Extraction of uranium with 2,3-dihydroxynaphthalene and cetyltrimethylammonium bromide, and its fluorimetric determination in silicate rocks

A novel procedure for the extraction of uranium has been described. UO₂ ²⁺ forms a 1:3 anionic complex with 2,3-dihydroxynaphthalene in the pH range, 4–12. This anionic complex is best extracted into ethyl acetate at pH 11–12 under the influence of a counter cation, cetyltrimethylammonium bromide. This extraction technique has been extended to the separation of uranium from silicate rock matrices for its determination by fluorimetry. Except Co, Cr, and Fe, most elements present in silicate rocks do not interfere. While the interferences of Co and Cr are suppressed by the addition of EDTA, iron is removed by prior extraction at pH 4–5 as its neutral complex with 2,3-dihydroxynaphthalene. The results compare favourably with those obtained from the conventional technique, i.e., extraction of uranium in ethyl acetate from NHO₃ medium under the influence of Al(NO₃)₃ ^.9H₂O as salting out agent. The extraction system under study is capable of separating even ultra-trace amounts of uranium quantitatively from complex matrices of rock samples. Besides, the method is simple, rapid, cost effective and precludes the use of reagents like nitric acid and aluminum nitrate (salting out agent) required in bulk quantities in the conventional system.     

Improvement of an overloaded, multi-component, solvent gradient bioseparation through multiobjective optimization

Solvent gradient chromatography is quite often used in analytical studies for decreasing the analysis time of samples having components with widely different retention behaviour. Several studies, both theoretical and experimental, have been reported on the optimization of gradient profiles in improving analytical separation performance, suggesting various linear and non-linear gradients. In preparative chromatography, on the other hand, though solvent gradient is being increasingly used (especially in bioseparation) to improve the product yield and productivity, there is a dearth of literature and clearer understanding of the effect(s) of modifier gradients on the separation performance. For this, the gradients used in applications are of relatively simple profiles like step or linear gradients, obtained through hand optimization based on experience and intuition. Significant improvements, however, can be expected using the state-of-the art modelling of chromatographic processes and optimization routines running on widely available hi-speed desktop computers. In this work we are reporting such an optimization procedure to improve the purification of an industrial multi-component mixture, containing 65.8% of Calcitonin as the main product, in an overloaded reversed-phase column. The work comprises both theoretical simulations and their experimental validation using multilinear gradients as optimization variable. The study produced interesting insights for modifier gradient design, like using peak deformation of the target peptide to increase yield and productivity, and improved our understanding of the effect of modifier gradients in non-linear separations.     

Fundamental challenges and opportunities for preparative supercritical fluid chromatography

The use of supercritical fluids as mobile phases in chromatography was suggested nearly fifty years ago. In spite of some major potential advantages, this mode of chromatography, generally known as SFC, is only now beginning to be considered by the mainstream community but it still does not yet enjoy a popularity comparable to those of gas or liquid chromatography. This seems to be largely due to a combination of (1) the serious instrumental difficulties that took many years to solve; (2) the complexity of the behavior of supercritical fluids in chromatographic systems when their temperature, pressure, or composition changes; (3) the long-lasting absence of any substantial incentive to use more complex systems, when the simpler and more robust approaches provided by HPLC are available. This situation, however, has begun to significantly change during recent years. The incentive of employing green, sustainable technologies in industrial processes as well as in analyses is increasing. Because mobile phases generally used in SFC tend to be less environmentally harmful and less expensive than those used in HPLC, SFC presents strong economical and regulatory advantages over the latter technique. Added to that, steady advancements in LC techniques in the last three decades has solved many instrumental difficulties related to SFC, which is now taking full advantages of many of these advances. One factor, however, has remained mostly unresolved. A clearer understanding of the physico-chemical behavior of supercritical fluids in preparative chromatographic columns under nonlinear conditions is still needed. This seems to be the main obstacle to the establishment of SFC as a sustainable separation tool. One aim of this review is to highlight these issues in more detail through a survey of the state-of-the-art techniques available for the design and operation of SFC. Another aim is to outline a possible series of investigations, which are necessary to develop a better physical understanding of SFC.     

Nickel(II) complexes of the macrocyclic ligand 5-nitromethyl-5,7,12,14-tetramethyl-1,4,8,11-tetraazacyclotetradeca-4,11-diene containing a pendant nitro group

The reaction of MeNO2 in the presence of Et3N with the nickel(II) complex of C-meso-5,7,12,14-tetramethyl-1,4,8,11-tetraazacyclotetradeca-4,11-diene gives the nickel(II) complex of the 5-nitromethyl derivative containing a pendant nitro group. The complex is octahedral with the nitro group coordinated to nickel(II) via the aci-nitro tautomer. Although the complex contains one water molecule, six-coordination occurs by interaction with a neighbouring CH NO2- group in a polymeric structure. Recrystallisation from aqueous ammonia gives a blue paramagnetic complex with lattice ammonia. Addition of HClO4 to the blue paramagnetic hydrate gives the orange-brown diperchlorate salt with a pendant nitro group. This salt displays a planar octahedral equilibrium in aqueous solution, NiL+2H2O NiL(H2O)2, with K=0.28 at 40degC. The thermodynamic parameters for this equilibrium are DeltaH=-59+2kJmol-1and DeltaS=-200+5JK-1mol-1. The nitro group can be reduced with Zn/HCl to give the amino derivative. The configurations of the complexes are considered and the spectroscopic results discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Complexes of a tridentate ONS Schiff base. Synthesis and biological properties

Several new complexes of a tridentate ONS Schiff base derived from the condensation of S-benzyldithiocarbazate with salicylaldehyde have been characterised by elemental analyses, molar conductivity measurements and by i.r. and electronic spectra. The Schiff base (HONSH) behaves as a dinegatively charged ligand coordinating through the thiolo sulphur, the azomethine nitrogen and the hydroxyl oxygen. It forms mono-ligand complexes: [M(ONS)X], [M=Ni^II, Cu^II, Cr^III, Sb^III, Zn^II, Zr^IV or U^VI with X = H₂O, Cl]. The ligand produced a bis-chelated complex of composition [Th(ONS)₂] with Th^IV. Square-planar structures are proposed for the Ni^II and Cu^II complexes. Antimicrobial tests indicate that the Schiff base and five of the metal complexes of Cu^II, Ni^II, U^VI, Zn^II and Sb^III are strongly active against bacteria. Ni^II and Sb^III complexes were the most effective against Pseudomonas aeruginosa (gram negative), while the Cu^II complex proved to be best against Bacillus cereus (gram positive bacteria). Antifungal activities were also noted with the Schiff base and the U^VI complex. These compounds showed positive results against Candida albicans fungi, however, none of them were effective against Aspergillus ochraceous fungi. The Schiff base and its zinc and antimony complexes are strongly active against leukemic cells (CD₅₀ = 2.3–4.3 μg cm⁻³) while the copper, uranium and thorium complexes are moderately active (CD₅₀ = 6.9–9.5 μg cm⁻³). The nickel, zirconium and chromium complexes were found to be inactive. This revised version was published online in June 2006 with corrections to the Cover Date.