SYNTHESIS AND STRUCTURE OF AN IRON(III) SULFIDE-FERRITIN BIOINORGANICNANOCOMPOSITE

Amorphous iron sulfide minerals containing either 500 or 3000 iron ato ms in each cluster have been synthesized in situ within the nanodimens ional cavity of horse spleen ferritin. Iron-57 Mossbauer spectroscopy indicated that most of the iron atoms in the 3000-iron atom cores are trivalent, whereas in the 500-iron atom clusters, approximately 50 per cent of the iron atoms are Fe(III), with the remaining atoms having an effective oxidation state of about +2.5. Iron K-edge extended x-ray a bsorption fine structure data for the 500-iron atom nanocomposite are consistent with a disordered array of edge-shared FeS4 tetrahedra, con nected by Fe(S)(2)Fe bridges with bond lengths similar to those of the cubane-type motif of iron-sulfur clusters. The approach used here for the controlled synthesis of bioinorganic nanocomposites could be usef ul for the nanoscale engineering of dispersed materials with biocompat ible and bioactive properties.