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Biospeciation and antidiabetic effects of oxidovanadium(IV) complexesUgirinema, Vital January 2014 (has links)
The syntheses of bis(1R-imidazole-2/4-carboxylato)oxidovanadium(IV) complexes was successfully carried out and the complexes were isolated in the solid state. The coordinated water was confirmed by elemental analyses, and single crystal XRD. The complexes were therefore distorted octahedral rather than square planar due to the coordination of water at the sixth position. The reaction of the vanadyl ion (VO2+) with imidazole-4-carboxylic acid (Im4COOH), imidazole-2-carboxylic acid (Im2COOH) and methylimidazole-2-carboxylic acid (MeIm2COOH), respectively, in the presence of small bioligands (bL) [oxalate (Ox), lactate (Lact), and phosphate (Phos)] and high molecular weight (HMM) human serum proteins [albumin (HSA) and transferrin (hTf)] were studied in aqueous solution using potentiometric acid base titrations under oxygen and carbon dioxide–free conditions. The data obtained from these titrations was used to calculate the binary and ternary stability constants using the programme HYPERQUAD. The overall stability constants for VO2+-L-Ox system (log β1111 = 18.9, 18.79 and 19.86), VO2+-L-Lact system (log β1111 = 21.83, 20.98 and 22.86), and VO2+-L-Phos system (log β1111 = 27.35, 24.16 and 27.42) (for L= Im4COOH, Im2COOH and MeIm2COOH, respectively) were obtained. The species distribution diagrams showed that under physiological pH the following ternary and quaternary species; [(VO)L(bL)], and [VO(L)(bL)(OH)], would dominate provided that the competition with serum proteins is not too strong. These species were also confirmed by HPLC, LC-MS and EPR. The overall stability constants for the VO2+-L-HSA system (log β2,1,1,0 = 24.3, 23.7 and 24.7), and for the VO2+-L-hTf system (log β2,2,1,0 = 31.1, 30.8, 36.4 for L = Im4COOH, Im2COOH and MeIm2COOH, respectively), suggesting stronger binding of transferrin. The formation constants for the formation of binary (VO(IV) and the proteins) were 9.1 and 13 for log β11, and 20.9 and 25.2 for β12, for human serum albumin and human serum transferrin respectively. The species distribution diagrams for the proteins (HMM) with oxidovanadium(IV) under physiological pH was dominated by VO(HMM)2, VOL(HMM) for unsubstituted Im4COOH and Im2COOH, however, for the N-substituted MeIm2COOH, the species distribution diagrams under physiological pH, were dominated by VOL2, VO(HMM)2 and VO2L2(HMM). These species were further confirmed by HPLC, MALDI-TOF-MS and EPR. The glucose stimulated insulin secretion (GSIS) action of the complexes was investigated using INS-1E cells at 1μM concentration which was established through cytotoxicity studies via the MTT assay. The vanadium salt (VOSO4), cationic vanadium(IV) complex ([VO(MeImCH2OH)2]2+) were also included in the GSIS study in addition to the three neutral complexes [VO(Im4COO)2, VO(Im2COO)2 and VO(MeIm2COO)2] for comparison. The neutral complexes, especially VO(MeIm2COO)2, showed promising results in the stimulation of insulin secretion than the cationic complex and the vanadium salt.
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Vanadium-51 solid-state magic angle spinning NMR spectroscopy of vanadium haloperixodases and oxovanadium (V) haloperoxidase mimicsPooransingh-Margolis, Neela. January 2006 (has links)
Thesis (Ph.D.)--University of Delaware, 2006. / Principal faculty advisor: Tatyana Polenova, Dept. of Chemistry & Biochemistry. Includes bibliographical references.
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Synthesis and characterisation of novel oxovanadium(IV) Schiff base complexes: A study of their electronic spectral properties, peroxide binding affinities, DFT-calculated geometries and spectra, and cytotoxicity towards human carcinoma cells.Bartlett, Malcolm Alan. January 2012 (has links)
A series of five, tetradentate Schiff-base ligands were synthesised and chelated to vanadyl to form
oxovanadium(IV) complexes. The ligands, 4,4’-{benzene-1,2-diylbis[nitrilo(1E)phen-1-yl-1ylidene]}-
dibenzene-1,3-diol (H2L1), 4,4’-{ethane-1,2-diylbis[nitrilo(1E)phenyl-1-yl-1-ylidene]}dibenzene-1,3-diol
(H2L2), 4,4’-{propane-1,2-diylbis[nitrilo(1E)phen-1-yl-1-ylidene]}dibenzene-1,3-diol (H2L3), 4,4’-{(2-
hydroxypropane-1,3-diyl)bis[nitrilo(1E)phen-1-yl-1-ylidene]}dibenzene-1,3-diol (H2L4) and 4,4’-{2,2-
dimethylpropane-1,3-diyl)bis-[nitrilo(1E)phen-1-yl-1-ylidene]}-dibenzene-1,3-diol (H2L5), characterised by
TOF-MS, IR, electronic absorption, 1H and 13C NMR spectroscopy. The ligand H2L5 was also characterised
by XRD. The ligands were shown to have a bis-zwitterionic structure in the solid state, and possibly also in
solution. Complexes were characterised by Elemental Analysis, TOF-MS, IR, electronic absorption spectra,
EPR and 51V NMR spectroscopy. They form mononuclear complexes, with one ligand binding a single
vanadyl ion.
EPR spectroscopy was performed on both the powdered form and solutions of the complexes. All the
complexes displayed axial symmetry, with increasing distortion from an ideal square pyramidal geometry
as the size and bulk of the central chelate ring was increased. Isotropic g0 values suggest solvent
interaction with the vanadium ion for the coordinating solvent DMSO. Additional distortion on the
coordination geometry, presumably from the benzyl groups of the compounds, causes the isotropic
hyperfine coupling constants to be greater than expected.
Furthermore, the ability of the complexes to bind peroxide species was investigated by following the
addition of H2O2 to the complexes using 51V NMR spectroscopy to observe shielding changes at the
vanadium nucleus, and 1H NMR spectroscopy to monitor the bulk magnetic susceptibility, via a modified
Evan’s NMR method. Similar experiments were done with sodium hydroxide for comparison. As expected,
the oxoperoxovanadium(V) complexes were more stable than their progenitor oxovanadium(IV)
complexes. Additionally, increasing the distortion from the ideal pseudo square-pyramidal coordination
geometry for the vanadyl ion resulted in a greater increase in the apparent stability of the peroxocomplexes.
This latter effect is further enhanced by the addition of a hydrogen-bonding group in close
proximity to the vanadium nucleus.
DFT calculations of the optimized geometries, natural bond orbitals, electronic absorption and infra-red
frequencies were performed for both the ligands and the complexes; nuclear magnetic resonance
calculations were performed for the ligands as well. The B3LYP/6-311G (d,p) and B3LYP/LANL2DZ level of
theories were used for the ligands and complexes respectively, except for electronic transitions, which
were calculated using TD-SCF methods for both ligands and complexes. Calculated and experimental
results were compared where possible, and showed reasonable agreement for all calculations performed.
The exception to this was for the NMR calculations for the ligands, which were poorly simulated.
Finally, the in vitro biological activity of the complexes was evaluated for cytotoxicity against the human
tumour cell lines: A549, U251, TK-10 and HT29, via an MTT assay. All complexes showed promising
anticancer activity, as evidenced by their low IC50 values for the cell lines A549, U251 and TK-10, which are
in general, lower than that observed for cisplatin. They did, however, express negligible activity against
the HT29 colon adenocarcinoma cell line; showing an apparent selectivity for certain cell lines. These
oxovanadium(IV) complexes, thus warrant further evaluation as chemotherapeutic agents. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2012.
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Magnetic Exchange in Oxovanadium(IV) Complexes with N-Salicylideneamino AcidsHu, James Hung-Jen 01 1900 (has links)
Copper(II) and oxovanadium(IV) ions resemble one another magnetically in having one unpaired electron in their complexes irrespective of their geometrical structures and bond types involved. Copper(II) complexes with antiferromagnetic exchange are well known. On the contrary, antiferromagnetic exchange in oxovanadium(IV) complexes is rather new and not well established. Very few oxovanadium(IV) complexes have been reported to have this anomalous magnetic property. In the investigation of the magnetic properties of oxovanadium(IV) complexes, we have successfully prepared two series of new oxovanadium(IV) complexes with N-salicylideneamino acids.
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Regulation and chemotherapeutic targeting of human Cdc25A phosphataseScrivens, Paul James. January 2007 (has links)
No description available.
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Regulation and chemotherapeutic targeting of human Cdc25A phosphataseScrivens, Paul James. January 2007 (has links)
The Cdc25 phosphatases are highly conserved from yeast through humans and play pivotal roles in regulating the activities of cyclin-dependent kinases (Cdks). Cdc25A is one of three human Cdc25 family members, and has previously been shown to be overexpressed in numerous cancers and to transform rodent fibroblasts. Cdc25A therefore represents a rational target for chemotherapeutic development. Further, a thorough understanding of its biology and regulation in normal and transformed cells may facilitate the development of strategies to specifically interfere with the proliferation of cancerous cells. In this work I describe experiments which demonstrate that bisperoxoVanadium compounds, and specifically bpV(Me2Phen), inhibit Cdc25A phosphatase in vitro and in vivo. Further, these compounds cause cell-cycle arrest, are cytotoxic to cancer cells, and slow the growth of tumours in mouse models. With respect to the fundamental biology of Cdc25A, I have identified a sequence element (NLS) responsible for nuclear localization of Cdc25A phosphatase. An analysis of this sequence demonstrated high conservation of flanking phosphoacceptor sites, notably Serine 292. S292 was predicted to be a consensus PKA or CamKII substrate. Using site-directed mutagenesis I have shown that S292 is the sole site of PKA phosphorylation in vitro. The functional importance of S292 phosphorylation was investigated via transfections of phospho-mimetic mutants of S292 (S292E) expressed as GFP-fusion proteins; these studies indicate that S292 phosphorylation may promote nuclear localization. Studies by other groups have indicated that S292 is a phosphorylation site for inhibitory kinases, namely Chk1 and Chk2 (4). I generated a phospho-specific antibody to this site and demonstrate by immunofluorescence and western blotting an unexpected pattern of S292 phosphorylation associated with nuclear bodies and the mitotic apparatus. I provide evidence to suggest that these sites represent local fine-tuning of Cdc25A, allowing Cdk activity to be controlled at the level of specific subcellular structures. These studies highlight the complexity of Cdc25 regulation and indicate a previously unappreciated degree of control of their activity such that these enzymes exist in multiple discrete pools within a given cell.
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Oxidovanadium complexes with N-donor heterocyclic chelates.Hlela, Thulani Innocent. 12 February 2014 (has links)
The growing significance of vanadium in medicinal inorganic chemistry is due to the diverse
biological activities of its metal complexes, as elaborated in Chapter 1. These biological
activities stem from the fact that vanadium is an essential trace element as well as its ability to
form active pro-drugs under physiological conditions. To improve the bio-availability of these
potential metallopharmaceuticals, the use of biologically relevant ligand systems such as
heterocyclic ligands were considered. These chelators should provide the stability and the ability
to promote absorption through cell-membranes. The techniques as described in Chapter 2 were
employed to analyze and characterize the formulated heterocyclic ligands and their metal
complexes. The attained research findings are mainly divided into two studies which involve the
explorative coordination chemistry of two classes of ligands: 2-pyridylbenzimidazole (see
Chapter 3) and 2-phenylsubstituted heterocyclics (see Chapter 4). An additional brief study is
described in Chapter 5 which discusses the attempted coordination of a uracil Schiff base ligand.
In Chapter 3, the coordination behaviour of Hpybz (2-pyridylbenzimidazole) towards vanadium
in various oxidation states (i.e. +III/IV/V) was explored. The six-coordinate complex cis-
[VVO2(Hpybz)(pybz)] (1) was isolated as the CH3OH.(H2O)2 hydrate from the reaction of
NH4VO3 and Hpybz in aqueous methanol. The crystal structure shows that the vanadium is
bonded to two cis-oxido ligands, and to the two bidentate ligands pybz and Hpybz. This
combination of ligands confers six-coordination on the metal centre, which is a rare coordination
number for a mononuclear dioxido complex of vanadium(V). From the reaction between Hpybz
and VCl3 the cationic complex salt cis-[VIII(OH)2(Hpybz)2]Cl (2) was formed. The ligands in cis-
[VIII(OH)2(Hpybz)2]Cl exhibits the same coordination behaviour as in 1, but instead of the
dioxido moiety present in 1, two hydroxyl co-ligands are coordinated to the metal centre, with
both chelator ligands neutral. Conductivity measurements in DMF affirmed that the compound is
a 1:1 electrolyte. A novel binuclear mixed-valence oxidovanadium compound, (μ-
O)[VVO(pybz)2.VIVO(Hpybz)(acac)] (3), was obtained from the reaction of Hpybz with
VO(acac)2. ESR analysis illustrates paramagnetic behaviour typical of a type I dimer. The metal
compound, VO(Hpbyz)2SO4 (4).H2O was isolated in a good yield from the reaction of two
equivalents of Hpybz with vanadyl sulfate.
Chapter 4 reports the isolation of oxidovanadium compounds with 2-phenylsubstituted
benz(imidazole/othiazole/oxazole) chelators. The 2:1 molar reaction between NH4VO3 and 2-
hydroxyphenylbenzothiazole (Hobs) led to the formation of a polynuclear vanadium(IV)
complex, [VO(obs)2]n (1). The atmospheric oxygen-induced oxidation reaction of VCl3 and 2-
hydroxyphenyl-1H-benzoxazole (Hobo) afforded a similar oxidovanadium compound,
[VO(obo)2]n (2). A characteristic eight-line isotropic signal was observed in the ESR spectrum of
2 in DMF while, due to the poor solubility of 1, a singlet was attained upon analysis of the single
crystals. A diamagnetic dioxidovanadium(V) complex, cis-[VO2(obz)py] (3) (Hobz = 2-
hydroxyphenyl-1H-benzimidazole) was isolated from the reaction of NH4VO3 and Hobz in a
methanolic solution. A broad singlet is found in the 51V NMR spectrum at -520.7 ppm for the
d0-vanadium centre. The intra-ligand (π-π*) relaxations [466 nm for 1, 376 nm for 2 and 469 nm
for 3] could be observed in the emission spectra which were obtained in anhydrous DMF. In an
effort to synthesize a coordination compound of vanadium, the reaction of a heterocyclic ligand,
2-mercaptophenyl-1H-benzimidazole (Hsbz) with vanadyl sulfate resulted in an unexpected
reaction product, [C26H20N4S2].[SO4].4H2O (4).
In Chapter 5, the metal-induced cyclization of 5-amino-6-[(Z)-(2-hydroxybenzylidene)amino]-
1,3-dimethylpyrimidine-2,4-(1H, 3H)-dione (H3duo) by NH4VO3 resulted in the formation of a
cyclized benzimidazole derivative, 8-(2-hydroxyphenyl)-1,3-dimethyl-1H-purine-2,6-(3H, 7H)-
dione (1). The IR spectra of H3duo and its cyclized form are nearly identical where only minor
shifts in the significant bands are observed. The molecular transformation was more evident
when comparing the 1H NMR spectra of H3duo and 1. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2013.
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Solid phase crystallization of vanadium dioxide thin films and characterization through scanning electron microscopy /Rivera, Felipe, January 2007 (has links) (PDF)
Thesis (M.S.)--Brigham Young University. Dept of Physics and Astronomy, 2007. / Includes bibliographical references (p. 89-94) and index.
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Interactions of Vanadium Compounds With Reducing Equivalents: Evidence of Free Radical Involvement and Possible Mechanisms of ToxicityKeller, Randal J. 01 May 1988 (has links)
Vanadium compounds have been reported to cause numerous toxicological effects including NAD(P)H oxidation and lipid peroxidation. The purpose of this thesis is to determine the active form of vanadium in causing these effects, and to determine any possible free radical involvement in these processes. Vanadium-stimulated oxidation of NADH was studied spectrophotometrically and by electron spin resonance spectroscopy. In 25 mM sodium phosphate buffer at pH 7. 4, vanadyl , (V(IV)), is slightly more effective in stimulating NADH oxidation than was vanadate (V(V)). Addition of a superoxide generating system, xanthine/xanthine oxidase, results in a marked increase in NADH oxidation by vanadyl, and to a lesser extent, by vanadate. In contrast, addition of hydrogen peroxide did not change the NADH oxidation by vanadate, but greatly enhanced NADH oxidation by vanadyl. Use of the spin trap DMPO in reaction mixtures containing vanadyl and hydrogen peroxide or a superoxide generating system resulted in the detection by ESR of hydroxyl radical. Hydroxyl radical was also detected in the system containing vanadate plus superoxide. It was found that superoxide is capable of reducing vanadate to vanadyl, and that vanadyl is capable of reaction with hydrogen peroxide in a Fenton-like mechanism to produce hydroxyl radical. Hydroxyl radical is suggested to be the active species involved in NADH oxidation. Other reductants, such as thiols, are also capable of supporting vanadate-stimulated NADH oxidation . The above results indicat that ability of vanadium to act in a Fenton-like mechanism is an important process in the vanadium-stimulated oxidation of NADH.
Vanadyl was found to be the active form of vanadium involved in initiating and stimulating lipid peroxidation in purified and partially purified fatty acid micelle preparations. Hydroxyl radicals were shown to be involved in initiating diene conjugation when vanadyl and hydrogen peroxide were added together in the reaction mixture. Furthermore, hydroxyl radicals were shown to be generated in the vanadyl-catalyzed decomposition of fatty acid lipoperoxides.
The results of this study indicat that the ability of vanadium compounds to oxidize NADH and to stimulate lipid peroxidation are related by the common mechanism of hydroxyl radical production from the reaction of vanadyl with hydrogen peroxide.
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Deep space radiations-like effects on VO2 smart nano-coatings for heat management in small satelittesMathevula, Langutani Eulenda 01 1900 (has links)
Thermal control in spacecraft will be increasingly important as the spacecraft grows smaller and more compact. Such spacecraft with low thermal mass will have to be designed to retain or reject heat more efficiently. The passive smart radiation device (SRD) is a new type of thermal control material for spacecraft. Current space thermal control systems require heaters with an additional power penalty to maintain spacecraft temperatures during cold swings. Because its emissivity can be changed without electrical instruments or mechanical part, the use of SRD decreases the request of spacecraft power budget. The (SRD) based on VO2 films is one of the most important structures of the functional thermal control surface, being lighter, more advanced and without a moving devices. A large portion of the heat exchange between an object in space and the environment is performed throughout radiation, which is in turn determined by the object surface properties. The modulation device is coated on the spacecraft surface and thus provides a thermal window that can adapt to the changing conditions in orbit.
VO2 is well known to have a temperature driven metal to insulator transition ≈ 68ᴼC accompanying a transformation of crystallographic structure, from monoclinic (M-phase, semiconductor) at temperature below 68ᴼC to tetragonal (R-phase, metal) at temperature above 68ᴼC. This transition temperature is accompanied by an increase of infrared reflectivity and a decrease of infrared emissivity with increasing temperature. This flexibility makes VO2 potentially interesting for optical, electrical, and electro-optical switches devices, and as window for energy efficiency buildings applications. This study reports on effect of thickness on VO2 as well as the effect of proton irradiation on VO2 for active smart radiation device (SRD) application. VO2 was deposited on mica by Pulsed laser deposition techniques. The thickness of the film was varied by varying the deposition time. To characterize VO2 the following techniques were performed: XRD, AFM, SEM, TEM, XPS, RBS, RAMAN and transport measurements for optical properties. The effect of proton irradiation was observed using the SEM, where the change in structure, from crystal grains to rods, was observed. / Physics / M.Sc. (Physics)
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