and some agents are present in process waters. Analyzing sizing agent levels in process waters allows for the evaluation of sizing agent retention. In the experimental section, Kemira Oyj's AKD analysis method for process waters from paper mills is updated. The hazardous and possibly carcinogenic extraction Solvent A is replaced with the greener and safer Solvent B. Sample preparation is improved, reducing analysis time from six hours to one. Additionally, a new high performance liquid chromatography – evaporative light scattering detector (HPLC-ELSD) method is introduced, capable of simultaneously analyzing AKD and hydrolyzed AKD (HAKD) in a single chromatogram. This is the first time a HPLC method is reported for analyzing HAKD from process waters. This method achieves 99% recovery rates with 0.2 ppm LOQ for both AKD and HAKD.
  • Youngren, Cristina (2023)
    Novichok nerve agents are persistent, highly toxic chemical weapons which were added to the Chemical Weapons Convention in 2020 after their use on civilians in England. The detection and characterization of Novichok nerve agents and the degradation products formed after their exposure to decontamination products can be accomplished through complementary instrumental analyses. Chromatographic methods such as LC-MS/MS can be utilized to qualitatively detect Novichok degradation products such as hydrolysates and LC-HRMS can provide information about their structure via the elemental composition and fragmentation pathways. By contrasting these data to spectroscopic techniques such as 1H and 31P NMR, structural elucidation of decontamination products is possible as well as the determination of the kinetics of the decontamination process itself. The literature review contains a summary of all published instrumental methods with which Novichok nerve agents, degradation products, biomarkers and adducts have been analyzed and the efficacy of those methods. In the experimental research, Novichok nerve agent A-234 was decontaminated via six different decontaminants and analyzed by LC-MS/MS to identify the mass spectra of the degradation products of each, followed by LC-HRMS analysis to determine the elemental composition and fragmentation patterns of the degradation products. The A-234 rate of hydrolysis kinetics were measured by 1H and 31P NMR spectroscopy in three of the decontaminants and when possible, two dimensional analysis was used to correlate the structural data from the chromatographic analysis. Lastly, the A-234 hydrolysate was derivatized via TMSDAM methylation for GC-MS/MS analysis after testing with two silylating and three methylating agents. Decontamination of A-234 was successful within 48 hours with three decontamination agents and complete hydrolysis was observed within 5 hours with an oxidizer-containing quaternary salt based decontamination agent.
  • Elliott, Todd (2019)
    An investigation into switchable polarity ionic liquids was carried out to find greener alternative substituents and still obtain a switchable polarity ionic liquid. First for fluorinated compounds (fluorinated alcohol and amine) with a non-fluorinated hydroxylamine to form a mixed carbamate, then replacing the superbase with a basic tertiary (or secondary) amine. The trigger molecule for switching polarity was CO2. It was found that O-hexylhydroxylamine was a suitable replacement for fluorinated ethanol and fluorinated ethylamine to work with DBU (superbase) to form a switchable polarity ionic liquid. The three amines of triethylamine (TEA), diisopropylethylamine (Hünigs base) and diisopropylamine (DIPA) were inconclusive or unsuccessful. Both TEA and DIPA require further alternative analysis for a conclusive result while Hünigs base was proven to be unsuccessful. These reaction products were characterised with 1H and 13C NMR and ReactIR spectral data. Synthesis of hydroxylamine was also approached for a greener improvement. A new synthesis method is demonstrated that is successful using water and methylamine in ethanol working on reaction equilibria. The new method proposed had a yield of 29.1%, while the patent literature method that used hydrazine monohydrate (which is highly toxic and unstable unless in solution) gave a yield of 54.3% of hydroxylamine. A secondary investigation was also undertaken in to basicity effects of caesium carbonate on the CO2 addition to aniline, with and without a superbase present. The superbase used was tertramethylguanidine (TMG). Aniline, p-nitroaniline and p-methoxyaniline were tested for CO2 addition by formation of an amide peak in ReactIR. There was formation of the amide peak with caesium carbonate, though not as much as with the already known TMG. A concentration series of caesium carbonate and TMG in aniline was also devised to observe the effect the added caesium carbonate had on the aniline-TMG system in absorbing CO2. This was also analysed using ReactIR spectra. It was seen generally that by increasing the concentration of both/either TMG/Cs2CO3 there is an increase in carbamate. However further concentration series data is required before a generalised rule can be defined.
  • Fu, Shu Yi Vicky (2022)
    Biomacromolecules are large particles found in biological fluids. The upregulations and downregulation of some biomacromolecules, such as extracellular vesicles (EVs) have been linked to cancer and infectious diseases. The study of these biological particles can help us in understanding the progression of those conditions better. Furthermore, studying naturally occurring biological molecules, e.g., immunoglobulin G (IgG), DNA, nucleic acids and glycoproteins can help us to gain more insight to important biological processes in the human body. The first part of this thesis is a literature review of monolithic columns in the separation of large biological molecules in liquid chromatographic and capillary electrochromatographic applications. Columns, including novel monolithic stationary phases, also known as monoliths, have been developed to counter some of the problems associated with the traditionally used packed beds in separation science. Monoliths have a unique structure of interconnecting porous channels, which allows faster separation with better resolution, reproducibility and mass transfer characteristics compared to packed beds. Organic-based polymer monoliths are the most widely used monolithic materials in biological applications, but the use of inorganic-based silica monoliths and hybrid monoliths have grown in the last couple of decades. Monolithic columns are versatile and they can be utilized in several chromatographic techniques, such as reversed-phase chromatography, affinity chromatography, ion-exchange chromatography, capillary electrochromatography and mixed-mode chromatography. Due to the growing interest, miniaturized monoliths e.g. in microfluidic devices, small capillaries and microarrays have been exploited to allow faster separation using sample volumes even as low as a few femtolitres. For higher sample throughput, monoliths in the format of 96-well plates, tips, sheets and disks have been introduced, especially for sample pre-treatment purposes. In the experimental part, affinity monolithic chromatography was employed for the isolation of lipoproteins and EVs in both exomere and exosome size range. The main function of EVs is transporting signal molecules from cell-to-cell to maintain homeostasis of the body. Low-density lipoprotein (LDL), very-low-density lipoprotein and chylomicrons are lipoproteins that transport different lipids in the human blood stream. The study of these particles is important because lipoproteins and especially LDL have been associated with atherosclerotic cardiovascular diseases. The experimental part of this thesis is focused on studying the feasibility of Convective Interaction Media (CIM) monoliths in disk (1.3 µm pores, 0.34 ml) and 96-well plate (2.1 µm pores, 0.1 ml) formats in purifying nanosized biomacromolecules from human plasma. The preparation of the affinity monoliths and the isolation of particles in the disk format was conducted following existing protocols and methods, which were modified for the monolithic 96-well plate. Six different monoclonal antibodies (mAbs), anti-CD9, anti-CD34, anti-CD61, anti-CD63, anti-CD81 and anti-CD82 were immobilized on the monolithic supports to target EVs. Anti-apoB100 mAb was used in targeting apolipoprotein B100 present on the surface of apoB100-containing lipoproteins. The isolation in the disk format was done using an on-line immunoaffinity chromatography – asymmetric flow field-flow fractionation method connected to ultraviolet, dynamic light scattering and diode array detectors. To compare the two different formats with different pore sizes in lipoprotein and EV isolation, the immobilization protocol and isolation conditions were optimized for the monolithic well plate. The isolation on the monolithic 96-well plate was done within 20 minutes, and the operation consumed three times less sample and buffer than in the disk format. Both monolithic formats were suitable for LDL isolation and the disks could also be used in EV isolation and separation. However, due to the larger pore size, EVs were found to be unstable in the monolithic wells.
  • Puumi, Jukka (2021)
    An overview on utilization of dual nickel/photocatalyst protocols to conduct aryl-heteroatom cross-coupling reactions is presented. Basic concepts of photocatalysis, including different relaxation pathways, the difference of singlet and triplet states, and parameters used to predict reactivity are first disclosed. The general components used in dual nickel/photocatalyst protocols are presented followed by the discussion on reactivity trends. The reactivity trends are compared with other common aryl-heteroatom cross-coupling protocols (Buchwald-Hartwig-, Ullmann- and Chan-Lam couplings) illustrating the general advantages and disadvantages of each cross-coupling method. The scope of different dual nickel/photocatalyst protocols are then explored, concentrating on cross-coupling of amines, alcohols/thiols and carboxylic acids. The developments in mechanistic understanding on the dual nickel/photocatalyst aryl-heteroatom cross-couplings in recent years are reviewed. It is concluded that photocatalytic single electron transfer-based cycles, proposed for a number of coupling protocols, are very unlikely to take place. It is made clear that, based on the current knowledge, two principle mechanism are reasonable: energy transfer or thermal Ni(I)/Ni(III) cycles. Problems concerning energy transfer mechanisms are also discussed. Finally, applicability of dual nickel/photocatalyst aryl-heteroatom cross-coupling for industrially significant transformations is briefly discussed.
  • Koivula, Juho (2021)
    Kirjallisuuskatsauksessa käydään läpi erilaisia menetelmiä C3-substituoitujen indolien synteeseihin 2-alkenyylianiliinityyppisistä lähtöaineista, joiden bentsyylinen asema oli substituoitu. Erityistä huomiota kiinnitetään menetelmiin, joiden reaktiomekanismeiksi ehdotettiin radikaalimekanismeja. Myös näitä ehdotettuja radikaalimekanismeja esitellään tutkielmassa. Kokeellisessa työssä tutkittiin C3-subsituoitujen indolien hapettavaa synteesiä hiilikatalyytin avulla. Lähtöaineina käytettiin bentsyylisesti aryylisubstituoituja 2-alkenyylianiliinijohdannaisia. Joidenkin lähtöaineiden typpeen oli kiinnitetty metoksipyridiini, jonka kiinnitystä varten kehitettiin Buchwald-katalyysi. Hiilikatalyysit tuottivat hyviä saantoja. Korkea elektronitiheys, etenkin aniliinin bentseenirenkaan ja/tai typen aromaattisen substituentin korkea elektronitiheys, oli eduksi. Reaktion mekanismin ehdotetaan alkavan hapettumisella radikaalikationiksi, ja näitä hapetuspotentiaaleja laskettiin aiemmin raportoidun menetelmän mukaisesti. Mikäli indolin 5-renkaan substituutiot (N1, C2, C3) olivat tarpeeksi samankaltaisia, korkea elektronitiheys, matala hapetuspotentiaali ja hyvä saanto korreloivat. Indolin 5-renkaan substituutio on kuitenkin merkittävämpi tekijä kuin hapetuspotentiaali ja/tai korkea elektronitiheys. Pyridiini typen suojaryhmänä toimi katalyysissä ja se onnistuttiin poistamaan helposti. Metoksipyridiini toimi katalyysissä hyvin, mutta sen kvantitatiivinen poistaminen ei onnistunut.
  • Känsäkoski, Silja (2023)
    Lignin is an abundant aromatic polymer found in renewable biomass sources such as trees and grasses. Lignin is largely formed as a side product in paper and pulping industries, and recent research has been trying to valorize it for value-added products such as fuels and chemicals through catalytic depolymerization. This thesis work consists of two parts: a literature review on lignin and it depolymerization methods and the experimental part where lignin is depolymerized, and the products are analyzed. In the literature review an overview of lignin, its structure and different sources is given. Furthermore, different extraction methods of lignin from the biomass source are reviewed, and more specifically the organosolv process is highlighted. Different products formed in the depolymerization of lignin are presented along with their applications. Depolymerization methods including pyrolysis, oxidative depolymerization, solvolysis and reductive depolymerization are reviewed. Finally, different metal catalysts, with a focus on molybdenum-based ones, used in reductive lignin depolymerization are presented. In the experimental part two molybdenum phosphide catalysts are synthesized and characterized. They are used in the depolymerization of fraunhoferk130 and GVL lignin using ethanolysis in a batch or autoclave reactor. The mass balance of product fractions and monophenol yields are presented. Monophenol yields ranged from 3.5 wt.% to 22.8 wt.%. Additional hydrogen pressure suppresses repolymerization and char formation but has negative impact on monomer yields so the true role of hydrogen gas remains unclear. Increasing reaction temperature led to smaller molar mass but higher char formation. The different catalysts used are compared in the results with the help of the monomer yields, mass balance and molar masses. Overall, the molybdenum-based catalysts showed promise as monomer yields were in lieu of those found in literature and can be synthesized with lower costs than noble metal catalysts.
  • Tynkkynen, Jere (2022)
    This paper features two parts; a literature review discussing the recent development in using electrochemical gas sensors for pollutant detection and the use of sensor nodes in real-life locations, and an experimental section focusing on the kinetic study of nitrogen containing compounds utilizing in-tube extraction device. Growing interest towards personal safety have led to development of low-cost electrochemical sensors for personal safety, indoor air quality and leak detection applications. Heterojunctions and light illumination have emerged as an effective way to improve sensor performance, but the selectivity of electrochemical sensors remains relatively poor. Multiple sensors can be combined to create ‘E-noses’ which significantly improve the selectivity and compound identification. These E-noses have been deployed in some indoor locations, either being stationary in sensor networks or moved around by a robot or drone. All approaches have benefits and caveats associated to them, with the differences between individual sensors limiting sensor network use, and slow response and recovery times limiting the use of moving sensors. A novel micropump system was constructed to be used in the active air sampling together with in tube extraction (ITEX) and thermal desorption gas-chromatography (TD-GC-MS). The repeatability of this method was tested in a kinetic study of 10 selected nitrogen containing compounds in a custom-built permeation chamber. The breakthrough times and volumes of the compounds were investigated. Kinetic modelling was successful for 9 out of the 10 compounds with 1 compound behaving significantly different from the rest. The breakthrough times were always over 20 minutes and breakthrough volumes were around the 1000 ml region. Reproducibility was tested with multiple ITEX’s and samples were taken from five indoor locations. Three of the tested compounds were found in some of the samples.
  • Gabbouj, Selma (2022)
    Chemical attribution encompasses the detection and characterization of compounds of interest to find signature impurity, isotopic, and elemental profiles, which can be used to link illegal material to specific manufacturers, stocks, precursors, synthetic routes, or geographical locations. Explosives have been increasingly used for criminal purposes world-wide due to the availability of explosive material, precursors, and synthesis instructions. Nitrate ester, nitramine, and nitroaromatic military explosives as well as homemade organic peroxides are examples from over 250 explosive materials listed in the 2020 Federal Register of the US Bureau of Alcohol, Tobacco, Firearms, and Explosives. The first part of the thesis is a literature review, which aims to 1) present published mass spectrometric (MS) and liquid chromatographic (LC) detection methods for explosives and 2) explore chemical attribution studies of explosives and related compounds, such as illicit drugs and chemical warfare agents. The second part presents the experimental research carried out at the Finnish Institute for Verification of the Chemical Weapons Convention (VERIFIN), which aims to 3) develop an analysis method for multiclass explosives using liquid chromatography-high resolution mass spectrometry (LC-HRMS) and 4) perform chemical attribution of the nitrate ester explosive pentaerythritol tetranitrate (PETN) from different sources by isotopic and impurity profiling. Multiclass explosives detection required optimization of MS parameters, such as lower ion transfer tube and vaporizer temperatures and negative ion detection mode, as well as introduction of additives into LC eluents to promote adduct formation. PETN, 1,3,5-trinitro-1,3,5-triazinane (RDX), 1,3,5,7-tetranitro- 1,3,5,7-tetrazocane (HMX), 2,4,6-trinitrophenyl-methylnitramine (tetryl), 2-amino-4,6-dinitrotoluene (2- ADNT), and 4-amino-2,6-dinitrotoluene (4-ADNT) were detected from a mixture as nitrate adducts. Optimal parameters for the isotopic profiling of PETN were found to be 500 000 resolution, 2E4 (5 %) automatic gain control (AGC) target, and 50 ms injection time. Student’s t-tests revealed statistically significant differences between oxygen isotope ratio (18O/16O) values of PETN from two different sources. However, lack of repeatability of the isotope ratio results was an issue. 7 different methods were tested for the impurity profiling of PETN. Samples were rather pure but clear differences in the high mass range (m/z 600–900) impurity profiles of the two types of PETN were discovered, leading to the conclusion that they are indeed from different sources. Tentative structures of PETN homologue derivatives were assigned to the impurities using MS2 fragmentation and literature. Based on the results of this work, LC-HRMS is suitable for impurity analysis even for pure samples, but not very efficient or practical for analyzing isotope ratios.
  • Martinmäki, Tatu (2020)
    Tiivistelmä – Referat – Abstract Molecular imaging is visualization, characterization and quantification of biological processes at molecular and cellular levels of living organisms, achieved by molecular imaging probes and techniques such as radiotracer imaging, magnetic resonance imaging and ultrasound imaging. Molecular imaging is an important part of patient care. It allows detection and localization of disease at early stages, and it is also an important tool in drug discovery and development. Positron emission tomography (PET) is a biomedical imaging technique considered as one of the most important advances in biomedical sciences. PET is used for a variety of biomedical applications: i.e. imaging of divergent metabolism, oncology and neurology. PET is based on incorporation of positron emitting radionuclides to drug molecules. As prominent radionuclides used in PET are of short or ultra-short half-lives, the radionuclide is most often incorporated to the precursor in the last step of the synthesis. This has proven to be a challenge with novel targeted radiotracers, as the demand for high specific activity leads to harsh reaction conditions, often with extreme pH and heat which could denature the targeting vector. Click chemistry is a synthetic approach based on modular building blocks. The concept was originally developed for purposes of drug discovery and development. It has been widely utilized in radiopharmaceutical development for conjugating prosthetic groups or functional groups to precursor molecules. Click chemistry reactions are highly selective and fast due to thermodynamic driving force and occur with high kinetics in mild reaction conditions, which makes the concept ideal for development and production of PET radiopharmaceuticals. Isotope exchange (IE) radiosynthesis with trifluoroborate moieties is an alternative labeling strategy for a reasonably high yield 18F labeling of targeted radiopharmaceuticals. As the labeling conditions in IE are milder than in commonly utilized nucleophilic fluorination, the scope of targeting vectors can be extended to labile biomolecules expressing highly specific binding to drug targets, resulting to higher contrast in PET imaging. A trifluoroborate functionalized prosthetic group 3 was synthetized utilizing click chemistry reactions, purified with SPE and characterized with HPLC-MS and NMR (1H , 11B-, 13C-, 19F-NMR). [18F]3 was successfully radiolabeled with RCY of 20.1 %, incorporation yield of 22.3 ± 11.4 % and RCP of >95 %. TCO-functionalized TOC-peptide precursor 6 was synthetized from a commercial octreotide precursor and a commercially available click chemistry building block via oxime bond formation. 6 was characterized with HPLC-MS and purified with semi preparative HPLC. Final product [18F]7 was produced in a two-step radiosynthesis via IEDDA conjugation of [18F]3 and 6. [18F]7 was produced with RCY 1.0 ± 1.0 %, RCP >95 % and estimated molar activity of 0.7 ± 0.8 GBq/µmol. A cell uptake study was conducted with [18F]7 in AR42J cell line. Internalization and specific binding to SSTR2 were observed in vitro.
  • Brasseur, Paul (2021)
    Plasmonic is an emerging field which has showed application for photocatlysis. Here we investigate a gold/platinum bimetallic catalytic system, and try to show how the catalytic properties of gold nanoparticles can be us to harvest visible light energy to increase the catalytic activity of platinum. Platinum being are rare and expensive metal, we also took the opportunity to find the optimal amount of catalyst to reduce platinum use. The catalyst is composed of a core spherical gold nanoparticles, of around 15 nm diameter. They were synthesized using an inversed Turkevich method, based on trisodium citrate, gold precursor salt and done in solution. Various amount of platinum was deposited on those nanoparticles using seeded growth method. The amount of platinum varied for single atoms to an atomic monolayer. This suspension of nanoparticles was deposited on ultrafine silica powder to be used for certain reaction and characterization. The material was characterized via several technics. UV-Visible and Diffuse Reflectance Spectroscopy were used to characterize its optical properties and showed a absorption peak around 524 nm characteristic of gold nanoparticles of this size. Imaging was done using electron microscopy (SEM and TEM) to study the morphology and showed monodisperse and spherical particles. The exact composition of the different catalyst were obtain using Atomic Emission Spectroscopy. The study was conducted by using reduction reaction as tests to investigate differences in conversion and selectivity under dark and monochromatic 525 nm and 427 nm light conditions. We chose to work on reduction of 4-nitrophenol, phenylacetylene and nitrobenzene, because they are widely used both in research and industry, and are easy to set up. Some catalyst showed good enhancement under 525 nm light, especially the one with the least amount of platinum. Different selectivity were also observed, indicating the presence of different reaction pathways under light conditions.