The metallobiochemistry of ultratrace levels of platinum group elements in the rat.

The use of platinum, palladium and rhodium (Platinum Group Elements - PGEs) and the possibility of exposure to their ultratrace levels is increasing. In fact, the exponential development of metallic PGE-based nanoparticles (<100 nm in size) opens extraordinary perspectives in the areas of electrocatalysts and catalytic converters, magnetic nanopowders, polymer membranes, cancer therapy, coatings, plastics, nanofibres and textiles. Like other metal-based nanoparticles, exposure to PGEs nanoparticles may result in a release of ultratrace amounts of Pt, Pd, Rh ions in the body whose metabolic fate and toxicity still need to be evaluated. Furthermore, PGEs can act as allergic sensitizers by acting as haptens and inducing both type I and IV allergic reactions. In this work we studied the in vivo metabolic patterns of ultratrace levels of potent allergens and sensitizers PGE halogenated salts. (191)Pt, (103)Pd and (101m)Rh radioisotopes were prepared via cyclotron irradiation and used for radiolabelling Na2(191)PtCl4, Na2(103)PdCl4 and Na2(101m)RhCl6 salts. These anionic chlorocomplexes were intraperitoneally injected into rats (114 ng Pt kg(-1) bodyweight; 24 ng Pd kg(-1) b.w.; 16 ng Rh kg(-1) b.w.). At 16 h post-exposure, PGEs were poorly but significantly retained in all tissues analysed. Kidneys, spleen, adrenal gland, liver, pancreas and small intestine were the organs with the highest Pt, Pd, Rh concentrations. In the blood 30-35% of (103)Pd and (191)Pt and 10% of (101m)Rh were recovered in the plasma, mainly bound to albumin and to a less extent to transferrin. The hepatic and renal intracellular distribution showed the highest recovery of (191)Pt, (103)Pd and (101m)Rh in the nuclear fraction (liver) and in the cytosol (kidney). Chromatographic separation and ultrafiltration experiments on kidney and liver cytosols showed the strong ability of biochemical macromolecules to bind (191)Pt, (103)Pd and (101m)Rh, and being responsible for the retention of the three elements in the body. The link to macromolecules is the basis for the sensitizing capacity of PGEs.

External and internal gelation of pectin solutions: microscopic dynamics versus macroscopic rheology.

Pectin is a natural biopolymer that forms, in the presence of divalent cations, ionic-bound gels typifying a large class of biological gels stabilized by non-covalent cross-links. We investigate and compare the kinetics of formation and aging of pectin gels obtained either through external gelation via perfusion of free Ca(2+) ions, or by internal gelation due to the supply of the same ions from the dissolution of CaCO3 nanoparticles. The microscopic dynamics obtained with photon correlation imaging, a novel optical technique that allows obtaining the microscopic dynamics of the sample while retaining the spatial resolution of imaging techniques, is contrasted with macroscopic rheological measurements at constant strain. Pectin gelation is found to display peculiar two-stage kinetics, highlighted by non-monotonic growth in time of both microscopic correlations and gel mechanical strength. These results are compared to those found for alginate, another biopolymer extensively used in food formulation.

Metabolic fate of ultratrace levels of GeCl(4) in the rat and in vitro studies on its basal cytotoxicity and carcinogenic potential in Balb/3T3 and HaCaT cell linesdagger.

The use of germanium (Ge) and the possibility of exposure to trace and ultratrace amounts of this element is increasing. Germanium is widely used in the industrial field as a semiconductor and also as a dietary supplement, an elixir to 'promote health and cure disease' (e.g. cancer and AIDS). More recently, germanium nanoparticles, ranging in size from 60 to 80 nm, have been developed as a potential spleen imaging agent. Like other metal-based nanoparticles used in nanomedicine, Ge nanoparticles may release trace and ultratrace amounts of Ge ions when injected. The metabolic fate and toxicity of these ions still needs to be evaluated. In this study the metabolic fate of a cationic tetravalent Ge species was studied in vivo by injecting rats i.p. with ultratrace amounts of Ge (80 ng kg(-1)) as [(68)Ge]GeCl(4). The cytotoxicity and carcinogenic potential was assessed in vitro using immortalised human skin keratinocytes and mouse fibroblasts (HaCaT and Balb/c 3T3 cell lines, respectively). At 24 h post-exposure Ge was poorly retained in rat tissues (kidney, liver, intestine, femur, spleen and the heart were the organs with the highest Ge concentration). In the blood, Ge was rapidly cleared, being almost equally distributed between plasma and red blood cells. The excretion was mainly via the urine. The hepatic and renal intracellular distribution showed the highest recovery of Ge in the cytosol and the nuclear fractions. Chromatographic separation and ultrafiltration experiments on kidney and liver cytosols showed that the bulk of Ge was associated with low molecular weight components, representing a 'mobile pool' of the element in the body. However, a significant part of the element was able to interact with biological macromolecules which could be responsible for the presence of Ge in the liver and kidney after 7 days. The in vitro experiments confirmed the low degree of cytotoxicity of GeCl(4) both in HaCaT and Balb/3T3. The latter model was more sensitive to the toxic effects induced by Ge as shown by a colony forming efficiency (CFE) greater than 70% at 700 microm of exposure. At the highest exposure concentration tested (700 microm) GeCl(4) failed to induce morphological neoplastic transformation of the cells, suggesting for the first time that a cationic form of Ge ions has no carcinogenic potential. This supports the results of the only study reported in mice, treated orally long-term to an anionic species of Ge such as sodium germanate (Kanisawa and Schroeder, 1967).