Inhalational cough challenges in the assessment of cough

Khalid, Saifudin

January 2013

Introduction: Cough is the commonest reason for which medical advice is sought. In assessment of chronic cough and in developing anti-tussive medications, inhalational cough challenges with capsaicin and citric acid are commonly employed. However the ability of these inhalational cough challenges to distinguish health and disease is not clear and it is not known which end point is best in making such assessments. Methods: Subjects belonging to five different categories (healthy volunteers, subjects with COPD, asthma, healthy current smokers and chronic cough) were compared with each another by using the standard cough challenges employing Capsaicin and Citric acid and also by using newer inhalational cough challenge agents such as prostaglandin E2 and bradykinin. In addition adaptation to repeated inhalations of tussive agents was also assessed. The relationship between the cough reflex sensitivity as gauged by using inhalational cough challenge tests and objective cough recording was explored in all five groups. Finally the change in C5 in Capsaicin evoked cough by using a substance to block TRPV1 channel and its effect on objective cough recording was assessed in subjects with chronic cough. Results: Different tussive agents have different abilities to distinguish between different diagnostic categories and a combination of inhalational cough challenge tests have a better accuracy of predicting diagnostic groups as compared to one on its own. There are significant differences in the rates of adaptation to repeated inhalations of PGE2 and there is a significant reduction in cough response over period of time in all disease groups. Using the TRPV1 antagonist resulted in a modest increase in the Log C5 concentration of capsaicin but this was not matched by a change in objective cough recording or CQLQ scores. Conclusions: The different abilities of tussive agents to distinguish between different diagnostic categories suggest that the information conveyed by the one inhalational cough challenge test is different from that by another test. The choice of the inhalational cough challenge test should therefore depend on which groups are included in the study. There was no significant difference in the rate of adaptation to prolonged challenge with citric acid or capsaicin and no significant correlation of the magnitude of adaptation with objective cough recording suggesting that this is unlikely to be responsible for the increased cough rates seen in diseases such as chronic cough, COPD or asthma. The TRPV1 antagonist did not result in a significant change in objective cough recording or CQLQ scores. The change in C5 with the TRPV1 antagonist was however modest and this may be reason for this study failing to show a relationship between these different measures.

616.2

Syntéza keramických materiálů na bázi Ca-Co-O systému / Synthesis of ceramic materials based on Ca-Co-O system

Žáková, Kateřina

January 2018

In this work synthesis of structure cobaltites based on Ca-Co-O system is discussed. As major way of synthesis was chosen citric acid method. The document is devided into theoretical and experimental part and also into discussion of observed results. Main focus of literary research is general utilization and function of thermoelectric materials, related thermoeletric effects according to structural defects in crystals. Also topic of cobaltite ceramics is described. Due to the fact that calcium-cobalt oxides are conductive, their use is point of interest in high-temperature and energy applications. During experiments differential thermal and thermogravimetric analysis (TG-DTA), X-Ray diffraction, heat microscopy and scanning electron microscopy were used.

Molecular Transportation in Polymer and Composite Materials: Barrier Performance and Mechanical Property Evaluation

Md Nuruddin (8738436)

21 April 2020

<p>Transport of gasses and liquids through polymers and composites is an important factor to be considered when designing a material for structure and packaging applications. For structural engineering applications, more focus has been given to the transportation of water, vapor and organic liquids rather than gases as diffusion of these liquids into the polymers and polymer-based composites can significantly lower service life. In addition, much attention has been given to the leaching of unreacted reactant molecules, solvents, additives, degradation products from the polymers and composites to the atmosphere (water, soil etc.). We studied the transport of volatile organic compounds and water in cured-in-place-pipe (CIPP) (a representative of FRPC) and gas permeability of highly engineered cellulose nanocrystals (CNC) films.</p> <p>Cured-in-place-pipe (CIPP) is a popular technology which uses fiber reinforced polymer composite to repair sanitary sewer, stormwater, and drinking water pipe. The liner is installed in the field and exposed to flowing water immediately after installation (curing of the liner) is done. Curing conditions dictate liner properties as undercured liners can contain unreacted styrene monomers, additives, degradation products. These agents can leach out and enter the environment (soil, water, air). The objective of this work was to investigate the curing behavior, volatile content, thermal stability of steam-cured and UV-cured CIPP liners collected from Indiana and New York installation sites. The liner specimens were also exposed to water and other aggressive environmental conditions (saltwater, concrete pore solution at 50 °C) to explore the leaching of unreacted styrene and other organic chemicals from the liners. The influence of transportation of water, salt solution and pore solution through liners on mechanical and thermo-mechanical properties was also examined to study the durability of the liners. Study suggested that the durability of the liners depends on the curing condition and exposed environment conditions.</p> <p>The function of polymer packaging materials is mainly to inhibit gas and moisture permeation through the films. Cellulose nanocrystals (CNCs) have drawn growing interest for the packaging due to their non-toxicity, abundance in nature, biodegradability and high barrier properties. The objective of this work was to corelate the alignment of CNC with free volume and barrier performance of the film. Furthermore, citric acid (CA) was added to the CNC suspensions with varying quantity to explore the effect of CA on coating quality and barrier performance of CNC coated polypropylene (PP) film. Study revealed that CA addition in CNC suspension can enhance the hydrophobicity and gas barrier performance of coated PP films while retaining the high optical transparency. </p>

volatile

cured-in-place-pipe

permeability

cellulose nanocrystals

stormwater

curing

Thermal Stability

mechanical

packaging

alignment

barrier performance

coating

citric acid

transparency

Příprava a charakterizace karbidů vybraných d a p prvků / Preparation and characterisation of selected d and p elements carbides

Nižňanský, Matěj

January 2020

This thesis is focused on carbide ceramics synthesis, more specifically on the synthesis of a Ti2AlC MAX Phase carbide using solution chemistry rather than powder metallurgy. Chloride and nitrate precursors have been used as a source of metals and citric acid as a source of carbon for carbothermal reduction and as a complexing agent. A new route of precursor synthesis has been developed based on peroxo-titanic acid, which helps retain aluminium. The syntheses were performed using the SPS facility to ensure high heating rates. Al4C3 and TiC carbides and their mixtures were prepared successfully. However, the Ti2AlC phase was not synthesized under used conditions. The phase composition, structure and grain sizes of the samples were investigated by powder X-ray diffraction, X-ray fluorescence and electron microscopy. The contents of carbon in the precursors were determined by thermogravimetric analysis.

Die Nutzung der Hefe Yarrowia lipolytica zur Produktion von Citronensäure aus nachwachsenden Rohstoffen

Förster, André

17 October 2006

Eine der für die biotechnologische Nutzung interessanten Eigenschaften der Hefe Yarrowia (Y.) lipolytica ist ihr Vermögen, unter bestimmten Kultivierungsbedingungen große Mengen an organischen Säuren, darunter auch Citronensäure (CS), ins extrazelluläre Medium zu sekretieren. Aufgrund ihrer Apathogenität, ihres breiten Substratspektrums und ihrer guten molekulargenetischen und verfahrenstechnischen Handhabbarkeit, stellt sie einen idealen Mikroorganismus zur biotechnologischen Gewinnung von Citronensäure dar. Bei der durch eine Stickstofflimitation ausgelösten Überproduktion von CS mit Y. lipolytica kommt es parallel auch zur Ausscheidung von Isocitronensäure (ICS), deren Anteil am Gesamtsäureprodukt in Abhängigkeit von der C-Quelle in Wildtypstämmen zwischen 10 % (Glucose, Saccharose, Glycerol) und 40-55 % (Pflanzenöle, Alkan) liegt. In der Literatur beschriebene Mutantenstämme von Y. lipolytica besitzen ein von Wildtypstämmen abweichendes Produktmuster und können sowohl weniger (2-5 % auf Glucose, 5-10 % Alkan und Pflanzenöl) als auch mehr ICS (15-35 % Glu¬cose, 65-75 % Alkan, Ethanol bzw. Pflanzenöl) sekretieren. Die gezielte Überexpression des für die Isocitratlyase codierenden Gens ICL1 durch die Erhöhung der Kopiezahl führte zu einer drastischen Erhöhung der Enzymaktivität in den entsprechenden ICL1 multicopy Transformanden (10-15fach gegenüber Wildtyp) aufgrund des Gen-Dosis-Effektes. Auf den getesteten hydrophilen C-Quellen Glucose, Glycerol und Saccharose verringerte sich der ICS-Anteil von durchschnittlich 10-12 % auf 3-5 %, auf den hydrophoben C-Quellen Hexadecan und Sonnenblumenöl sogar von durchschnittlich 40-55 % auf Werte um 5-10 %. Im Ergebnis dieser Untersuchungen entstand ein Patent (DE10333144A1), welches ein Verfahren zur Gewinnung von CS mit einer genetisch veränderten Hefe Y. lipolytica beschreibt. Die Zerstörung des Leserahmens des ICL1 Gens in Mutantenstämmen bewirkte das Ausbleiben der Synthese einer funktionell aktiven Isocitratlyase, was den Verlust der Fähigkeit zur Verwertung gluconeogenetischer C-Quellen wie Ethanol, Alkan und Pflanzenölen zur Folge hatte. Auf Glucose bzw. Glycerol zeigten diese Mutantenstämme im Vergleich zum Wildtypstamm jedoch nur eine geringe Erhöhung des ICS-Anteils um durchschnittlich 2-5 Prozentpunkte. Die Zerstörung des Leserahmens des IDP2 Gens, codierend für die NADP-abhängigen Isocitratdehydrogenase, führte zur Glutamat-Auxotrophie des entsprechenden Mutantenstammes auf allen getesteten C-Quellen. In der Produktbildung zeigte diese Mutante im Vergleich zum Wildtypstamm eine Verringerung des ICS-Anteils um durchschnittlich 2-4 Prozentpunkte. Es konnte gezeigt werden, dass Saccharose ein geeignetes Substrat zur Gewinnung von CS mit rekombinanten Stämmen von Y. lipolytica darstellt, die das für die Invertase codierende SUC2 Gens aus Saccharomyces cerevisiae exprimieren. Natürlicherweise kann Y. lipolytica diesen Zucker aufgrund des Fehlens des Enzyms Invertase nicht verwerten. Im Schüttelkolben wurden aus 100 g/l Saccharose unter nicht optimierten Bedingungen bereits 56 g/l CS+ICS gewonnen. Nach der Optimierung durch die Reduktion des für die Invertaseexpression durch pXPR2 notwendigen Peptonanteils von 1,7 auf 0,4 g/l erhöhte sich die Produktkonzentration auf 77 g/l. Die Übertragung des Produktionsprozesses in den Bioreaktor hatte die Verdopplung der Produktbildungsraten (RZA von 0,4 auf 0,85 g/l*h, r von 46 auf 89 mg/g*h) zur Folge, bedingt durch die Aufhebung der Sauerstofflimitation. Die Steigerung der Invertaseaktivität, die sich unter Bioreaktorbedingungen als ein Limi¬tationsfaktor her¬ausstellte, konnte durch die Anhebung des pH-Wertes von 5,0 auf 6,0 bzw. 6,8 er¬reicht werden. Dadurch konnten die Produktbildungsrate RZA um bis zu 80 % von 0,42 auf 0,76 g/l*h, die biomassespezifische Produktbildungsge¬schwin¬digkeit r um bis zu 70 % von 0,06 auf 0,1 g/g*h und die Ausbeute um bis zu 64 % von 0,5 auf 0,82 g/g gesteigert werden. Einen weiteren Limitationsfaktor für den CS-Bildungsprozess aus Saccharose stellt bei ausreichender Invertaseexpression offenbar die Aufnahme von Glucose und Fructose dar. Die Hefe Y. lipolytica zeigte höchste Produktbildungsraten aus Pflanzenölen, wie Sonnenblumen- oder Rapsöl, als nachwachsende Rohstoffe. Um zu prüfen, ob die Produktivität der CS-Bildung aus Pflanzenölen mit Y. lipolytica gesteigert werden kann, sollte die Triglyceridverwertung durch die Erhöhung der extrazellulären Lipaseaktivität verbessert werden. Dazu wurden zum einen Insertionsmutantenstämme, die auf eine erhöhte extrazelluläre Lipaseaktivität im Plattentest hin selektiert wurden, charakterisiert. Zum anderen wurde das für die extrazelluläre Lipase codierende LIP2 Gen in Y. lipolytica überexprimiert. Die erhaltenen LIP2 multicopy Transformanden zeigten eine bis zu 400fach erhöhte Lipaseaktivität im Vergleich zum Wildtypstamm (von 400 U/l auf bis zu 150000 U/l). Eine Verbesserung der Triglyceridverwertung aufgrund der Erhöhung der extrazellulären Lipaseaktivität in den untersuchten Insertionsmutanten und LIP2 multicopy Transformanden wurde nicht festgestellt. Die erhaltenen Daten für die Produktbildungsrate RZA (0,9-1,1 g/l*h), die biomassespezifische Produktbildungsgeschwindigkeit r (0,08-0,14 g/g*h) und die Ausbeuten (1,3-1,5 g/g) waren innerhalb der untersuchten Stämme vergleichbar und ließen keine verbesserte Produktbildung erkennen. Der geschwindigkeitsbestimmende Schritt liegt offenbar nicht bei der Hydrolyse der Triglyceride durch Lipasen, sondern bei der Aufnahme und dem Transport der Fettsäuren und/oder deren Katabolismus.

info:eu-repo/classification/ddc/540

ddc:540

Vliv antidepresiv a depresivní poruchy na mitochondriální funkce / Effects of antidepressants and depressive disorders on mitochondrial functions

Hroudová, Jana

January 2012

Mood disorders are serious diseases. Nevertheless, their pathophysiology is not sufficiently clarified. Biological markers that would facilitate the diagnosis or successful prediction of pharmacotherapy are still being sought. The aim of the study was to find out whether mitochondrial functions are affected by antidepressants, mood stabilizers and depression. Our research is based on recent hypotheses of mood disorders, the advanced monoamine hypothesis, the neurotrophic hypothesis, and the mitochondrial dysfunction hypothesis. We assume that impaired function of mitochondria leads to neuronal damage and can be related to the origin of mood disorders. Effects of antidepressants and mood stabilizers on mitochondrial functions can be related to their therapeutic or side effects. In vitro effects of pharmacologically different antidepressants and mood stabilizers on the activities of mitochondrial enzymes were measured in mitochondria isolated from pig brains (in vitro model). Activity of monoamine oxidase (MAO) isoforms was determined radiochemically, activities of other mitochondrial enzymes were measured spectrophotometrically. Overall activity of the system of oxidative phosphorylation was measured electrochemically using high- resolution respirometry. Methods were modified to measure the same...

Joint project: Geochemical retention of radionuclides on cement alteration phases (GRaZ) - Subproject B

Schmeide, Katja, Philipp, Thimo, Wolter, Jan-Martin, Kretzschmar, Jérôme, Dullies, Paul, Lippold, Holger, Schymura, Stefan, Stumpf, Thorsten

23 June 2021

The report summarizes the results obtained by the Institute of Resource Ecology of the Helmholtz-Zentrum Dresden-Rossendorf within the BMWi-financed Joint Research Project “Geochemical retention of radionuclides on cement alteration phases (GRaZ)”. The project focused on the retention behavior of Ca-bentonite and cementitious material, both constituents of the geo-engineered barrier of deep geological repositories for high-level radioactive waste, towards radionuclides. Specifically, the influence of increased salinities and of hyperalkaline conditions on interaction processes in the system radionuclides – organics – clay/cementitious materials – aquifer was studied. For this purpose, complexation, sorption and desorption studies were performed at alkaline to hyperalkaline pH conditions (pH 8-13) and under variation of the ionic strength (0.1 to 4 M) applying complex solution compositions. For the U(VI) citrate system molecular structures dominating in the pH range 2-9 were studied spectroscopically (NMR, UV-Vis, FT-IR). As dominating species 2:2, 3:3, 3:2 and, above critical concentrations also 6:6 and 9:6 U(VI) citrate complexes were identified or confirmed and complex formation constants were determined. U(VI) sorption on Ca-bentonite at (hyper)alkaline conditions in mixed electrolyte solutions was studied by means of batch sorption experiments. The U(VI) retention on Ca-bentonite was shown to be very effective at pH>10, even in the presence of carbonate and despite the prevalence of anionic aqueous uranyl species. The presence of two independent U(VI) surface complexes on Ca-bentonite at pH 8-13 was shown by site-selective TRLFS and EXAFS spectroscopy. The sorption of anionic uranyl hydroxide complexes to the mineral surface was shown to be mediated by calcium cations. In further experiments, the effect of isosaccharinic acid (ISA) and polycarboxylate ether (PCE) on U(VI) and Eu(III) sorption, respectively, on Ca-bentonite was studied. An effect of ISA on U(VI) sorption on Ca-bentonite only occurs when ISA is present in very high excess to U(VI). The effect of PCE, as a commercial cement superplasticizer, on Eu(III) sorption onto Ca-bentonite was negligible already at moderate ionic strengths. The retention of U(VI) and Cm(III) by various C-(A-)S-H phases, representing different alteration stages of concrete, was studied by batch sorption experiments. Sorbed or incorporated actinide species were identified by TRLFS. The stability of U(VI) and Cm(III) doped C-(A-)S-H phases at high ionic strengths conditions was studied in solutions simulating the contact with North German claystone formation water. Potential changes of actinide speciation as well as formation of secondary phases due to leaching effects were followed spectroscopically. The results of this project show that both bentonite and cementitious material constitute an important retention barrier for actinides under hyperalkaline conditions and increased ionic strength.

Effects of Natural Antioxidants on Lipid Oxidation of Menhaden Oil

Baek, Naerin

25 January 2013

Preventing oxidative deterioration of fish oil is a significant challenge for the food industry. Natural antioxidants are widely incorporated into foods and oils to prevent oxidation and extend shelf life. The goal of the study is to investigate the activity of novel antioxidants in menhaden oil and to develop optimum formulations containing mixed tocopherols to control oxidation of menhaden oil. Alpha tocopherol, gamma tocopherol, and delta tocopherol in menhaden oil were found at 0.18mg/g, 0.37mg/g, and 0.14mg/g, respectively, using HPLC analysis. Teng Cha extract effectively delayed oxidation of menhaden oil (MO) when stored at 40°C for eight days by measuring primary oxidation products and secondary oxidation products. The combinations of Teng Cha extract and rosemary extract and combinations of ascorbyl palmitate, citric acid, Teng Cha extract and rosemary extract more effectively improved stability of MO containing mixed tocopherols than Teng Cha extract alone at 40°C storage for eight days by measuring primary oxidation products and secondary oxidation products. From this study, Teng Cha extract can be used as a potential natural antioxidant in food industry, especially in combinations with rosemary extract and tocopherols, extending shelf life of menhaden oil. / Master of Science in Life Sciences

Natural antioxidant

menhaden oil

Oxidation

tocopherol

Teng Cha extract

rosemary extract

ascorbyl palmitate

citric acid

HPLC

Oxidation products--Primary

Oxidation products--Secondary

NMR Spectroscopic Investigation of Lanthanide, Actinide, and Selenium Containing Complexes Related to the Environment or Nuclear Waste Disposals

Kretzschmar, Jerome

27 May 2019

The ultimate goal of this work is providing insights into fundamental (physico-) chemical (redox) behavior of hexavalent uranium (U(VI)), trivalent europium (Eu(III)) and selenium (Se), and upon their interaction with ubiquitous small biomolecules (in case of U(VI) and Eu(III)) or alkaline earth metal ions (in case of Se(IV) and Se(VI)) by application of Nuclear Magnetic Resonance (NMR) spectroscopy. NMR spectroscopy is a powerful method proving its usefulness also to environmental and nuclear waste related studies in aqueous solutions by determination of (potential) binding sites, molecular structures (even conformation and configuration) as well as intra- and intermolecular dynamics, (redox) reaction pathways and mechanisms. The present work comprises extensive NMR spectroscopic investigations in aqueous (D2O) solutions on (i) glutathione (GSH) and glutathione disulfide (GSSG) interactions with trivalent lanthanides (Ln(III), particularly Eu(III)) and U(VI), (ii) molecular structures of citrate (Cit) complexes of U(VI), and their reactions upon light-irradiation, as well as (iii) pH- and temperature-dependent speciation of selenium oxyanions, i.e., Se(VI) (selenate) and Se(IV) (selenite and, notably, hydrogen selenite) as well as Se(VI) and Se(IV) interaction with alkaline earth metal ions. These investigations are supported by time-resolved laser-induced fluorescence spectroscopy (TRLFS), ultraviolet-visible-near infrared (UV-Vis-NIR), IR/Raman, and extended X-ray absorption fine structure (EXAFS) spectroscopy, transmission electron microscopy (TEM), as well as quantum chemical calculations on density functional theory (DFT) level. For NMR spectroscopic data on GSH/GSSG complexation towards both Eu(III) and U(VI) are lacking, the herein presented results are new, and nicely complement other spectroscopic studies. Ln(III) complexes of GSH are characterized by their high solubility at least up to 300 mM and pD 5. However, the formation constant of the Eu(III)–GSH 1:1 complex is quite low with log K = 1.71 ± 0.01 as determined by Eu(III)-TRLFS. The diamagnetic La(III) and Lu(III) showed only little effect on the NMR spectra (< 2 ppm) while analogous Eu(III) solutions revealed hyperfine shifts up to 40 ppm. Eu(III)-induced 1H chemical shift changes are solely upfield and attributed to be predominantly due to pseudocontact contribution caused by dipolar interaction. In contrast, Eu(III)-induced 13C chemical shift changes of adjacent atoms – at least for the carboxyl and α-carbons – show alternating signs, indicating spin polarization effects owing to contact contribution. As expected for hard LEWIS acids and shown by other spectroscopies, complexation facilitates by the carboxyl groups. Qualitative differences between the glutamyl and glycyl carboxylate in metal ion complexation are ascribed to COULOMB repulsion due to the positively charged NH3+ in direct vicinity. Investigations of the U(VI)–GSH system covered experiments under both oxidizing and reducing conditions, performed with GSH’s oxidized form, GSSG, at ambient conditions, while samples with reduced GSH were handled under N2 atmosphere. For either condition, U(VI) showed interaction in aqueous (D2O) solution with both GSH and GSSG as determined by U(VI)-induced 1H and 13C chemical shift changes and U(VI) TRLFS, the latter comprising measurements at 25 °C and –120 °C. In principle, the interactions are stronger as compared to the Ln(III) system, and the speciation in both solution and solid is more complex owing to the aqueous chemistry of uranium. Observed binary GSH complexes are [UO2(H2GSH)]2+ for pD values up to ≈ 2.3, and [UO2(HGSH)]+ predominating for pD > 2.3. Complementary to the Eu(III) results, whenever net neutral binary GSH/GSSG or ternary hydroxo GSH/GSSG U(VI) complexes form in solution, both these U(VI) systems revealed extensive precipitation because of the low solubility of these complexes. Binary U(VI) GSSG and ternary U(VI) hydroxo GSSG complexes yield solid phases from pD 2 through 8, even in carbonatic media. The largest quantities of aqueous GSSG–U(VI) complexes are observed for pD ≈ 3.5, with the association constant for pH 3 determined by TRLFS as log K = 4.81 ± 0.08 for a 1:1 complex. GSH cannot compete with hydroxo ligands for complexation as of pD 6, whereas GSSG can at least partially compete with hydroxo and carbonate ligands upon formation of both quaternary U(VI) hydroxo carbonate GSSG, and ternary U(VI) carbonate GSSG (poly-)anionic species of high solubility. Under reducing and near-neutral conditions (pD 6 – 9) GSH immediately reduced U(VI) with subsequent formation of nanocrystalline UO2+x. After centrifugation of the starting material and allowing the decanted supernatant to age, the dissolved nanocrystals assemble network-like as disclosed by TEM, and further analysed by selected-area electron diffraction (SAED), energy-dispersive X-ray (EDX) and UV-Vis spectroscopy, revealing hyper-stoichiometric UO2+x phases. Such network-like assembled actinide containing nanocrystals, with the arrangement most likely provoked by the presence of GSSG, have never been shown before. Complementary, the precipitate that has also been allowed to age as a wet paste, showed color changes from yellow via olive to black, indicating a reaction to proceed. The repeatedly probed and dissolved material exhibited GSSG in NMR spectra, and UV-Vis-NIR absorption bands attributed to U(IV) and, notably, U(V), the latter implying a one-electron transfer with subsequent disproportionation of U(V) to U(IV) and U(VI). Therefore, obtained results advance the understanding of both fundamental redox behavior of uranium and the role of GSH (and related molecules) in U(VI) detoxification processes in vivo. Although investigated for over 70 years, there are still controversial discussions on both speciation and structures of U(VI)–Cit complexes. By means of NMR’s strength in both structure determination and sensitivity to dynamic processes, studies regarding the U(VI)–Cit system allowed further fundamental insights into the structures of the formed complexes on a molecular level. Upon complexation a chiral center is induced in Cit’s central carbon, resulting in the formation of two diastereomeric pairs of enantiomers, whereupon the dimeric complexes exhibit syn and anti configured isomers. In fact, the combination of 17O NMR (note: at natural abundance) and quantum chemical calculations allowed an unambiguous decision on complex geometry and overall configurations. It is evidenced for the first time that the syn isomer is favored in aqueous solution in contrast to the preferably crystallizing anti isomer. Both isomers coexist and interconvert among one another, with a rate estimated to be in the order of 102 s–1 at 25 °C in acidic media, and a corresponding activation energy of approximately 60 kJ mol–1. Moreover, clear indications for uranium chirality is observed for U4+, with the 1:1 U(IV)–Cit complexes also forming two diastereomeric pairs of enantiomers. Comprehensive spectroscopic experiments combined with quantum chemical calculations improved basic understanding of the photo-reaction mechanism in the U(VI)–Cit system. Regardless of sample conditions, Cit is degraded to β-ketoglutarate, acetoacetate, and acetone, while U(VI) was reduced to U(IV) at pD 2 and U(V) at pD 5, suggesting a two- and a one-electron transfer, respectively. NMR signals observed for pD 5 samples at remarkable 1H chemical shift values between 25 and 53 ppm, in combination with UV-Vis-NIR absorptions at about 750 and 930 nm, are assigned to U(V) complexes of citrate. With regard to reported pH dependence on reaction rate and yield in the literature combined with observations in this work, H+/D+ are considered mechanistically crucial constituents. Furthermore, the photoreaction proceeds intermolecularly, requiring for free Cit to be present in solution. In consideration of both the U(VI)–Cit photoreaction and the U(VI)–GSH chemical redox reaction, regardless of the particular mechanism, in both cases the process is intermolecular. This is not only a highly interesting, but the more a very important result, rendering the reductants not required to be bound to U(VI) in order to reduce it. Owing to the suitability of 77Se as NMR-active but non-radioactive Se isotope, this spectroscopy was also applied to study chemical behavior of the nuclear waste related long-lived 79Se. For the first time spectroscopic evidence is given for hydrogen selenite dimerization in aqueous solution upon formation of homo-dimers by hydrogen bonding that are stable up to 60 °C and so are other selenium oxyanionic species. Additionally, a remarkably higher 77Se chemical shift temperature coefficient of the dimer – as compared to corresponding selenite and selenous acid – was found. These findings are attributed to a significant deshielding upon heating due to remarkably different rovibrational modes upon stretching the dimer as a whole instead of its dissociation into monomers owing to the rather strong hydrogen bonds. Interaction of selenium oxyanions with ubiquitous alkaline earth metals, i.e., Ca2+ and Mg2+, showed formation of weak aqueous complexes of both selenite and hydrogen selenite dimer for excessive selenium, however, at high ionic strength (5.6 M) for equimolar Ca2+ and Se(IV) even at pHc 5 crystalline calcium selenite is formed.

info:eu-repo/classification/ddc/540

ddc:540

Regulation of Stomata Opening in the Crassulacean Acid Metabolism Plant Kalanchoe Laxiflora

Albader, Anoud Abdulmalik

08 December 2017

Stomata are small pores that are located on the surface of epidermal leaves, and they can regulate the uptake of CO2 and prevent water lose by opening and closing the pores. Stomata of plants can be regulated by external condition such as CO2, biotic and abiotic stresses and internal factors. CAM (crassulacean acid metabolism) plants adapt to hot and dry environments by closing stomata during the day and opening stomata during the cool night. However, it is still unclear how CAM plants open their stomata during the night and close them during the day. In this study, a number of factors were evaluated for their potential roles in promoting stomatal opening in the model CAM plant Kalanchoe laxiflora. Citrate is an important organic acid and it accumulates during the night in CAM plants. It is shown in this study that citrate promoted stomatal opening in detached leaf epidermis of Kalanchoe laxiflora. Further, the cytokinin zeatin is also shown to stimulate stomatal opening in detached leave of Kalanchoe laxiflora. Melatonin is an important regulator of circadian rhythms in mammals and has been implicated in regulation of plant abiotic stress responses. Melatonin was detected in the leaves of Kalanchoe laxiflora. It promoted stomatal opening in detached epidermis of Kalanchoe laxiflora. Together, these results suggest that stomata of Kalanchoe laxiflora respond to citrate and malate which are the main organic acids accumulate during nighttime and also to some signaling molecules (zeatin, melatonin, and serotonin) by opening stomata during dark period.

malic acid

citric acid

malate dehydrogenase

phosphoenolpyruvate carboxylase

RUBISCO

Native gel electrophoresis

preparation of epidermal strip

Indole Acetic Acid

cytoplasmic NADP-malic enzyme

potassium

measurements of aperture size

vacuole