Oxydiacetato complexes of thorium(IV), the crystal structures of tetra-aquo bis(oxydiacetato)thorium(IV) hexahydrate and di(sodium nitrate) disodium tris(oxydiacetato)thorium(IV)

The crystal and molecular structures of Th(oda)₂(H₂O)₄·6H₂O (1) and Na₂[Th(oda)₃]·2NaNO₃ (2) (oda = oxydiacetate) have been determined from three-dimensional X-ray diffraction data and refined by least squares to R = 0.049 and Rw = 0.049 for 2265 independent reflections for (1) and to R = 0.024 and Rw = 0.023 for 2196 independent reflections for (2).Crystal parameters are as follows: (1), tetragonal, space group P4₁2₁2, a = 10.335(2), c = 20.709(5) Å and Z = 4; (2), monoclinic, space group C2/c, a = 17.096(5), b = 9.451(2), c = 16.245(4) Å, β = 107.8(1) and Z = 4.In both compounds the thorium atom lies on a crystallographic two-fold axis. The co-ordination number for thorium in (1) is 10 (bicapped square antiprism geometry), the compound is monomeric, the two oda ligands are tridentate to the metal, and four water molecules complete the coordination sphere; in thorium (2) the coordination number is 9 (tricapped trigonal prism geometry) with three oda ligands tridentate to the metal, the [Th(oda)₃]^2? and NO₃^? anions are held together through the sodium ions which are coordinated both to the oda carboxylic oxygens and to the nitrate oxygens.The ThO coordination distances are: in (1) 2.411(8), 2.414(9) for the carboxylic oxygens, 2.479(10) and 2.486(8) for water molecules and 2.697(9) for the etheric oxygen and in (2) 2.384(3), 2.402(4) and 2.402(4) for the carboxylic oxygens, 2.559(5) and 2.562(4) Å for the etheric oxygens.     

Chloride and tropolonato mixed complexes of uranium(IV) and thorium(IV)

The synthesis of some new chloride and tropolonato mixed complexes of the general composition MCl_4?nTrop_n·mL (M = U^IV, Th^IV; n = 1, 2, 3; m = $\text{1}\text{2}$, $\text{2}\text{3}$, 1, 2 and 3; L = DME, THF, LiCl and 18-crown-6) by the reaction of uranium and thorium tetrachlorides with M′Trop (M′ = Tl and Li) is described. The residual chloride atoms in UTropCl₃·THF undergo further substitution reactions involving TlCp, while UTrop₂Cl₂·THF shows a different behaviour toward TlCp, since Cp₃UCl as one of the main reaction products is obtained. Protolysis of Cp₂U(NEt₂)₂ by HTrop affords a mixture of CpUTrop₃ and Cp₂UTrop₂. Finally both UTropCl₃·THF and UCl₄ react directly with HTrop, the nature of the resulting products depending on the reaction solvent.     

Chloride and oxinate mixed complexes of uranium(IV) and thorium(IV)

Some new chloride and oxinate mixed complexes of general composition MCl_4?nOx_n (M = U(IV) and Th(IV); Ox = 8-hydroxyquinolinato; n = 1, 2) were synthesized by the reaction of uranium or thorium tetrachlorides with M′Ox (M′ = Na, K, Tl) or MgOx₂. By using the oxine the formation of the adducts MCl₄·2HOx occurs, without the substitution of the chloride ions. By suspending MCl₄·2HOx in the presence of a strong base (Proton Sponge) MCl₂Ox₂ was formed immediately. The reaction of UCl₂Ox₂ and TlCp did not afford Cp₂UOx₂, which can be easily prepared by reaction of Cp₂U(NEt₂)₂ and HOx.     

Biosorption of thorium (IV) by a Pseudomonas biomass

Lyophilized biomass of a Pseudomonas soilisolate adsorbed thorium (IV) (430 mg g^–1 dry wt) optimally at pH 4, with 91% of equilibrium loading being reached in 1 min. Equilibrium metal sorption showing conformity to Langmuir isotherm model suggested a monolayered thorium binding. Thorium binding remained unaffected or slightly affected (< 20% inhibition) in presence of equimolar (430 M) concentration of several interfering ions except Fe³⁺ (40% inhibition). More than 90% of loaded thorium could be recovered using 1 M CaCO₃, though mineral acids and Na₂CO₃ were also effective.     

Guanine complexes with dysprosium(III), thorium(IV) and uranium(IV) chlorides

By refluxing mixtures of guanine (guH) and DyCl₃, ThCl₄ or UCl₄ in ethanol-triethyl orthoformate, solid complexes of the Dy(guH)₂(gu)Cl₂ and M(gu)₂Cl₂ (M = Th, U) types were isolated. The insolubility of the new complexes in organic media, combined with the coordination number six suggested by the spectral evidence, favors polymeric configurations. Most likely structures involve a linear, chainlike, single-bridged polymeric backbone

The Dy³⁺ complex is probably a linear polymer, also containing terminal unidentate guanine ligands, whilst for M = Th⁴⁺, U⁴⁺ highly polymeric structures arising from cross-linking between linear polymeric

units seems most likely. IR evidence rules out participation of the O(6) oxygen of guanine in coordination, despite the hard acid character of the metal ions under study. Guanine apparently coordinates exclusively through ring nitrogens in the new metal complexes; N(9) and N(7). N(9) are, respectively, the most likely binding sites of terminal unidentate and bridging bidentate guanine. The chloro ligands present in the complexes seem to be exclusively terminal.     

N-substituted ethylcarbamate complexes of thorium(IV) and lanthanum(III) nitrates

N-substituted ethylcarbamates form with thorium nitrate the complexes Th(NO₃)₄·3RHNC(O)OC₂H₅ (where R = CH₃, C₂H₅, C₆H₅(CH₃)CH) and with lanthanum nitrate the complexes La(NO₃)₃· 2RR′NC(O)OC₂H₅·3H₂O (where R = CH₃, C₂H₅, C₆H₅(CH₃)CH; R′ = H and R = CH₃, C₆H₅; R′ = C₂H₅ or R = R′ = CH₃). In addition the anhydrous La(NO₃)₃·3(C₂H₅)₂NC(O)OC₂H₅ has been isolated. From the IR spectra it is deduced that the carbamates coordinate the metal through the carbonyl oxygen atom and that the nitrato groups act as chelated ligands. ¹H nmr spectral data of the complexes are reported and discussed.     

Structural chemistry of actinide compounds with different coordination numbers: The crystal and molecular structures of tetrachlorotris(N,N-diethylpropionamide)thorium(IV) and tetra-N-thiocyanato tetrakis(N,N-dimethylpropionamide)thorium(IV)

The crystal and molecular structures of ThCl₄(depa)₃ (1) (depa = N,N-diethylpropionamide) and Th(NCS)₄(dmpa)₄ (2) (dmpa = N,N-dimethylpropionamide) have been determined from three-dimensional X-ray diffraction data. The compounds crystallize in space group P2₁/n (1) and P2₁/a (2), with a = 18.107(5), b = 10.347(3), c = 17.867(5) Å, β = 108.5(1)°, Z = 4 (1) and a = 22.759(6), b = 13.763(4), c = 11.910(3) Å, β = 91.4(1)° and Z = 4 (2). Full matrix least-squares refinement of both structures gave for (1) with 3126 intensity data R = 0.046 and Rw 0.046 and for (2) with 3480 intensity data R = 0.050, Rw 0.054. The different steric constraints imposed by the ligand give rise to different coordination numbers. In (1) the coordination polyhedron about the seven co-ordinate thorium atom is a pentagonal bipyramid with two chlorine atoms in the axial positions, an unusual geometry for Th(IV) species. The average bonding distances are ThO = 2.340(9), ThCl_eq = 2.754(3) and ThCl_ax = 2.692(3) Å.In (2) the less hindering dmpa ligand favours the presence of four of them in the metal coordination sphere in a distorted square antiprismatic coordination geometry. ThO and ThN average 2.37(1) and 2.49(2) Å respectively.     

N,N-diisopropylcarboxylic acid amide complexes of thorium(IV) and uranium(IV) N-thiocyanates; the crystal structure of tetraisothiocyanato tetrakis(N,N-diisopropylacetamide-O)uranium(IV)

The complexes M(NCS)₄·xL (x = 2, M = U, L = Me₃CCON(Prⁱ)₂(dippva); x = 3, M = Th, L = Me₂CHCON(Prⁱ)₂(dipiba) and dippva, M = U, L = EtCON(Pr¹)₂(dippa), dipiba and dippva; x = 4, M = Th, L = MeCON(Prⁱ)₂(dipa), dippa and dipiba, M = U, L = dipa, dippa) and the solvates M(NCS)₄·4dipa·CH₂Cl₂ (M = Th, U) have been prepared. Their i.r. and u.v.-visible (M = U only) spectra are reported. The crystal and molecular structure of U(NCS)₄(dipa)₄· CH₂Cl₂ has been determined by the heavy-atom method from X-ray diffractometer data and refined by least squares to R 0.029 for 1135 independent reflections. The crystal is tetragonal, space group P$\text{4}$2₁c, with Z = 2, a = 15.663(4) and c = 10.512(3) Å. The coordination geometry about the 8-coordinate uranium atom is dodecahedral with the N atoms of the NCS groups occupying the dodecahedral A sites and the ‘dipa’ O atoms the B sites. The bonding distances of UO and UN are 2.363(8), and 2.444(11) Å respectively.     

Actinide coordination chemistry - a unique example of a homoleptic complex of nine-coordinate thorium(IV)

The dimethylsulfoxide (dmso) solvate of Th(IV) perchlorate is readily obtained from acidic aqueous Th(IV) solutions and has a formulation established from a single crystal structure determination of [Th(dmso-O)₉](ClO₄)₄ · 4dmso; triclinic, , a=12.4811(8) Å, b=12.4879(8) Å, c=23.969(2) Å, α=94.684(1)°, β=95.823(1)°, γ=119.347(1)°. The primary coordination sphere of the Th is of tricapped trigonal prismatic form, with the symmetry of the [Th(dmso-O)₉] entity being close to C_3h.     

Synthesis,spectral characterization,in vitro microbial and cytotoxic studies of lanthanum(III) and thorium(IV) complexes with 1,2,4-triazole Schiff bases

A series of metal complexes of La(III) and Th(IV) have been synthesized with newly derived biologically active ligands. These ligands were synthesized by the condensation of 3-substituted-4-amino-5-hydrazino-1,2,4-triazole with 8-formyl-7-hydroxy- 4-methylcoumarin. The structure of the complexes has been proposed by elemental analyses, spectroscopic data i.e. i.r., ¹H nmr, Uv-Vis, FAB-mass and thermal studies. The elemental analyses of the complexes conform to the stoichiometry of the type [La(L)·3H₂O]·2H₂O and [Th(L)(NO₃)·2H₂O]·2H₂O where (L = L^I-L^IV). All the complexes are soluble in DMF and DMSO and are non-electrolytes in DMF and DMSO. All these ligands and their complexes have also been screened for their antibacterial (Escherichia coli, Staphylococcus aureus, Staphylococcus pyogenes and Pseudomonas aeruginosa) and antifungal activities (Aspergillus niger, Aspergillus flavus and cladosporium) by the MIC method. The brine shrimp bioassay was also carried out to study their invitro cytotoxic properties.     

Membrane Depolarization by Hexacyanoferrate (III), Hexabromoiridate (IV) and Hexachloroiridate (IV)

Three artificial electron acceptors of different E_o and charge,hexacyanoferrate (III) (K₃Fe(CN)₆), hexachloroiridate (IV) (K₂IrCl₆),and hexabromoiridate (IV) (K₂IrBr₆), were compared with respectto their rate of reduction by roots of Zea mays L., the concomitantproton secretion, and to the effect on plasmalemma depolarization. It has been shown that these plasma membrane impermeable electronacceptors were reduced by a plasmalemma reductase activity.At low concentrations proton secretion was slightly inhibited,at higher concentrations, however, the rate of proton secretionwas stimulated. The root cell plasmalemma showed a transientdepolarization after addition of all three electron acceptors.The depolarization was concentration-dependent for the iridatecomplexes but not for hexacyanoferrate (III). For both iridatecomplexes maximum depolarization was reached at 50 µmoldm^–3. A hypothetical model as an explanation of the redox dependentproton secretion will be given. Key words: Hexachloroiridate (IV), hexabromoiridate (IV), hexacyanoferrate (III), plasmalemma redox, membrane potential, Zea mays     

Some new derivatives of organozirconium(IV) and organotitanium(IV) with thiophenecarboxylic acids

The complexes of the type Cp₂M(3-TC)Cl, Cp₂M(3-TC)₂, Cp₂M(3-TA)Cl, Cp₂M(3-TA)₂, Cp₂M(2-TB)Cl, Cp₂M(2-TB)₂ [where Cp = cyclopentadienyl, M = Zr or Ti] were synthesized by the reactions of dichlorobis(cyclopentadienyl)zirconium(IV) and dichlorobis(cyclopentadienyl)titanium(IV) with 3-thiophenecarboxylic acid (3-TCH), 3-thiopheneacetic acid (3-TAH) and 2-thiophenebutyric acid (2-TBH) respectively in different stoichiometric ratios. The new complexes were characterized by their elemental analysis, ¹H NMR, IR, and electronic spectral data.     

A quantitative histochemical study of dipeptidylpeptidase IV (DPP IV)

Summary In order to elucidate the possibility of a quantitative study of dipeptidylpeptidase IV (DPP IV) in cells and cell compartments of tissue sections kinetic investigations were performed with biochemical fluorometric and cytophotometric (microdensitometric) methods in the jejunum, kidney and liver of adult rats; in addition, two approaches of microdensitometric measuring (endpoint and continuous cytophotometry) were compared. Biochemically, Gly-Pro-4-methoxy-2-naphthylamine (MNA) is the best substrate compared with the 1-naphthylamine and 2-naphthylamine due to its high hydrolysis rate, the low Michaelis constant (K_m) and the relative high fluorescence of MNA. Its pH optimum is between 8.5 and 9. The hydrolysis rates delivered by cacodylate, phosphate and Tris HCl are similar and always higher than with other buffers. The maximal reaction velocity is reached with 3 mM Gly-Pro-MNA. The hydrolysis is inhibited in the presence of phenantroline, diisopronyl fluorphosphate, formaldehyde and diazonium salts; furthermore, formaldehyde and diazonium salts increase the Km of DPP IV. Fast Blue B pure (FBB) is the simultaneous coupling reagent of choice. End-point (plug and scanning procedure) and continuous microdensitometry with Gly-Pro-MNA and FBB in the intestinal and renal brush border and in renal glomerula have to be carried out at suboptimal pH (7.5). However, the optimal substrate concentrations are identical and the overall relation between the activity of DPP IV in the jenum, liver and kidney are similar in the quantitative histochemical and biochemical system. A linear relationship between the quantity of azo-dye and section thickness or incubation time exists between 4 m and 10 m and during the first 6 min of incubation respectively. Among different plotting procedures the best-fit method delivers the most reliable results. — The microdensitometric data in the small intestine show that K_m and V_max differ at different positions of the villi and may represent parameters for the maturation process of the enterocytes; in the kidney microdensitometry reveals different DPP IV activities in the different parts of the nephron. Both, the findings for the villi and the nephron cannot be obtained by biochemical methods.Supported by Deutsche Forschungsgemeinschaft (GU 184/1)Supported in part by Deutsche Forschungsgemeinschaft (SFB 105)     

Platinum(IV) isocyanide complexes

Neutral and cationic platinum(IV) isocyanide complexes of the type [PtCl₄(CNR)₂], [PtCl₄(CNR) (PMe₂Ph)], [PtCl₃(CNR)(PMe₂Ph)₂]⁺, [PtCl₂(CNR)₂ (PMe₂Ph)₂]²⁺, where R = methyl, t-butyl, cyclohexyl, p-tolyl, have been prepared by chlorine addition to the corresponding platinum(II) derivatives. The complexes [PtCl₂(CN)₂(CNR)₂] and [PtCl₂(CN)(CNR) (PMe₂Ph)₂]⁺ (R = t-butyl), are also reported. The cationic t-butylisocyanide derivatives are noteworthy in the way they readily lose the t-butyl cation at room temperature to give the corresponding cyano complexes. The compounds have been characterized by elemental analysis, molecular weights and conductivity measurements, and their i.r. and n.m.r. data are discussed in relation to structures and to the nature of the platinum-isocyanide bond.     

Extraction of Np(IV), Pu(IV) and Am(III) by bidentate organophosphorus extractant

This paper summarizes the extraction of Np(IV), Pu(IV) and Am(III) with dihexyl-N,Ndiethyl carbamyl methylene phosphonate (DHDECMP)-diethyl benzene (DEB) in nitric acid.The distribution ratio of Np(IV), Pu(IV) and Am(III) was studied as a function of a number of parameters such as concentration of nitric acid, salting-out reagent in the aqueous phase, contact time and temperature. Stripping and separation of Np(IV), Pu(IV) and Am(III) from the pregnant organic phase were also studied. The suitable stripping and separation conditions were obtained. The enthalpy changes ΔH_Np, ΔH_Pu, ΔH_Am associated with their extraction process were estimated individually. The composition of extracted complex of Np(IV), Pu(IV) and Am(III) was determined.     

Alkylimido complexes of titanium(IV)

TiCl₄ reacts with t-butylamine in benzene to give [Ti(NCMe₃)Cl₂(NH₂CMe₃)₂]_x and t-butylamine hydrochloride. The IR spectrum indicates both c/s and trans metal dichlorides (300; and 308, 208 cm⁻¹). In the ¹³C NMR spectrum the t-butylimido quaternary carbon resonance occurs at 72.1 ppm. A dimeric structure incorporating symmetric t-butylimido bridges is proposed. TiCl₄ in benzene react under reflux with two equivalents of Me₃SiNHCMe₃ to give [Ti(NCMe₃)Cl₂(NH₂CMe₃)]_x and with iso-propylamine and ethylamine to give complexes of the form [Ti(NR)Cl₂(NH₂R)₂]_x. Broad bands below 800 cm⁻¹ in the IR spectra suggest polymeric MNM bridges. For [Ti(NCHMe₂)Cl₂(NH₂CHMe₂)]_x the iso-propylimido CH resonance in the ¹³C NMR spectrum occurs at 67 ppm. [Ti(NCMe₃)Cl₂(NH₂CMe₃)₂]₂ reacts with L=bipy or tmed to give [Ti(NCMe₃)Cl₂(L)]₂, and TiCl₄ reacts with two equivalents of Me₃SiNHCMe₃ in benzene and then tmed to give [Ti(NCMe₃)Cl₂(tmed)]₂. The ¹³C NMR spectrum shows the t-butylimido quaternary carbon resonance at 73.5 ppm and the tmed resonances are chemically equivalent. A dimeric μ-NCMe₃ bridging structure is proposed for the complex.     

Mixed-ligand tris chelated complexes of Mo(IV) and W(IV): A comparative study

Two hitherto unknown mixed-ligand tris chelated complexes containing 2-aminothiophenolate, [Et₄N]₂[M^IV(NH-(C₆H₄)-S)(mnt)₂] (M = Mo, 1a; W, 2a) and two mixed-ligand tris chelate complex containing N,N-diethyldithiocarbamate, [Et₄N]₂[M^IV(Et₂NS₂)(mnt)₂] (M = Mo, 1b; W, 2b) have been synthesized and characterized structurally. Although these complexes are supposed to be quite similar to the well-known symmetric tris chelate complexes of maleonitriledithiolate (mnt), [Et₄N]₂[M^IV(mnt)₃] (M = Mo, 1c; W, 2c), but display both trigonal prismatic and distorted trigonal prismatic geometry in their crystal structure indicating the possibility of an equilibrium between these two structural possibilities in solution. Unlike extreme stability of 1b, 2b, 1c and 2c, both 1a and 2a are highly unstable in solution. In contrast to one reversible reduction in case of 1b and 2b, 1a and 2a exhibited no possible reduction up to −1.2 V and two sequential oxidation steps which have been further investigated with EPR study. Differences in stability and electrochemical behavior of 1a, 1b, 2a and 2b have been correlated with theoretical calculations at DFT level in comparison with long known 1c and 2c.