Béla Noszál

Electrodeless, accurate pH determination in highly basic media using a new set of 1H NMR pH indicators

A set of indicator molecules was selected and applied to elaborate an NMR-based pH determination method, free of glass electrode errors in highly basic media. Accurate measurement of pH values and protonation constants was achieved by a successive build-up of overlapping, increasingly high pH solutions, using a collection of 8 compounds of appropriately incremented basicities. In order to verify the method, acid-base properties were quantified for two compounds with very high basicities in conflicting reports: two pharmaceutically important biguanidine drugs, metformin and phenformin.

Triprotic site-specific acid–base equilibria and related properties of fluoroquinolone antibacterials

The complete macro- and microequilibrium analyses of six fluoroquinolone drugs - ciprofloxacin, enrofloxacin, norfloxacin, pefloxacin, ofloxacin and moxifloxacin - are presented. Previous controversial literature data are straightened up, the protonation centers are unambiguously identified, and the protonation macro- and microconstant values are reported. The macroconstants were determined by (1)H NMR-pH titrations while the microconstants were determined by a multi-modal spectroscopic-deductive methodology, in which methyl ester derivatives were synthesized and their NMR-pH titration data contributed to the evaluation of all the microconstants. The full (1)H, (13)C and (15)N NMR assignments, NMR-pH profiles, macro- and microprotonation schemes and species-specific diagrams are included. Our studies show that the fluoroquinolones have three protonation centers: the carboxylate group, the N-1 and N-4 piperazine nitrogens and concentration of the uncharged microspecies is way below the values published earlier. The results could be well interpreted in terms of structural properties. The protonation macro- and microconstant values allow the pre-planned method development in techniques such as capillary zone electrophoresis and also, the interpretation of fluoroquinolone mechanism of biological action, including the pharmacokinetic properties, and antibacterial activities that are all heavily influenced by the states of protonation.

Drug delivery: a process governed by species-specific lipophilicities.

Drug delivery is a cascade of molecular migration processes, in which the active principle dissolves in and partitions between several biological media of various hydrophilic and lipophilic character. Membrane penetration and other partitions are controlled by a number of physico-chemical parameters, the eminent ones are species-specific basicity and lipophilicity. Latter is a molecular property of immense importance in pharmacy, bio-, and medicinal chemistry, expressing the affinity of the molecule for a lipophilic environment. This review gives an overview of the types and definitions of the partition coefficient, the most widespread lipophilicity parameter, focusing on the species-specific (microscopic) partition coefficients. We survey the pertinent literature and summarize our recent works that enabled the determination of previously inaccessible species-specific partition coefficients for coexisting, inseparable protonation isomers too. This thorough insight provides explanation why some drugs unexpectedly get into the central nervous system and sheds some light on the submolecular mechanism of pharmacokinetic processes. The contribution of the various ionic forms to the overall partition can now be quantitated. As a result, there is clear-cut evidence that passive diffusion into lipophilic media is not necessarily predominated by the non-charged species, contrary to the widespread misbelief.

Equilibrium and structural characterization of ofloxacin–cyclodextrin complexation

The enantiomer-specific characterization of ofloxacin–cyclodextrin complexes was carried out by a set of complementary analytical techniques. The apparent stability constants of the ofloxacin enantiomers with 20 different cyclodextrins at two different pH values were determined to achieve good resolution capillary electrophoresis enantioseparation either to establish enantioselective drug analysis assay, or to interpret and design improved host–guest interactions at the molecular level. The cyclodextrins studied differed in the nature of substituents, degree of substitution (DS), charge and purity, allowing a systematic test of these properties on the complexation. The seven-membered beta-cyclodextrin and its derivatives were found to be the most suitable hosts. Highest stability and best enantioseparation were observed for the carboxymethylated-beta-cyclodextrin (DSxa0~xa03.5). The effect of substitution pattern (SP) was investigated by molecular modeling, verifying that SP greatly affects the complex stability. Induced circular dichroism was observed and found especially significant on carboxymethylated-beta-cyclodextrin. The complex stoichiometry and the geometry of the inclusion complexes were determined by 1H NMR spectroscopy, including 2D ROESY techniques. Irrespective of the kind of cyclodextrin, the complexation ratio was found to be 1:1. The alfa-cyclodextrin cavity can accommodate the oxazine ring only, whereas the whole tricyclic moiety can enter the beta- and gamma-cyclodextrin cavities. These equilibrium and structural information offer molecular basis for improved drug formulation.

The complete microspeciation of arginine and citrulline

(1)H NMR-pH titrations of arginine, the most basic natural amino acid and citrulline, its neutral counterpart were carried out. Two other closely related auxiliary compounds were also studied. The 8 macroscopic protonation constants were determined. Combining the four datasets in a deductive method, all the 12 microconstants of arginine, the 4 microconstants of citrulline and arginine amide were calculated. An error-propagation analysis and the pH-dependent distribution of the 8 arginine microspecies are provided.

Lipophilicity of morphine microspecies and their contribution to the lipophilicity profile

The complete set of experimental microscopic partition coefficients of morphine was determined for the first time for any compound. The acid-base microequilibria were characterized by combining pH-potentiometry and deductive methods using auxiliary compounds of reduced complexity. The results show around three times as many non-charged than zwitterionic microspecies in aqueous solution. Partition of the individual microspecies was mimicked by model compounds of the closest possible similarity, then correction factors were determined and introduced. Thus the intrinsic partition coefficients of all the microspecies could be quantitated, including the non-charged and the zwitterionic ones. The non-charged microspecies is 1070 times as lipophilic as its zwitterionic protonation isomer. Their contribution ratio to the overall lipophilicity is 3090. The lipophilicity profile of morphine was expressed, calculated and depicted in terms of species-specific lipophilicities over the entire pH range.

Lipophilicity of zwitterions and related species: A new insight

The experimental determination of microscopic partition coefficients for protonation isomers is elaborated for the first time, and applied for niflumic acid, an ampholytic, mainly zwitterionic drug for pains in joints and muscles. The acid-base microequilibria of niflumic acid are also characterized by NMR-pH and deductive methods using auxiliary compounds of reduced complexity. The results show that 16 times as many zwitterionic than non-charged microspecies exist in aqueous solution. Partition of the individual microspecies was mimicked by model compounds of the closest possible similarity, then correction factors were also determined and introduced. Thus the long-awaited intrinsic partition coefficients of the non-charged vs. zwitterionic species could be calculated. The non-charged microspecies is 390 times as lipophilic as its zwitterionic protonation isomer. The microscopic partition coefficients are also in line with the experimentally determined distribution coefficients. These results make evident that contribution of the zwitterionic microspecies to the overall lipophilicity is not negligible, especially at the isoelectric pH region of the compound.

Triprotic acid–base microequilibria and pharmacokinetic sequelae of cetirizine

(1)H NMR-pH titrations of cetirizine, the widely used antihistamine and four related compounds were carried out and the related 11 macroscopic protonation constants were determined. The interactivity parameter between the two piperazine amine groups was obtained from two symmetric piperazine derivatives. Combining these two types of datasets, all the 12 microconstants and derived tautomeric constants of cetirizine were calculated. Upon this basis, the conflicting literature data of cetirizine microspeciation were clarified, and the pharmacokinetic absorption-distribution properties could be interpreted. The pH-dependent distribution of the microspecies is provided.

Species-specific lipophilicity of thyroid hormones and their precursors in view of their membrane transport properties

A total of 30 species-specific partition coefficients of three thyroid hormones (thyroxine, liothyronine, reverse liothyronine) and their two biological precursors (monoiodotyrosine, diiodotyrosine) are presented. The molecules were studied using combined methods of microspeciation and lipophilicity. Microspeciation was carried out by (1)H NMR-pH and UV-pH titration techniques on the title compounds and their auxiliary derivatives of reduced complexity. Partition of some of the individual microspecies was mimicked by model compounds of the closest possible similarity, then correction factors were determined and introduced. Our data show that the iodinated aromatic ring system is the definitive structural element that fundamentally determines the lipophilicity of thyroid hormones, whereas the protonation state of the aliphatic part plays a role of secondary importance. On the other hand, the lipophilicity of the precursors is highly influenced by the protonation state due to the relative lack of overwhelmingly lipophilic moieties. The different logp values of the positional isomers liothyronine and reverse liothyronine represent the importance of steric and electronic factors in lipophilicity. Our investigations provided clear indication that overall partition, the best membrane transport - predicting physico-chemical parameter depends collectively on the site-specific basicity and species-specific partition coefficient. At physiological pH these biomolecules are strongly amphipathic due to the lipophilic aromatic rings and hydrophilic amino acid side chains which can well be the reason why thyroid hormones cannot cross membranes by passive diffusion and they are constituents of biological membranes. The lipophilicity profile of thyroid hormones and their precursors are calculated and depicted in terms of species-specific lipophilicities over the entire pH range.

Solubility, Delivery and ADME Problems of Drugs and Drug-Candidates

Description: This comprehensive ebook covers all the aspects of ADME/PK modeling including solubility, absorption, formulation, metabolic stability, drug-drug interaction potential and a special delivery tool of drug candidates. The book provides an integrated view of fundamental ADME issues and challenges in early drug development from the aspect of practicing drug researchers. It also provides valuable help for the medicinal chemist in the process of multiple optimization.