Synthesis and reactivity of cytotoxic platinum(II) complexes of bidentate oximes: a step towards the functionalization of bioactive complexes

Two new platinum(II) complexes bearing triphenylphosphine and bidentate oxime ligands [Pt(Cl)(PPh3){(κ2-N,O)-(1{C(R)=N(OH)-2(O)C10H6})}] (R = H, Me) were synthesized in good yields from trans-[PtCl(μ-Cl)(PPh3)]2. The structure of [Pt(Cl)(PPh3){(κ2-N,O)-(1{CH=N(OH)-2(O)C10H6})}] was determined by single-crystal X-ray diffraction. Both complexes showed good antiproliferative properties in vitro against HeLa, A2780, and A2780cis cancer cell lines. They reacted cleanly with alkylating agents in the presence of aqueous bases under phase-transfer catalysis conditions to afford the corresponding O-alkylation products [Pt(Cl)(PPh3){(κ2-N,O)-(1{HC=N(OR′)-2(O)C10H6})}] [R′ = CH2CH2Cl, CH2Ph, (CH2)4Br] in good yields

Создатели ядерного щита

The first example of a crystallographically established bis-adduct of tridentate 2,2':6',2:6',2"'-quaterpyridine (qtpy) of formula [Fe(qtpy)(2)][ClO4](2) has been obtained by treating an aqueous solution of iron(II) perchlorate with the ligand in the presence of triethylamine

Homodinuclear Lanthanide Complexes with the Divergent Heterotopic 4,4′-Bipyridine N-Oxide (bipyMO) Ligand

The synthesis of dinuclear molecular complexes [Eu2(dbm)6(bipyMO)2], 1, [Tb2(dbm)6(bipyMO)2], 2, [Eu2(tta)6(bipyMO)2], 3 [Eu2(hfac)6(bipyMO)3], 4, [Tb2(hfac)6(bipyMO)3], 5 is here reported (bipyMO = 4,4′-bipyridine N-oxide, Hdbm = dibenzoylmethane, Htta = thenoyltrifluoroacetone, Hhfac = hexafluoroacetylacetone). The products were obtained in mild conditions and with high yields reacting anhydrous lanthanide β-diketonates and bipyMO in 1:1 or 1.5 molar ratio in toluene. X-ray single crystal studies on 2, 3, 4 showed that the heterotopic ligands are hypodentate, bridging the two lanthanide centres exclusively through the oxygen atom. Photoluminescence studies show bright red emissions from europium derivatives with absolute quantum yields up to 44 %

An element through the looking glass: Exploring the Au-C, Au-H and Au-O energy landscape

Gold, the archetypal “noble metal”, used to be considered of little interest in catalysis. It is now clear that this was a misconception, and a multitude of gold-catalysed transformations has been reported. However, one consequence of the long-held view of gold as inert metal is that its organometallic chemistry contains many “unknowns”, and catalytic cycles devised to explain gold's reactivity draw largely on analogies with other transition metals. How realistic are such mechanistic assumptions? In the last few years a number of key compound classes have been discovered that can provide some answers. This Perspective attempts to summarise these developments, with particular emphasis on recently discovered gold(III) complexes with bonds to hydrogen, oxygen, alkenes and CO ligands