The invention provides metal-peptoid complexes for use as electrocatalyst in water oxidation processes.

##STR00001##

The invention relates to platinum and rhenium complexes of formula (I) that may be used as imaging agents. In particular, the invention relates to imaging agents, for example imaging agents for use in the imaging of peroxisomes. Certain embodiments of the invention relate to compounds per se. Other embodiments relate to a process for the preparation of compounds and to the use of compounds as imaging agents. (Formula (I))

##STR00001##

The invention relates to platinum and rhenium complexes of formula (I) that may be used as imaging agents. In particular, the invention relates to imaging agents, for example imaging agents for use in the imaging of peroxisomes. Certain embodiments of the invention relate to compounds per se. Other embodiments relate to a process for the preparation of compounds and to the use of compounds as imaging agents. (Formula (I))

Organometallic compounds comprising a chloroquinoline moiety and uses of the compounds. The compounds are, for example, manganese or rhenium complexes of a ligand comprising a chloroquinoline moiety. The compounds can be used in, for example, methods of inhibiting cell growth.

Organometallic compounds comprising a chloroquinoline moiety and uses of the compounds. The compounds are, for example, manganese or rhenium complexes of a ligand comprising a chloroquinoline moiety. The compounds can be used in, for example, methods of inhibiting cell growth.

A method of making a polyfunctional polyfluorinated compound includes combining first components that include a polyfluorinated cyclic compound having 4 to 7 ring carbon atoms and at least one of osmium tetroxide, ruthenium tetroxide or a precursor thereof and forming a polyfluorinated dicarboxylic acid. Two of the ring carbon atoms of the polyfluorinated cyclic compound form a double bond or an epoxide. The precursor reacts with an oxidant to form ruthenium tetroxide. Methods also include converting the polyfluorinated dicarboxylic acid to a polyfluorinated dicarboxylic acid halide and converting the polyfluorinated dicarboxylic acid halide to other polyfunctional polyfluorinated compounds.

A method of making a polyfunctional polyfluorinated compound includes combining first components that include a polyfluorinated cyclic compound having 4 to 7 ring carbon atoms and at least one of osmium tetroxide, ruthenium tetroxide or a precursor thereof and forming a polyfluorinated dicarboxylic acid. Two of the ring carbon atoms of the polyfluorinated cyclic compound form a double bond or an epoxide. The precursor reacts with an oxidant to form ruthenium tetroxide. Methods also include converting the polyfluorinated dicarboxylic acid to a polyfluorinated dicarboxylic acid halide and converting the polyfluorinated dicarboxylic acid halide to other polyfunctional polyfluorinated compounds.

A diazadienyl compound represented by General Formula (I) below: ##STR00001##
wherein R.sup.1 represents a C.sub.1-6 linear or branched alkyl group, and M represents nickel atom or manganese atom. In particular, since a compound in which R.sup.1 in General Formula (I) is a methyl group has a high vapor pressure and a high thermal decomposition starting temperature, the compound is useful as a raw material for forming a thin film by a CVD method or ALD method.

Organic luminescent materials containing cycloalkyl ancillary ligands is disclosed, which can be used as emitters in the emissive layer of an organic electroluminescent device. The organic luminescent materials is metal complexes which comprise a new series of cycloalkyl containing acetylacetone type ancillary ligands. These novel ligands can effectively improve the lifetime of the device, change the sublimation characteristics and improve device performance. Also disclosed are an electroluminescent device and a formulation.

Organic luminescent materials containing cycloalkyl ancillary ligands is disclosed, which can be used as emitters in the emissive layer of an organic electroluminescent device. The organic luminescent materials is metal complexes which comprise a new series of cycloalkyl containing acetylacetone type ancillary ligands. These novel ligands can effectively improve the lifetime of the device, change the sublimation characteristics and improve device performance. Also disclosed are an electroluminescent device and a formulation.