Stereolability of dihydroartemisinin, an antimalarial drug: a comprehensive kinetic investigation. Part 2.

Artemisinin or qinghaosu has now largely given way to the more potent dihydroartemisinin (DHA, 1) and its derivatives in the treatment of drug-resistant malaria, in combination with other classical antimalarial drugs. DHA is obtained by NaBH(4) reduction of artemisinin and contains a stereochemically labile center at C-10, which provided two lactol hemiacetal interconverting epimers, namely 1α and 1ß. In the solid state, the drug consists exclusively of the ß-epimer; however, upon dissolution, the two epimers equilibrate, reaching different solvent-dependent ratios with different rates. Such equilibration also occurs in vivo, irrespective of the isomeric purity at which the drug would have been administered. The aim of this study was then to achieve an in-depth understanding of the kinetic features of the α/ß equilibration. To this purpose, free energy activation barriers (ΔG(‡)) of the interconversion were determined as a function of both general and specific acid and base catalysts, ionic strength, and temperature in different solvents by dynamic HPLC (DHPLC). In hydro-organic media, the dependence of ΔG(‡) on temperature led to the evaluation of the related enthalpic and entropic contributions. Theoretical calculations suggested that the rate-determining step of the interconversion is not the ring-opening of the cyclic hemiacetal but the previous reversible deprotonation of the individual epimers (base-catalyzed mechanism). The whole findings may contribute to shed some light on the mechanism of action and/or bioavailability of the drug at the molecular level.

Stereolability of dihydroartemisinin, an antimalarial drug: a comprehensive thermodynamic investigation. Part 1.

Artemisinin (Qinghaosu, 1) is a sesquiterpene lactone endoperoxide isolated from Artemisia annua L. that Chinese herbalists have traditionally used to treat malaria. Reduction of artemisinin by NaBH(4) produced dihydroartemisinin (DHA, 2) and yielded a new stereochemically labile center at C-10, which in turn provided two lactol hemiacetal interconverting epimers, namely, 2α and 2ß. With the aim of fully investigating the thermodynamics of interconversion, we gathered the relative abundance of the two epimers within a wide variety of solvents and rationalized the results by linear solvation energy relationships (LSER) analysis. Beside the difference in polarity, the better stabilization of 2α in polar solvents was found to be significantly related to its greater acidity with respect to 2ß, which was estimated by two independent theoretical approaches based on molecular modeling calculations and empirical data, and supported by (1)H NMR measurements. On the contrary, differential effects of cavitational energy have been highlighted as interactions strongly responsible for the small values of equilibrium constant measured for the ß â‡† α process in the less polar media. Determination of forward and backward epimerization rate constants in seven media, clearly differing in both permittivity and capacity to be H-bond donors, indicated that, in the spontaneous process, the transition state of the rate-limiting step develops a significant degree of anionic character, as typically happens in the base-catalyzed breakdown of hemiacetals.

Stereodynamic investigation of labile stereogenic centres in dihydroartemisinin.

Since its identification in the early 1970s, artemisinin, as well as semi-synthetic derivatives and synthetic trioxanes, have been used in malaria therapy. Reduction of artemisinin by NaBH4 produced dihydroartemisinin (DHA), and yielded a new stereochemically labile centre at C-10, which, in turn, provided two interconverting lactol hemiacetal epimers (namely alpha and beta), whose rate of interconversion depends on buffer, pH, and solvent polarity. Since interconversion of the two epimers occurred on a chromatographic time-scale, this prompted a thorough investigation of the phenomenon as a crucial requisite of any analytical method aimed at quantitating this family of drugs. In this critical review we discuss the current importance of the on-column epimerization of DHA in the development of analytical methods aimed at quantifying the drug, with the purpose of identifying the optimal conditions to minimize on-column epimerization while achieving the best selectivity and efficiency of the overall separation.

Specific targeting of highly conserved residues in the HIV-1 reverse transcriptase primer grip region. 2. Stereoselective interaction to overcome the effects of drug resistant mutations.

Starting from the prototypic compound 4, we describe new, potent, and broad-spectrum pyrrolobenzo(pyrido)oxazepinones antivirals. A biochemical and enzymological investigation was performed for defining their mechanism of inhibition at either recombinant HIV-1 RT wild type and non-nucleoside reverse transcriptase inhibitors (NNRTIs)-resistant mutants. For the novel compounds (S)-(+)-5 and (S)-(-)-7, a clear-cut stereoselective mechanism of enzyme inhibition was found. Molecular modeling studies were performed for revealing the underpinnings of this behavior.

On-column epimerization of dihydroartemisinin: an effective analytical approach to overcome the shortcomings of the International Pharmacopoeia monograph.

We developed a cryo-HPLC/UV method for the simultaneous determination of artemisinin (1), alpha-dihydroartemisinin (2alpha), beta-dihydroartemisinin (2beta), and a ubiquitous thermal decomposition product of 2 (designated as diketoaldehyde, 3), starting from the International Pharmacopoeia monograph on dihydroartemisinin. The method takes for the first time the on-column epimerization process of 2 into consideration. Chromatographic separation was obtained under reversed-phase conditions on a Symmetry C18 column (3.5 microm particle size) with a mobile phase consisting of acetonitrile-water 60:40 (v/v), delivered at 0.60-1.00 ml/min flow-rates, with ultraviolet detection at low wavelength (lambda = 210 nm). Low temperatures (T = 0-10 degrees C) were selected on the grounds of a diastereoselective dynamic HPLC (DHPLC) study performed at different temperatures, aimed at identifying the best experimental conditions capable of minimizing the on-column interconversion process.