Characterization of a new hexasodium diphosphopentamolybdate hydrate, Na6[P2Mo5O23]x7H2O, by 23Na MQMAS NMR spectroscopy and X-ray powder diffraction

A novel hexasodium disphosphopentamolybdate hydrate, Na6[P2Mo5O23]x7H2O, has been identified using X-ray powder diffraction, 1H, 23Na, and 31P magic-angle spinning (MAS) NMR, and 23Na multiple-quantum (MQ) MAS NMR. Powder XRD reveals that the hydrate belongs to the triclinic spacegroup P1 with cell dimensions a = 10.090(3) A, b = 15.448(5) A, c = 8.460(4) A, alpha = 101.45(6) degrees, beta = 104.09(2) degrees, gamma = 90.71(5) degrees, and Z = 2. The number of water molecules of crystallization has been determined on the basis of a quantitative evaluation of the 1H MAS NMR spectrum, the crystallographic unit cell volume, and a hydrogen content analysis. The 23Na MQMAS NMR spectra of Na6[P2Mo5O23]x7H2O, obtained at three different magnetic fields, clearly resolve resonances from six different sodium sites and allow a determination of the second-order quadrupolar effect parameters and isotropic chemical shifts for the individual resonances. These data are used to determine the quadrupole coupling parameters (CQ and eta Q) from simulations of the complex line shapes of the central transitions, observed in 23Na MAS NMR spectra at the three magnetic fields. This analysis illustrates the advantages of combining MQMAS and MAS NMR at moderate and high magnetic fields for a precise determination of quadrupole coupling parameters and isotropic chemical shifts for multiple sodium sites in inorganic systems. 31P MAS NMR demonstrates the presence of two distinct P sites in the asymmetric unit of Na6[P2Mo5O23].7H2O while the 31P chemical shielding anisotropy parameters, determined for this hydrate and for Na6[P2Mo5O23]x13H2O, show that these two hydrates can easily be distinguished using 31P MAS NMR.     

Comparison of the immunolabeling of heated and deplasticized epoxy sections on the electron microscopical level.

The purpose of this study was to compare the yield of immunogold labeling of heated epoxy sections with the yield of labeling of deplasticized epoxy sections, and to compare the immunolabeling of deplasticized high-accelerator epoxy sections and deplasticized low-accelerator epoxy sections. Renal swine tissue and human thyroid tissue were embedded in both high- and low-accelerator epoxy resin and also in LR-White resin. Immunogold labeling was performed on deplasticized (ethoxide-treated), heated and non-treated ultrathin sections from these specimens. The renal tissue was immunolabeled with anti-IgG, and the thyroid tissue was immunolabeled with anti-thyroglobulin. The ethoxide treatment of the epoxy sections induced complete deplasticizing. The immunogold labeling with anti-IgG on deplasticized epoxy sections of renal tissue demonstrated significantly more intense immunolabeling of immune complex deposits than the corresponding epoxy sections which were exposed to heat in citrate buffer. The results for labeling areas of thyroglobulin substance with anti-thyroglobulin showed no significant differences between deplasticized and heated epoxy sections, probably because the sodium ethoxide partly destroys the antigenicity. Deplasticized high-accelerator epoxy sections showed significantly higher yield of immunolabeling than deplasticized low-accelerator epoxy sections and LR-White sections both for anti-IgG and anti-thyroglobulin. This can be explained by the reduced tendency for the knife to cleave proteins when cutting high-accelerator epoxy sections. High-accelerator epoxy sections which were exposed to heat in citrate buffer were more intensely immunolabeled than similarly treated low-accelerator epoxy sections, in agreement with previous results. The ultrastructural preservation of the tissues of deplasticized epoxy sections was inferior compared with the other sections. This study shows that the choice between deplasticizing technique or heating of epoxy sections has to be considered with respect to the nature of the antigen and to the requirement for ultrastructural preservation.     

Particle concentration measurement of virus samples using electrospray differential mobility analysis and quantitative amino acid analysis

Virus reference materials are needed to develop and calibrate detection devices and instruments. We used electrospray differential mobility analysis (ES-DMA) and quantitative amino acid analysis (AAA) to determine the particle concentration of three small model viruses (bacteriophages MS2, PP7, and ?X174). The biological activity, purity, and aggregation of the virus samples were measured using plaque assays, denaturing gel electrophoresis, and size-exclusion chromatography. ES-DMA was developed to count the virus particles using gold nanoparticles as internal standards. ES-DMA additionally provides quantitative measurement of the size and extent of aggregation in the virus samples. Quantitative AAA was also used to determine the mass of the viral proteins in the pure virus samples. The samples were hydrolyzed and the masses of the well-recovered amino acids were used to calculate the equivalent concentration of viral particles in the samples. The concentration of the virus samples determined by ES-DMA was in good agreement with the concentration predicted by AAA for these purified samples. The advantages and limitations of ES-DMA and AAA to characterize virus reference materials are discussed.     

Preparation and crystal structures of formato complexes of the [MIV3O4]4+ and [MIV3S4]4+ (M = Mo,W) clusters. Convenient precursors to the corresponding aqua complexes

In the aqueous chemistry of molybdenum(IV) and tungsten(IV), trinuclear, incomplete cubane-like, oxo and sulfido clusters of the type [M3E4]4+ (M = Mo, W; E = O, S) play a central role. We here describe how formato complexes of all these cluster cores can be prepared in high yields by crystallization from methanol-water or ethanol-water mixtures. Since potassium and ammonium formate are very soluble in these alcohol-water mixtures, high formate concentrations could be accomplished in the solutions from which the corresponding salts of cluster formato complexes crystallized. The [Mo3O4]4+ compounds could be synthesized without requiring the use of noncomplexing acids in the process. Some [M3E4]4+ compounds were characterized by single-crystal structure determinations. [NH4]3.20[K]0.80[H3O][Mo3O4(HCO2)8][HCO2].H2O was triclinic, space group P1 (No. 2) with a = 11.011(2) A, b = 13.310(2) A, c = 9.993(1) A, alpha = 106.817(7) degrees, beta = 91.651(9) degrees, gamma = 88.340(9) degrees, and two formula units per cell. [K]6[W3S4(HCO2)9][HCO2].2.27H2O.0.73CH3OH was monoclinic, space group C2/m (No. 12) with a = 19.605(6) A, b = 14.458(7) A, c = 13.627(5) A, beta = 118.94(2) degrees, and four formula units per cell. Generally, the nine coordination sites of [M3E4]4+ were occupied either by a mixture of monodentate and mu 2-bridging formato ligands or by monodentate formato ligands only. By dissolution in noncomplexing strong acid, all the formato complexes immediately hydrolyzed to form [M3E4(H2O)9]4+ aqua complexes. This allows, for example, high concentrations of [Mo3S4(H2O)9]4+ in CF3SO3H to be obtained and these solutions to be used for the synthesis of bimetallic clusters containing the cubane-like motif Mo3M'S4.     

Molecular metal sulfide cluster model for substrate binding to oil-refinery hydrodesulfurization catalysts

Reaction between [(eta5-Cp')3Mo3S4]+ and [Ni(1,5-cod)2] (Cp' = methylcyclopentadienyl; 1,5-cod = 1,5-cyclooctadiene) in THF at ambient temperature yielded a coordinatively unsaturated cubane-like cluster cation, [(eta5-Cp')3Mo3S4Ni]+. The ligand sphere at the Ni atom could be saturated by coordinating dimethyl sulfide, diethyl sulfide, di(tert-butyl) sulfide, tetrahydrothiophene, thiochroman-4-ol, 1,4-dithiane, pyridine, quinoline, or 4,4'-bipyridine. The products structurally model a mode of substrate coordination on proposed binding sites of heterogeneous MoNi sulfide hydrotreating catalysts. No stable coordination compounds could be isolated for thiophene derivatives. X-ray crystal structures are reported for the ligand-bridged dicluster compounds [[(eta5-Cp')3Mo3S4Ni]2(mu-C4H4S2)][pts]2 (C4H8S2 = 1,4-dithiane) and [[(eta5-Cp')3Mo3S4Ni]2(mu-bipy)][pts]2 (bipy = 4,4'-bipyridine).