thioguanine-anhydrous and 6-thiouric-acid

To develop a method that prospectively assesses adherence rates in paediatric patients with acute lymphoblastic leukaemia (ALL) who are receiving the oral thiopurine treatment 6-mercaptopurine (6-MP).. A total of 19 paediatric patients with ALL who were receiving 6-MP therapy were enrolled in this study. A new objective tool (hierarchical cluster analysis of drug metabolite concentrations) was explored as a novel approach to assess non-adherence to oral thiopurines, in combination with other objective measures (the pattern of variability in 6-thioguanine nucleotide erythrocyte concentrations and 6-thiouric acid plasma levels) and the subjective measure of self-reported adherence questionnaire.. Parents of five ALL patients (26.3%) reported at least one aspect of non-adherence, with the majority (80%) citing "carelessness at times about taking medication" as the primary reason for non-adherence followed by "forgetting to take the medication" (60%). Of these patients, three (15.8%) were considered non-adherent to medication according to the self-reported adherence questionnaire (scored > or = 2). Four ALL patients (21.1%) had metabolite profiles indicative of non-adherence (persistently low levels of metabolites and/or metabolite levels clustered variably with time). Out of these four patients, two (50%) admitted non-adherence to therapy. Overall, when both methods were combined, five patients (26.3%) were considered non-adherent to medication, with higher age representing a risk factor for non-adherence (P < 0.05).. The present study explored various ways to assess adherence rates to thiopurine medication in ALL patients and highlighted the importance of combining both objective and subjective measures as a better way to assess adherence to oral thiopurines.

Topics: Adolescent; Antimetabolites, Antineoplastic; Child; Child, Preschool; Female; Humans; Male; Medication Adherence; Mercaptopurine; Parents; Precursor Cell Lymphoblastic Leukemia-Lymphoma; Thioguanine; Uric Acid

The anticancer drug, 6-mercaptopurine (6MP) is subjected to metabolic clearance through xanthine oxidase (XOD) mediated hydroxylation, producing 6-thiouric acid (6TUA), which is excreted in urine. This reduces the effective amount of drug available for therapeutic efficacy. Co-administration of allopurinol, a suicide inhibitor of XOD, which blocks the hydroxylation of 6MP inadvertently enhances the 6MP blood level, counters this reduction. However, allopurinol also blocks the hydroxylation of hypoxanthine, xanthine (released from dead cancer cells) leading to their accumulation in the body causing biochemical complications such as xanthine nephropathy. This necessitates the use of a preferential XOD inhibitor that selectively inhibits 6MP transformation, but leaves xanthine metabolism unaffected.. Here, we have characterized two such unique inhibitors namely, 2-amino-6-hydroxy-8-mercaptopurine (AHMP) and 2-amino-6-purinethiol (APT) on the basis of IC50 values, residual activity in bi-substrate simulative reaction and the kinetic parameters like Km, Ki, kcat. The IC50 values of AHMP for xanthine and 6MP as substrate are 17.71 +/- 0.29 microM and 0.54 +/- 0.01 microM, respectively and the IC50 values of APT for xanthine and 6MP as substrates are 16.38 +/- 0.21 microM and 2.57 +/- 0.08 microM, respectively. The Ki values of XOD using AHMP as inhibitor with xanthine and 6MP as substrate are 5.78 +/- 0.48 microM and 0.96 +/- 0.01 microM, respectively. The Ki values of XOD using APT as inhibitor with xanthine and 6MP as substrate are 6.61 +/- 0.28 microM and 1.30 +/- 0.09 microM. The corresponding Km values of XOD using xanthine and 6MP as substrate are 2.65 +/- 0.02 microM and 6.01 +/- 0.03 microM, respectively. The results suggest that the efficiency of substrate binding to XOD and its subsequent catalytic hydroxylation is much superior for xanthine in comparison to 6MP. In addition, the efficiency of the inhibitor binding to XOD is much more superior when 6MP is the substrate instead of xanthine. We further undertook the toxicological evaluation of these inhibitors in a single dose acute toxicity study in mice and our preliminary experimental results suggested that the inhibitors were equally non-toxic in the tested doses.. We conclude that administration of either APT or AHMP along with the major anti-leukemic drug 6MP might serve as a good combination cancer chemotherapy regimen.

Topics: Adenine; Dose-Response Relationship, Drug; Enzyme Inhibitors; Hydroxylation; Kinetics; Mercaptopurine; Models, Chemical; Molecular Structure; Substrate Specificity; Thioguanine; Uric Acid; Xanthine; Xanthine Oxidase; Xanthines

The plasma concentrations and tissue distribution of thiopurines were studied in mice after oral administration of 50 mg/kg azathioprine (AZA) using HPLC analysis. Peak concentrations of AZA and three other thiopurine metabolites in plasma [thiouric acid (TUA) greater than 6-mercaptopurine (6-MP) greater than AZA greater than 8-hydroxy-AZA] were observed as early as 10 min after drug application, thus indicating fast absorption and extensive metabolism of AZA, and were followed by a rapid decline. The extraction of thiopurines from organs (intestinal mucosa, liver, kidney, testes, spleen, and bone marrow) and from red blood cells (RBCs) was preceded by an acid hydrolysis procedure resulting in the release of thiopurine bases from their corresponding ribonucleotides. 6-MP, 6-thioxanthene (6-TX), 6-thioguanine (6-TG), TUA, and 8-hydroxy-6-MP (8-OH-6-MP) were extracted from the organs, whereas only 6-MP and 8-OH-6-MP were found in the processed RBCs. Initially, high concentrations of TUA, the endpoint of metabolic AZA degradation, were detected in the intestinal mucosa and in the liver. This provides evidence for a first-pass metabolism of AZA in these two organs. The initial concentrations of 6-MP extracted from the organs were about 10-fold those found in plasma. This indicates rapid cellular uptake of 6-MP and an accumulation of 6-MP derivatives that can be explained by formation of the 6-MP ribonucleotide thioinosine monophosphate (TIMP). With the exception of plasma and RBCs, 6-TG, which may originate from intracellular 6-thioguanosine nucleotides (TGNs), was extracted from all organs examined in the study. From the sequence of appearance of 6-MP, 6-TX, and 6-TG extracted from spleen and bone marrow homogenates, it can be assumed that formation of TGN occurs via the nucleotide interconversion pathway TIMP----6-thioxanthosine monophosphate----6-thioguanosine monophosphate. The highest concentrations of 6-TG derivatives were found in the spleen and bone marrow. This correlates with the clinical and experimental observation that AZA cytotoxicity mainly affects bone-marrow stem cells and lymphocytes and supports the hypothesis (derived from in vitro experiments) that the incorporation of TGN into DNA is the cytotoxic mechanism of AZA and 6-MP.

Topics: Administration, Oral; Animals; Azathioprine; Chromatography, High Pressure Liquid; Erythrocytes; Male; Mercaptopurine; Mice; Mice, Inbred Strains; Purines; Thioguanine; Time Factors; Tissue Distribution; Uric Acid

A sample preparation technique and a high-performance liquid chromatographic method for 6-mercaptopurine (6-MP) that is simple, sensitive and without interference from its metabolites is described. 6-Thioguanine (6-TG) is added as an internal standard to the plasma sample, which is then treated with an aqueous solution of aluminum perchlorate to denature the plasma proteins and form complexes with 6-TG, 6-MP and its major metabolite, 6-thiouric acid (6-TUA). These complexes coprecipitate with proteins on centrifugation. 6-MP and its analogues are then extracted from the precipitate with perchloric acid containing sodium hydrosulfite and the extract is chromatographed on an Ultrasphere ODS column eluted with 0.1 M phosphoric acid and 0.001 M dithiothreitol in deionized water. The eluate is monitored at 340 nm. No interfering peak was encountered in over 300 clinical plasma samples. 6-TUA was separated from 6-MP and was found to be present in much higher concentration than 6-MP itself throughout the sampling time (6 h) following oral administration of the drug.

Topics: Aluminum; Cations; Chelating Agents; Chromatography, High Pressure Liquid; Humans; Mercaptopurine; Spectrophotometry, Ultraviolet; Thioguanine; Uric Acid

Despite extensive clinical experience with azathioprine (AZA), the disposition of various AZA metabolites remains obscure. We therefore evaluated the pharmacokinetics of three AZA metabolites: 6-mercaptopurine (6-MP), the immediate metabolite; 6-thiouric acid (6-TU), the final end product; and 6-thioguanine nucleotides (TGN), the active moiety; in eight renal transplant patients after oral administration of AZA. The low peak plasma 6-MP level of 73.7 +/- 23.7 ng/mL (mean +/- SD) and the short half-life (t1/2) of 1.9 +/- 0.6 hours suggest rapid conversion of 6-MP to other metabolites. A peak plasma 6-TU concentration of 1210 +/- 785 ng/mL was observed at 3.5 +/- 0.6 hours after the AZA dose. The strong correlation between 6-TU t1/2 and serum creatinine (r = 0.98, P = .0008) supported our previous work showing that 6-TU is primarily excreted by the kidneys. The total TGN levels in red blood cells (RBCs) in each patient remained largely unchanged over 24 hours with the intraindividual coefficient of variation ranging from 4.4% to 29.8%. In comparison, the mean TGN level varied considerably between patients, and ranged from undetectable to 413 pmol per 8 X 10(8) RBCs. However, there was no apparent correlation between white cell counts on day 0 (P greater than .5), day 7 (P greater than .5), or day 14 (P greater than .5) and RBC TGN level. The persistence of TGN in body tissues thus provides a pharmacokinetic rationale for the conventional once or twice daily AZA regimen.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Administration, Oral; Adult; Azathioprine; Chromatography, High Pressure Liquid; Data Collection; Female; Humans; Kidney Transplantation; Male; Mercaptopurine; Middle Aged; Thioguanine; Time Factors; Uric Acid

We present a rapid, sensitive and specific high-performance liquid chromatographic method for the analysis of 6-mercaptopurine (6MP), 6-thioguanine nucleotides (6TGN) and 6-thiouric acid (6TU), with excellent chromatographic separation of the thiopurines. Thiopurines in plasma and erythrocytes were extracted by mercuricellulose and re-eluted with beta-mercaptoethanol. For quantitative detection a reverse phase column (Lichrosorb RP-18 4 mm X 30 cm) and a UV detector were used. Detection limits were 20 nmol/l for 6MP in plasma, 250 nmol/l for 6TGN in erythrocytes, and 10 nmol/l and 15 nmol/l, respectively, for 6MP and 6TU in urine diluted 1:100 with beta-mercaptoethanol. Within-run and between-run variations were less than 10%. Recovery of 6MP added to plasma, and 6TGN monophosphate added to haemolysed erythrocytes were 91% and 81%, respectively.

Topics: Chromatography, High Pressure Liquid; Humans; Mercaptopurine; Thioguanine; Uric Acid

Topics: Animals; Azathioprine; Chromatography, High Pressure Liquid; Indicators and Reagents; Kinetics; Male; Mercaptopurine; Mice; Mice, Inbred C57BL; Thioguanine; Thiouracil; Uric Acid