797 High Thiopurine Methyltransferase Activity Does Not Affect Concentration of Azathioprine Metabolite 6-Thioguanine Nucleotide in Inflammatory Bowel Disease

Abstract

INTRODUCTION: Azathioprine (AZA) is commonly used to treat inflammatory bowel disease (IBD). Thiopurine methyltransferase (TPMT) converts AZA to key active metabolite 6-thioguanine nucleotide (6-TGN). Low TPMT activity is associated with high 6-TGN and side effects. Conversely, low 6-TGN is associated with lack of clinical response and has been associated with high TPMT activity but has not been examined in an IBD population. The aim of this study was to identify the independent effect of normal to high TPMT activity on 6-TGN concentrations in an IBD population. METHODS: We performed a retrospective chart review of patients aged >18 with IBD treated with AZA and with documented TPMT activity and 6-TGN levels from 2010 to 2017. To account for different assays, TPMT activity was normalized against the established low-normal TPMT activity, with low activity defined as less than 1 and high activity defined as above the 75th quantile of TPMT activity in the cohort. Those with low TPMT were excluded. Linear regression was used to determine the effect of TPMT activity on 6-TGN accounting for potential confounders. Further assessment of the interaction between dose and TPMT activity on 6-TGN was measured through the Average Causal Mediation Effects (ACME). Statistics performed in R v3.6.0 using mediation package. This study was IRB approved. RESULTS: Dosing of AZA in mg/kg, TPMT activity, and 6-TGN concentration were documented in 63 patients, of which 10 had low TPMT activity and were subsequently excluded, leaving 53 patients for analysis. Overall 37% of the cohort had a therapeutic 6-TGN level of >240 pmol/8 × 108 RBC. No patient under 1mg/kg achieved a therapeutic 6-TGN level, whereas 50% of patients taking 2.5 mg/kg did. The median 6-TGN in the normal TPMT range was 191.5 (IQR: 78.8, 296.3) versus 201 (IQR: 45, 312) in the high group (P = 0.57). There was a weak positive correlation between dosing (mg/kg) and 6-TGN (R2 = 0.08), while no correlation was seen between TPMT and 6-TGN (R2 = 0.0). Linear regression to assess the effect of TPMT activity and dose on 6-TGN concentrations including potential confounders of sex, age, smoking status only identified dose (mg/kg) to have a significant effect on 6-TGN concentration (Table 1). CONCLUSION: There was no effect on 6-TGN as TPMT activity increased, although 6-TGN was positively affected by dose. Despite normal TPMT activity, therapeutic 6-TGN concentrations were only found in 50% of those dosed at 2.5 mg/kg.