ABSTRACT
Alkylzinc alkoxides, [RZnOR']4, have received much attention as efficient precursors of ZnO nanocrystals (NCs), and their "Zn4O4 " heterocubane core has been regarded as a "preorganized ZnO". A comprehensive investigation of the synthesis and characterization of a new family of tert-butyl(tert-butoxy)zinc hydroxides, [(tBu)4 Zn4 (µ3-OtBu)x (µ3-OH)4-x], as model single-source precursors of ZnO NCs is reported. The direct reaction between well-defined [tBuZnOH]6 (16) and [tBuZnOtBu]4 (24) in various molar ratios allows the isolation of new mixed cubane aggregates as crystalline solids in a high yield: [(tBu)4 Zn4 (µ3-OtBu)3 (µ3-OH)] (3), [(tBu)4Zn4 (µ3-OtBu)2 (µ3-OH)2] (4), [(tBu)4 Zn4 (µ3-OtBu)(µ3-OH)3] (5). The resulting products were characterized in solution by (1) Hâ NMR and IR spectroscopy, and in the solid state by single-crystal X-ray diffraction. The thermal transformations of 2-5 were monitored by in situ variable-temperature powder X-ray diffraction and thermogravimetric measurements. The investigation showed that the Zn-OH groups appeared to be a desirable feature for the solid-state synthesis of ZnO NCs that significantly decreased the decomposition temperature of crystalline precursors 3-5.
ABSTRACT
The synthesis of vitamin B12 derivatives for selective orthogonal conjugation at both the Co center and 5'-OH is reported. Newly developed, reduction-free, direct alkynylation of vitamin B12 at the central cobalt ion proved to be versatile, with the formed acetylides, unlike other metalloorganic derivatives, showing remarkable heat and light stability, thus making them promising candidates as a drug carrier. Subsequently, high-yielding functionalization can be achieved via a sequence of selective [1,3] dipolar azide-alkyne cycloadditions (AACs) or carbamate formation followed by AAC.
Subject(s)
Alkynes/chemistry , Cobalt/chemistry , Drug Carriers/chemistry , Vitamin B 12/chemical synthesis , Cycloaddition Reaction , Molecular Structure , Vitamin B 12/chemistryABSTRACT
A straightforward, reduction-free method for the synthesis of organometallic cobalamins has been developed. Stable phenylacetylide derivatives were characterized by X-ray analysis, showing a pronounced influence of the electronic nature of substituents on their structure.