Drugs and related topics

Drugs is a topic that was certainly an issue of discussion at this year's annual meeting. This Committee had the responsibility of organizing a half day symposium on "Pharmaceutical Authenticity and Safety" that took place September 12, 2005. This symposium aims at improving the critical points in the analytical pharmaceutical field related to traceability assessment, use of certified reference materials (CRMs), and proficiency testing implementation to get the highest quality of the obtained results. Recognized experts presented these topics. Also, other complementary subjects, such as the application of advanced analytical technologies to reach the authenticity and safety of the pharmaceutical drugs and drug products, their microbiological quality assessment, without disregarding an important topic such as sampling, was presented and discussed. The talks that were presented are the following: "Proficiency Testing as a Need in the Pharmaceutical Field," Arlene Fox (AOAC INTERNATIONAL, Gaithersburg, MD); "Implementation of Traceability in the Pharmaceutical Laboratory," Thomas Layloff, (Management Sciences for Health, Arlington, VA); "Harmonized Characteristics of Certified Reference Materials According to ISO Guides-Attractive also for Pharmaceutical Analysis," Hendrik Emons (Reference Materials, Unit Institute for Reference Materials and Measurements (IRMM), Joint Research Centre European Commission, (Geel, Belgium); "Importance of LC/MS/MS for the Fingerprinting of Pharmaceutical Drugs," Paul A. Steinberg, (Thermo Electron Corp., Woodstock, GA); "Process Analytical Technology (PAT) as a Way for Better Manufacturing and Quality Assurance," John F. Kauffman (Division of Pharmaceutical Analysis, U.S. Food and Drug Administration (St. Louis, MO); "Stability Testing for the Safety Assessment of Pharmaceuticals," Marta Vidal (Boeringher Ingelheim Argentina, Buenos Aires, Argentina); "Validation of Microbiological Methods for Sterile and Nonsterile Pharmaceutical Products," Michael Brodsky (Brodsky Consultants, Thornhill, ON, Canada); "The Relationship Between Pharmacopoeial Reference Standards and ISO REMCO Initiatives and Guides," Ronald G. Manning (United States Pharmacopoeia, Rockville, MD).     

Recent topics of the metallacycles composed of the heavier group 14 elements

This Letter reviews recent advance of metallacycles with chelating Si-, Ge-, and Sn-ligands. Dehydrogenative bond-forming reactions of organosilanes, -germanes, and -stannanes promoted by Pd and Pt complexes afford four- and five-membered metallacycles composed of heavier group 14 elements. It has a couple of advantages such as easier preparation of the starting compounds and reaction procedure than the common metathesis reactions of dianions with transition metal dihalide complexes. These metallacycles are regarded as possible intermediates in catalytic dehydrocoupling polymerizations or as convenient precursors to form discrete oligomers.     

Group of symmetry of the periodic system of chemical elements

The concurrence of the group of symmetry of the periodic system of elements with the group of dynamical symmetry of a hydrogenlike atom is employed in the theoretical investigation of atoms. The character of the degeneracy of the eigenvalues of a hydrogenlike atom Hamiltonian, without changing its eigenfunctions, was changed by introducing into this Hamiltonian a term which violates the symmetry in relation to transformations from the subgroup O(4) of the group SO(4, 2). In consequence, it was realized that such “reorganization” of the states of a hydrogenlike atom, which form a representation of the group SO(4, 2), effects the splitting of this representation into finite‐dimensional multiplets, first of which are in full agreement with the experimentally observable composition of electron shells of atoms, and retains the physical meaning of quantum numbers that define electron states. ©1999 John Wiley & Sons, Inc. Int J Quant Chem 72: 499–508, 1999     

Some solved problems of the periodic system of chemical elements

Basic questions on the periodic system (PS) of chemical elements are still under discussion. Several common misconceptions will be resolved. The word “chemical element” comprises more than two concepts. The PS can be rationalized on a quantum chemical basis, namely with the aid of four concepts: (1) electron configurations of bonded atoms, (2) realistic sequences of orbital energies, (3) spatial extension of valence and Rydberg orbitals, and (4) energy gaps above the closed 1s² and np⁶ shells (n = 2–6). The PS of known elements cannot be naively extrapolated. The common discussion of the PS in textbooks of general, inorganic, and physical chemistry needs revision. © 2009 Wiley Periodicals, Inc. Int J Quantum Chem, 2010     

A regular periodic table of the elements and its quantum mechanical requirement

By using the n + (1/2)l filling rule of the atomic Aufbau principle, where n is the principal quantum number and l is the azimuthal quantum number, a new periodic table is presented, its periods having, in order, 8, 18, 18, 32, 42, 50, … elements. The mentioned rule is proposed instead of the n + l rule (or Madelung's rule) which constitutes the quantum mechanical basis of the current periodic table and predicts periods having, in order, 2, 8, 8, 18, 18, 32, 32, 50, … elements. The new periodic table is called “regular” because its groups are formed according to a single rule (namely, the first elements of each period are placed in the same order as the elements of the preceding period), in contrast with the current periodic table, where no simple rule can be applied for the same purpose. The most characteristic feature of the regular periodic table is the fact that its groups are also related in a periodic manner.     

Application of a new formulation of the periodic law to predicting the proton affinity of elements

To illustrate the efficiency of a previously proposed new formulation of the Periodic Law, the proton affinities and gas-phase basicities of 20 elements in the p- and d-blocks were predicted. These properties were considered as a function of the total number of p- or d-electrons in an atom, rather than depending on the nuclear charge or the number of outer-shell electrons. The analysis was performed block by block separately. For p elements, the kainosymmetry and additional periodicity were taken into account. Equations were deduced and then used for predicting the proton affinities and gas-phase basicities of p ⁴–p ⁶ elements (Se, Te, Po, At, and Rn) and d ²–d ¹⁰ elements (Zr, Nb, Mo, Tc, Ag, Cd, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg).     

Affinity of the elements in group VI of the periodic table to tumors and organs]

In order to investigate the tumor affinity radioisotopes, chromium (51Cr), molybdenum (99Mo), tungsten (181W), selenium (75Se) and tellurium (127mTe)--the elements of group VI in the periodic table--were examined, using the rats which were subcutaneously transplanted with Yoshida sarcoma. Seven preprarations, sodium chromate (Na251CrO4), chromium chloride (51CrCl3), normal ammonium molybdate ((NH4)299MoO7), sodium tungstate (Na2181WO4), sodium selenate (Na275SeO4), sodium selenite (Na275SeO3) and tellurous acid (H2127mTeO3) were injected intravenously to each group of tumor bearing rats. These rats were sacrificed at various periods after injection of each preparation: 3 hours, 24 hours and 48 hours in all preparations. The radioactivities of the tumor, blood, muscle, liver, kidney and spleen were measured by a well-type scintillation counter, and retention values (in every tissue including the tumor) were calculated in percent of administered dose per g-tissue weight. All of seven preparations did not have any affinity for malignant tumor. Na251CrO4 and H2127mTeO3 had some affinity for the kidneys, and Na275SeO3 had some affinity for the liver. Na2181WO4 and (NH4)299MoO4 disappeared very rapidly from the blood and soft tissue, and about seventy-five percent of radioactivity was excreted in urine within first 3 hours.     

Fractional sublimation of the β-diketone chelates of the lanthanide and related elements

Various β-diketone chelates of Sc(III), Y(III), Th(IV), U(IV). U(VI), Zr(IV) and the lanthanides have been prepared, characterized and investigated to determine if they were volatile and stable. The ligands employed were acetylacetone(AA), trifluoroacetylacetone(TFAA), hexafluoroacetylacetone(HFAA), and dipivaloyl-methane(DPM). The chelates were sublimed in a fractional vacuum sublimator and the recrystallization temperature zones recorded for individual chelates. None of the lanthanide acetylacetonates arc volatile but the Sc(III), Th(IV), U(IV) and dioxouranium(VI) acetylacetonates are thermally stable and quite volatile below 150° at 1 mm mercury pressure. The lanthanide, Sc(III), Y(III), and dioxouranium(VI) trifluoroacetylacetonates are volatile and can be vacuum-sublimed below 150°, but are thermally unstable; only the Th(IV) chelate is sufficiently stable to be quantitatively recovered by sublimation. The Sc(III), Y(III), Th(IV), and lanthanide hexafluoroacetylacetonates are thermally stable and easily sublimed below 125° in vacua or at atmospheric pressure. All the dipivaloylmethanates studied were thermally stable and volatile and could be quantitatively recovered by vacuum sublimation below 140°.The volatility of the HFAA and DPM lanthanide chelates increased with an increase in atomic weight (a decrease in ionic radii) of the lanthanides. The lack of volatility observed for the lanthanide AA and TFAA chelates is attributed to the fact that only hydrates of the chelates were formed, which decomposed at elevated temperatures in vacuo to form basic polymeric compounds.Separations are proposed for numerous binary mixtures of the β-diketone chelates of the lanthanide and related elements. Recrystallization temperature zones are given for the following binary mixtures which were quantitatively resolved by the fractional sublimation technique; 118-88° for Nd(DPM)₃ and 84-48° for Tm(DPM)₃; 72-49° for Sc(DPM) and 120-88° for Pr(DPM); 128-79° for La(DPM)₃ and 79-47° for Yb(DPM)₃; 70-47° for Th(TFAA)₄ and 116-96° for Gd(TFAA)₃; 52-42° for Th(HFAA)₄ and 120-80° for La(HFAA)₃.