The electrochemical oxidation ((+)Pt-Ni(-)/NH(4)Br/MeOH) of the natural product hispanolone (1a) produced, in high yield (>95%), spiro-tetracyclic compounds 7a-7d as a result of the intramolecular addition of the C-9 hydroxyl group into the C-16 position with the simultaneous addition of a CH(3)O group at the C-15 position of the hispanolone furan moiety. After the electrochemical oxidation, an acid-catalyzed slow secondary reaction occurred producing the previously undescribed alpha-butenolide derivative, iso-Leopersin G (9). An anti-inflammatory study with the electro-synthesized compounds showed that 1a has higher anti-inflammatory properties with very low cytotoxicity (e.g., the inhibition of TPA-induced ear edema assay IC(50) = 1.05 microM/ear, positive control indomethacin IC(50) = 0.27 microM/ear).
γ-Aminobutyric acid (GABA) is the most important inhibitory neurotransmitter in the central nervous system, and a deficiency of GABA is associated with serious neurological disorders. Due to its low lipophilicity, there has been an intensive search for new molecules with increased lipophilicity to cross the blood-brain barrier to raise GABA concentrations. We have designed and evaluated in vitro and in silico some new analogues of GABA, where the nitrogen atom at the γ-position is embedded in heterocyclic scaffolds and determined their inhibitory potential over the GABA-AT enzyme from Pseudomonas fluorescens. These modifications lead to compounds with inhibitory activity as it occurs with compounds 18a and 19a. The construction of Pseudomonas fluorescens and human GABA-AT models were carried out by homology modeling. Docking assays were done for these compounds over the GABA-AT enzyme models where 19a showed a strong interaction with both GABA-AT enzymes.
:
Anticonvulsants are drugs used in the treatment of seizures, their pharmacology includes promoters
of brain inhibition and inhibitors of brain activity; Of the latter, voltage-dependent sodium channel blockers (VGSCB) are
the most widely used in therapeutics.
Objective:
To propose the structural requirements of VGSC blockers through a quantitative structure-activity relationship
analysis of drugs with proven activity.
Methods:
IC50 values of anticonvulsant drugs on VGSCs were considered under similar experimental conditions; some
physicochemical properties of the molecules that were correlated with their biological activity were determined in silico.
Results:
Relationships were found between the dipole moment, pKa, EHOMO, and MR with the biological activity, which infers that between greater polarity and basicity of the drugs, their activity as blockers will increase. Subsequently, the structural subclassification of the drugs was carried out, based on the urea derivation, the groups of which were: Group 1 (direct
and bioisoster derivatives) and Group 2 (homologue and vinylogue derivatives of urea).
Conclusion:
The biological activity depends on the polarity, basicity, and electronic density of the drugs. The derivation of
urea is essential, which is present in its original substituted form or a bioisosteric form. Urea can be in the form of a homologue or a vinylogue at the ends of the molecule. Aromatic substitution to the urea portion is necessary.
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