Gas chromatographic determination of sparteine and 2- and 5-dehydrosparteine in plasma and urine

Enantioselective pharmacokinetics of tramadol in CYP2D6 extensive and poor metabolizers

OBJECTIVE

To describe in detail the intravenous, single oral and multiple oral dose enantioselective pharmacokinetics of tramadol in CYP2D6 extensive metabolizers (EMs) and poor metabolizers (PMs).

METHODS

Eight EMs and eight PMs conducted three phases as an open-label cross-over trial with different formulations; 150 mg single oral tramadol hydrochloride, 50 mg single oral tramadol hydrochloride every 8 h for 48 h (steady state), 100 mg intravenous tramadol hydrochloride. Urine and plasma concentrations of (+/-)-tramadol and (+/-)-M1 were determined for 48 h after administration.

RESULTS

In all three phases, there were significant differences between EMs and PMs in AUC and t(1/2) of (+)-tramadol (P< or =0.0015), (-)-tramadol (P< or =0.0062), (+)-M1 (P< or =0.0198) and (-)-M1 (P< or =0.0370), and significant differences in C(max) of (+)-M1 (P<0.0001) and (-)-M1 (P< or =0.0010). In Phase A and C, significant differences in t(max) were seen for (+)-M1 (P< or =0.0200). There were no statistical differences between the absolute bioavailability of tramadol in EMs and PMs. The urinary recoveries of (+)-tramadol, (-)-tramadol, (+)-M1 and (-)-M1 were statistically significantly different in EMs and PMs (P<0.05). Median antimodes of the urinary metabolic ratios of (+)-tramadol / (+)-M1 and (-)-M1 were 5.0 and 1.5, respectively, hereby clearly separating EMs and PMs in all three phases.

CONCLUSION

The impact of CYP2D6 phenotype on tramadol pharmacokinetics was similar after single oral, multiple oral and intravenous administration displaying significant pharmacokinetic differences between EMs and PMs of (+)-tramadol, (-)-tramadol, -(+)-M1 and (-)-M1. The O-demethylation of tramadol was catalysed stereospecific by CYP2D6 in the way that very little (+)-M1 was produced in PMs.

Drug disposition of chiral and achiral drug substrates metabolized by cytochrome P450 2D6 isozyme: case studies, analytical perspectives and developmental implications

The concepts of drug development have evolved over the last few decades. Although number of novel chemical entitities belonging to varied classes have made it to the market, the process of drug development is challenging, intertwined as it is with complexities and uncertainities. The intention of this article is to provide a comprehensive review of novel chemical entities (NCEs) that are substrates to cytochrome P450 (CYP) 2D6 isozyme. Topics covered in this review aim: (1) to provide a framework of the importance of CYP2D6 isozyme in the biotransformation of NCEs as stand-alones and/or in conjunction with other CYP isozymes; (2) to provide several case studies of drug disposition of important drug substrates, (3) to cover key analytical perspectives and key assay considerations to assess the role and involvement of CYP2D6, and (4) to elaborate some important considerations from the development point of view. Additionally, wherever applicable, special emphasis is provided on chiral drug substrates in the various subsections of the review.

P450 in the rat and man: methods of investigation, substrate specificities and relevance to cancer

1. Considerable evidence has been accumulated that orthologous rat and human P450 forms oxidize numerous chemicals in a highly similar manner, including the detoxication and activation of mutagens and carcinogens. 2. Nevertheless, certain specific substrates of rat P450s are not so well oxidized by the orthologous human forms, and vice versa. 3. Certain mutagens and carcinogens can be activated in a similar way by different (non-orthologous) forms in rat and man, confirming that studies on animals, directed ultimately to man, can be indicative but not predicative of chemical mutagenesis and carcinogenesis.

Rapid determination of sparteine and its metabolites in urine

A method is presented for the isolation, separation and determination of sparteine and its metabolites in urine. The isolation is based on rapid extraction with dichloromethane and pentane in a glass separator. For the separation and determination, capillary gas chromatography with nitrogen-phosphorus detection was used. The recovery of the method ranged from 81.6% to 94.8%, and the limit of determination varied between 0.2 and 0.5 microgram ml-1. For quantification, 17-ethylsparteine was used as the internal standard.

Lack of pharmacokinetic interaction between nifedipine, sparteine and phenytoin in man

Nifedipine, sparteine and phenytoin were administered orally to eight healthy subjects separately and as a 'cocktail' on four different occasions to investigate any kinetic interactions. All subjects were extensive metabolizers of sparteine. After drug intake plasma and urine samples were collected up to 32 h and the concentrations of parent drugs and main metabolites were measured. Clearances and formation clearances were not significantly different after single substrate and 'cocktail' administration. Low or non significant correlation coefficients were found between the oxidation of the individual substrates or formation of their metabolites. With this strategy of simultaneous administration of substrates ('cocktail') it appears possible to characterize (and correlate) activities of different cytochrome P-450 isoenzymes, without the disturbing influence of intraindividual variation of drug oxidation with time.