Potential antidiabetic molecule involving a new chromium(III) complex of dipicolinic and metformin as a counter ion: Synthesis,structure, spectroscopy,and bioactivity in mice

The chromium(III) complex, Cr(C₇H₃NO₄)₂·C₄H₁₂N₅ (1), was synthesised by chelating chromium with dipicolinic (H₂dipic) in methanol, and its structure was characterised using elemental analysis (EA), spectroscopy (infrared, UV–visible, and fluorescence) and single-crystal X-ray method. The density functional theoretical (DFT) computation was performed using the Gaussian 09 package. The stability of solution at different temperatures and pH values, the electrochemical, morphological and thermal properties of complex 1 were discussed. The preliminary bioactivities of complex 1 in streptozotocin (STZ)-induced type 2 diabetes mellitus (T2DM) mice were investigated using daily oral gavage for 12 weeks. The cytotoxicity was assessed using the methyl thiazolyl tetrazolium (MTT) assays, and the acute toxicity experiment test was carried out on healthy C57BL/6 mice with this complex. The complex 1 crystallised in the monoclinic system with the space group P2(1)/n, R₁ = 0.0642. The DFT-optimised structure of complex 1 was in excellent agreement with the X-ray crystal structure. The complex 1 exhibited good physical and chemical properties and beneficial function on blood glucose and lipid metabolism for T2DM. The antidiabetic activity of chromium(III) might be associated with chromium(VI). Furthermore, the cytotoxicity and the acute toxicity experiments showed that the complex 1 was hypotonic and secure to organism. The study of complex 1 showed that the prepared complex on the basis of H₂dipic and Met could inhibit hyperglycaemia and hyperlipidaemia in vivo and did not have potential toxicity. These results demonstrated that the complex 1 might provide an important reference for the development of functional hypoglycaemic foods or pharmaceuticals of T2DM.     

Mollusc-Derived Brominated Indoles for the Selective Inhibition of Cyclooxygenase: A Computational Expedition

Inflammation plays an important role in different chronic diseases. Brominated indoles derived from the Australian marine mollusk Dicathais orbita (D. orbita) are of interest for their anti-inflammatory properties. This study evaluates the binding mechanism and potentiality of several brominated indoles (tyrindoxyl sulfate, tyrindoleninone, 6-bromoisatin, and 6,6′-dibromoindirubin) against inflammatory mediators cyclooxygenases-1/2 (COX-1/2) using molecular docking, followed by molecular dynamics simulation, along with physicochemical, drug-likeness, pharmacokinetic (pk), and toxicokinetic (tk) properties. Molecular docking identified that these indole compounds are anchored, with the main amino acid residues, positioned in the binding pocket of the COX-1/2, required for selective inhibition. Moreover, the molecular dynamics simulation based on root mean square deviation (RMSD), radius of gyration (Rg), solvent accessible surface area (SASA), and root mean square fluctuation (RMSF) analyses showed that these natural brominated molecules transit rapidly to a progressive constant configuration during binding with COX-1/2 and seem to accomplish a consistent dynamic behavior by maintaining conformational stability and compactness. The results were comparable to the Food and Drug Administration (FDA)-approved selective COX inhibitor, aspirin. Furthermore, the free energy of binding for the compounds assessed by molecular mechanics–Poisson–Boltzmann surface area (MM–PBSA) confirmed the binding capacity of indoles towards COX-1/2, with suitable binding energy values except for the polar precursor tyrindoxyl sulfate (with COX-1). The physicochemical and drug-likeness analysis showed zero violations of Lipinski’s rule, and the compounds are predicted to have excellent pharmacokinetic profiles. These indoles are projected to be non-mutagenic and free from hepatotoxicity, with no inhibition of human ether-a-go–go gene (hERG) I inhibitors, and the oral acute toxicity LD₅₀ in rats is predicted to be similar or lower than aspirin. Overall, this work has identified a plausible mechanism for selective COX inhibition by natural marine indoles as potential therapeutic candidates for the mitigation of inflammation.