Chemistry and insulin-mimetic properties of bis(acetylacetonate)oxovanadium(IV) and derivatives

The syntheses and the solid state structural and spectroscopic solution characterizations of VO(Me-acac)(2) and VO(Et-acac)(2) (where Me-acac is 3-methyl-2,4-pentanedionato and Et-acac is 3-ethyl-2,4-pentanedionato) have been conducted since both VO(acac)(2) and VO(Et-acac)(2) have long-term in vivo insulin-mimetic effects in streptozotocin-induced diabetic Wistar rats. X-ray structural characterizations of VO(Me-acac)(2) and VO(Et-acac)(2) show that both contain five-coordinate vanadium similar to the parent VO(acac)(2). The unit cells for VO(Et-acac)(2) and VO(Me-acac)(2) are both triclinic, P (1) over bar, with a 9.29970(10) Angstrom, b = 13.6117(2) Angstrom, c 13.6642(2) Angstrom, alpha = 94.1770(10)degrees,beta = 106.4770(10)degrees, gamma = 106.6350(10)degrees for VO(Et-acac)(2) and a = 7.72969(4) Angstrom, b = 8.1856(5) Angstrom, 11.9029(6) Angstrom, alpha = 79.927(2)degrees, beta = 73.988(2)degrees, gamma = 65.1790(10)degrees For VO(Me-acac)(2). The total concentration of EPR-observable vanadium(IV) species for VO(acac)(2) and derivatives in water solution at 20 degrees C was determined by double integration of the EPR spectra and apportioned between individual species on the basis of computer simulations of the spectra. Three species were observed, and the concentrations were found to be time, pH, temperature, and salt dependent. The three complexes are assigned as the trans-VO(acac)(2). H2O adduct, cis-VO-(acac)(2). H2O adduct, and a hydrolysis product containing one vanadium atom and one R-acac(-) group. The reaction rate for conversion of species was slower for VO(acac)(2) than for VO(malto)(2), VO(Et-acac)(2), and VO(Me-acac)(2); however, in aqueous solution the rates for all of these species are slow compared to those of other vanadium species. The concentration of vanadium(V) species was determined by V-51 NMR, The visible spectra were time dependent, consistent with the changes in species concentrations that were observed in the EPR and NMR spectra. EPR and visible spectroscopic studies of solutions prepared as for administration to diabetic rats documented both a salt effect on speciation and formation of a new halogen-containing complex. Compound efficacy with respect to long-term lowering of plasma glucose levels in diabetic rats traces the concentration of the hydrolysis product in the administration solution.