Piet M. Hooymans

Pharmacokinetics of 6-mercaptopurine in patients with inflammatory bowel disease: implications for therapy.

Proper prospective pharmacokinetic studies of 6-mercaptopurine (6-MP) in inflammatory bowel disease (IBD) patients are lacking. As a result, conflicting recommendations have been made for metabolite monitoring in routine practice. The authors have evaluated 6-MP pharmacokinetics in IBD patients, including the genetic background for thiopurine methyltransferase (TPMT). Red blood cell (RBC) 6-thioguanine nucleotide (6-TGN) and 6-methylmercaptopurine ribonucleotide (6-MMPR) concentrations were measured in 30 IBD patients at 1, 2, 4, and 8 weeks after starting 6-MP, 50 mg once daily. Outcome measures included mean 6-TGN and 6-MMPR concentrations (± 95% confidence interval, CI95%) and their associations with TPMT genotype, 6-MP dose, and hematologic, hepatic, pancreatic, and efficacy parameters during the 8-week period. Steady-state concentrations were reached after 4 weeks, indicating a half-life of approximately 5 days for both 6-TGN and 6-MMPR; the concentrations were 368 (CI95% 284–452) and 2837 (CI95% 2101–3573) pmol/8 × 108 RBCs, respectively. Large interpatient variability occurred at all time points. TPMT genotype correlated with 6-TGN concentrations (0.576, P < 0.01), and patients with mutant alleles had a relative risk (RR) of 12.0 (CI95% 1.7–92.3) of developing leukopenia. A 6-MMPR/6-TGN ratio less than 11 was associated with therapeutic efficacy. Based on this pharmacokinetic analysis, therapeutic drug monitoring is essential for rational 6-MP dosing.

Dose-Dependent Influence of 5-Aminosalicylates on Thiopurine Metabolism

INTRODUCTION:Studies indicated that 5-aminosalicylates (5-ASA) may influence the metabolism of thiopurines; however, conclusions were restricted as a result of number of patients or study design.AIM:To determine the influence of 5-ASA on thiopurine metabolism, we performed a prospective multicenter pharmacokinetic interaction study of two different 5-ASA dosages (2 g daily followed by 4 g daily) in 26 inflammatory bowel disease (IBD) patients during steady-state AZA or 6-MP therapy.RESULTS:The 4-wk coadministration of 2 g 5-ASA daily, followed by a 4-wk period of 4 g 5-ASA daily, led to a statistical significant increase of 40% (absolute 84 pmol/8 × 108 RBC) and 70% (absolute 154 pmol/8 × 108 RBC) in 6-thioguaninenucleotide levels (6-TGN), respectively. A rise in 6-TGN levels was observed in 100% of patients after a 4-wk period of 4 g 5-ASA daily. The 6-methylmercaptopurine-ribonucleotide levels did not change. Signs of myelotoxicity were observed in 7.7% of patients (N = 2).CONCLUSIONS:The level of the pharmacologically active 6-TGN significantly increases in a dose-dependent manner during 5-ASA coadministration. IBD patients who are unresponsive or refractory to standard thiopurine therapy may benefit from the coadministration of 5-ASA, leading to an increase in 6-TGN levels.

6-Thioguanine seems promising in azathioprine- or 6-mercaptopurine-intolerant inflammatory bowel disease patients: a short-term safety assessment.

Objective 6-Mercaptopurine (6-MP) and azathioprine (AZA) have proven efficacy in the treatment of inflammatory bowel disease (IBD). However, adverse events leading to discontinuation may occur in 10–20% of patients. The efficacy of AZA and 6-MP is based on formation of their active metabolites, the 6-thioguaninenucleotides (6-TGNs). Therefore, 6-thioguanine (6-TG), an agent leading more directly to the formation of 6-TGNs and until recently used only in patients suffering from leukaemia, may be an alternative in AZA or 6-MP intolerance. The purpose of our study was to assess the short-term safety of 6-TG. Methods Thirty-two IBD patients with previously established AZA or 6-MP intolerance were treated with 6-TG in doses of 20 mg (n = 19) or 40 mg (n = 13) once daily. Safety parameters were obtained at 0, 1, 2, 4 and 8 weeks after start of medication. Primary outcome measures were the ability to tolerate 6-TG and the occurrence of adverse events. Secondary outcome definitions included laboratory parameters. Results Twenty-six (81%) patients were able to tolerate 6-TG during the first 8 weeks. In three of six patients, side effects leading to discontinuation were probably (n = 2) or obviously (n = 1) related to 6-TG. No clinically relevant haematological events or hepatotoxicity occurred in the observed period. Steady-state 6-TG levels were significantly higher with 40 mg once daily (1621 ± 828 picomol/8 × 108 red blood cells (RBC)) than with 20 mg once daily (937 ± 325 picomol/8 × 108 RBC; P = 0.001). Conclusions 6-TG treatment seems promising in AZA- or 6-MP-intolerant IBD patients. However, long-term safety and efficacy have yet to be determined.

Effects of absorption enhancers on human nasal tissue ciliary movement in vitro.

Sodium taurodihydrofusidate (STDHF) is one of the most promising absorption enhancers for nasal delivery of peptide drugs. Drugs and additives in nasal formulations should not interfere with the self-cleaning capacity of the nose by the ciliary epithelium. Measured in vitro on human adenoid tissue with a photoelectric method, STDHF was found to induce ciliostasis at concentrations of 0.3% (w/v) and higher. STDHF (0.3%) is less ciliostatic than laureth-9 (0.3%) or deoxycholate (0.3%). Glyco- and taurocholate (0.3%) show only very mild effects on nasal ciliary movement. Human insulin (1%) has no ciliostatic potency in vitro, whereas a combination of human insulin (1%) and STDHF (1%) is ciliostatic but not as potent as STDHF (1%) alone.

The Role of Xanthine Oxidase in Thiopurine Metabolism: A Case Report

Azathioprine (AZA) is widely used in the treatment of autoimmune inflammatory diseases. AZA is normally rapidly and almost completely converted to 6-mercaptopurine (6-MP) in the liver, which is further metabolized into a variety of pharmacologic active thiopurine metabolites. 6-MP is catabolized by xanthine oxidase (XO) to the inactive metabolite 6-thiouric acid. The authors report the case of a woman with chronic autoimmune pancreatitis unable to form active thiopurine metabolites. The 55-year-old woman presented with weight loss, progressive elevation of liver transaminases, and serum amylase. She was treated with prednisolone 30 mg/day (1 mg/kg) and AZA was increased to 75 mg/day (2.5 mg/kg); this was later increased to 150 mg/day (5 mg/kg). Despite good patient compliance, the active metabolites of AZA, 6-thioguanine nucleotides (6-TGN), and 6-methylmercaptopurine ribonucleotides (6-MMPR) could not be detected in the erythrocytes (RBC). Subsequently, AZA was switched to high-dose 6-MP (2.5 mg/kg) and the XO inhibitor allopurinol was added. After 1 week, this combination led to a high 6-TGN level of 616 pmol/8 × 108 RBC and a 6-MMPR level of 1319 pmol/8 × 108 RBC. Three weeks after starting treatment, 6-TGN and 6-MMPR even reached toxic levels (1163 pmol/8 × 108 RBC and 10015 pmol/8 × 108 RBC, respectively) so that 6-MP treatment was discontinued. To elucidate this finding, 6-MP (1.7 mg/kg) was prescribed for 3 days without allopurinol. The woman was not able to form active thiopurine metabolites. According to the authors, this is the first report of a patient unable to form detectable active thiopurine metabolites on AZA and 6-MP therapy despite good patient compliance. High XO activity led to an inability to form detectable levels of active thiopurine metabolites 6-TGN and 6-MMPR. This finding emphasizes the important role of XO in the biotransformation of thiopurines.

Effect of heparin on digitoxin protein binding

Reduction of digitoxin binding to plasma proteins after heparin has been reported. Our aim was to determine whether this reduction is an in vivo effect or occurs only after blood collection as a result of heparin‐induced lipolysis that increases levels of nonesterified fatty acids in vitro. The effect of heparin on digitoxin protein binding was studied in 10 patients undergoing hemodialysis receiving digitoxin maintenance therapy. Digitoxin free fraction increased after heparin, from 2.5% ± 0.7% to 4.4% ± 1.1%, but after inhibition of in vitro lipolysis with diethyl p‐nitrophenyl phosphate (2mM), a potent lipase inhibitor, there was no increase in the free fraction (2.3% ± 0.4% before heparin and 2.4% ± 0.5% after heparin). Digitoxin salivary levels were also unchanged (0.41 ± 0.08 ng/ml before heparin and 0.41 ± 0.08 ng/ml after heparin [n = 8]). These data indicate that the binding of digitoxin to plasma proteins in vivo is not altered by heparin. The reduced binding reported elsewhere was a result of heparin‐induced in vitro lipolysis.