Introduction
Thiopurines, including azathioprine (AZA), mercaptopurine (MP), and thioguanine (TG), are immunosuppressive therapies for maintaining steroid-free remission in inflammatory bowel disease (IBD) [
1‐
3]. The safety profile of thiopurines requires clinical monitoring because in up to 40% of thiopurine-treated patients with IBD, drug-related adverse events (AEs) lead to discontinuation of therapy [
3‐
14]. Dose-independent AEs usually manifest within 6 months after the start of thiopurines and include flu-like syndrome, gastrointestinal intolerance (nausea), arthralgia, and pancreatitis [
3,
4,
6‐
11,
13,
15‐
19]. Dose-dependent AEs can develop during long-term use and/or occur unexpectedly, and include hepatotoxicity, myelotoxicity, and infections [
3,
4,
6‐
11,
13,
15‐
20]. Frequent clinical monitoring is advised for timely detection and management of drug-related AEs [
5,
8,
9,
15,
21,
22].
Thiopurines are metabolized to the active metabolite 6-thioguanine nucleotide (6-TGN) and supratherapeutic 6-TGN levels can induce myelotoxicity [
23,
24]. Thiopurines are also converted into the methylated metabolite 6-MMP at the cost of 6-TGN and elevated 6-methylmercaptopurine (6-MMP) levels are associated with hepatotoxicity [
25,
26]. Current guidelines from the American Gastroenterological Association (AGA) Institute, European Crohn’s and Colitis Organization (ECCO), and British Society of Gastroenterology (BSG) recommend regular laboratory assessment every 3 to 4 months to assess safety of thiopurine therapy [
22,
27,
28]. These recommendations do not take into account the total years of thiopurine exposure, while severe AEs are rare after long-term thiopurine use [
9,
15,
16,
29]. A recent retrospective cohort study assessed the incidence rates and clinical consequences of laboratory toxicity in 1132 patients with IBD after 1 year of consecutive thiopurine treatment with a median follow-up of 3.3 years (until therapy cessation or end of study follow-up) [
19]. Only 83 patients (7%) required therapy adjustments based on laboratory findings [
19]. Thus, less frequent clinical monitoring, including laboratory assessment, might be feasible in long-term thiopurine users [
19,
29]. Moreover, frequent outpatient visits and laboratory assessments place a high burden on patients with IBD and the health care budget, especially in this COVID era [
30]. Studies about the safety of a reduced monitoring strategy in patients with IBD with long-term thiopurine therapy are lacking.
This study aimed to evaluate the feasibility, safety, and costs of a reduced monitoring strategy in thiopurine-treated patients with IBD in long-term steroid-free remission.
Materials and Methods
Study Design
This single-center prospective cohort study assessed the safety of a reduced monitoring strategy in thiopurine-treated patients with IBD in stable remission. This study was conducted at the Radboud University Medical Center in Nijmegen, The Netherlands between September 2017 and December 2018.
Patient visits at the outpatient IBD clinics were scheduled at baseline and 12 months with an additional appointment by phone at six months with a specialized IBD nurse. In addition, laboratory assessment was routinely performed at 6 and 12 months. During follow-up, patients were advised to contact their physician or IBD nurse in case of suspected disease activity or AEs.
Patient Population
Patients ≥ 18 years of age with an established diagnosis of Crohn’s disease (CD), ulcerative colitis (UC), or IBD-unclassified (IBD-U) who were treated with weight-dosed thiopurine monotherapy (including AZA, MP, TG) for more than 6 months were eligible. Patients had to be in corticosteroid-free remission during ≥ 6 months prior to baseline as defined below. Long-term steroid-use was only allowed for treatment of comorbidities.
Exclusion criteria were concomitant treatment with biologic agents or prior use of biologic agents or corticosteroids up to six months preceding baseline, disease activity (biochemical and/or clinical), or ongoing AEs related to thiopurines. Allowed co-medication included long-term use and stable doses (≥ 6 months) of allopurinol and mesalamine.
Data Collection
Baseline
At baseline, we collected demographics, medical history, disease phenotype according to the Montreal Classification, and current and prior medication use. Detailed information about previous and current thiopurine exposure (period of use and dose) and recent metabolite level (determined by the method of Lennard and Singleton, as previously published), defined as 2 months prior to or after baseline date, was collected [
23,
31]. At baseline, patients underwent metabolite measurement.
Follow-up
The laboratory assessment at baseline, 6 and 12 months included complete blood count, liver chemistry including alanine transaminase (ALT) and alkaline phosphatase (AP), C-reactive protein (CRP), fecal calprotectin (FCP), and thiopurine metabolite levels at baseline and as needed during further follow-up. All reported infections were collected during follow-up. Furthermore, physician global assessment (PGA) and medication adjustments were registered. During the first year of follow-up, additional contacts were recorded separately in a prospective fashion. During the second year of follow-up, only the primary outcome (as defined below) was recorded.
Data to calculate health care use were collected 1 year prior to baseline and during 1 year of follow-up after intervention, and included contact moments with attending physicians and IBD nurses, IBD-related laboratory assessment, and extra IBD-related diagnostics (imaging techniques).
Outcomes and Definitions
The primary outcome was the incidence of thiopurine-related AEs that required adjustments in thiopurine treatment during 24 months follow-up, including thiopurine discontinuation and dose adjustment. Secondary outcomes were only available for the first 12 months of the study and included all thiopurine-related AEs including laboratory toxicity, IBD-related AEs, therapy adjustments due to disease flares, and costs concerning IBD-related health care 1 year prior to and during the first year of the reduced monitoring frequency of 6 months. AEs were defined as any medical occurrence during the study follow-up, unrelated or related to underlying IBD, medical treatment, or strategy. Serious AEs included serious, life-threatening AEs resulting in death, irreversible illness or hospital admission. Severity of AEs were graded according to the Common Terminology Criteria for Adverse Events (CTCAE, version 5.0) [
32]. These AEs were categorized in thiopurine- and IBD-related AEs based on the discretion of the treating physician. Clinical remission was defined as steroid-free inactive disease without the need for step-up treatment with biologic agents based on the PGA in addition to biochemical remission as FCP ≤ 250 µg/g and/or CRP ≤ 5 mg/L. A disease flare was defined as disease activity that resulted in an adjustment of thiopurine therapy or initiation of a new drug to induce remission, as previously published [
33].
Laboratory results were assessed for toxicity as previously published [
19]. Laboratory toxicity was defined as myelotoxicity, including leukopenia or thrombocytopenia, and/or hepatotoxicity. Leukopenia was classified as mild (3.0–4.0 × 10
9/L), moderate (2.0–3.0 × 10
9/L), or severe (< 2.0 × 10
9/L) [
18,
19]. Thrombocytopenia was classified as mild (100–150 × 10
9/L), moderate (50–100 × 10
9/L), or severe (< 50 × 10
9/L) [
19]. Hepatotoxicity was defined as any abnormal liver tests above upper limit of normal (ULN), including an elevated AP (> 125 U/L) and/or ALT (> 45 U/L). Severity of hepatotoxicity was graded according to the CTCAE classification [
32]. Grade 1 was defined as liver tests between normal ULN and 2.5 × ULN (AP 125.1–312.5 U/L, ALT 45.1–112.5 U/L), grade 2 was between 2.5 and 5.0 × ULN (AP 312.6–625 U/L, ALT 112.6–225 U/L), and grade 3 was between 5.0 and 20.0 × ULN (AP 625.1–2500 U/L, ALT 226–900 U/L) [
19]. The window of therapeutic metabolite level of 6-TGN was defined as 235–450 pmol/8 × 10
8 red blood cells (RBC) and desired 6-MMP levels as equal or lower than 5700 pmol/8 × 10
8 RBC.
Statistical Methods
Normally distributed values were presented by mean and standard deviation (SD) and non-normally distributed values by median with interquartile range (IQR). Categorical variables were presented as proportions and compared using Pearson
χ2 or Fisher’s exact test. The Kaplan–Meier curve was used to describe the time to thiopurine-related AE that required a therapy adjustment during the study period of 24 months and patients were censored when lost to follow-up or the thiopurine therapy was ceased. Health care costs were calculated by the total amount of health care consumption per patient times the actual prices [
34,
35]. To compare the costs prior to and during the reduction of monitoring frequency a one-sample
t test with bootstrapping (
n = 10,000) was used. A
p value < 0.05 was considered statistically significant. SPSS Statistics (IBM, version 26.0) was used for statistical analyses.
Discussion
We prospectively monitored a carefully selected group of long-term (median duration > 6 years) thiopurine-treated patients with IBD after implementation of a 6-monthly clinical monitoring strategy. In total, 3.5% ceased thiopurine therapy due to thiopurine-related AEs during 24 months of follow-up, while none of the laboratory toxicity we found resulted in thiopurine dose adjustments. Thiopurine treatment was continued in 54.1% until 24 months and the main reason for thiopurine cessation was stable remission (30.6%), whereas abnormal metabolite levels were the main reason for thiopurine dose adjustments (12.9%). None of the thiopurine-related patient reported AEs required hospitalization.
We found a low rate (3.5%) of thiopurine-related AEs that led to thiopurine therapy adjustments during 24 months of follow-up. Although multiple studies have described thiopurine-related AEs and monitoring strategies during the first year of use, limited evidence is available for patients with long-term thiopurine use. The incidence rates of thiopurine-related laboratory toxicity leading to therapy adjustments were assessed during a 3-monthly monitoring strategy in a high-volume multicenter retrospective cohort [
19]. Overall, 6% ceased thiopurine therapy due to AEs versus 3.5% in our study [
19]. The AEs reported in the latter study comprised 2.6% clinical AEs (including general malaise, skin reactions, arthralgia, and other reasons) and laboratory toxicity in 3.5% [
19]. One important reason to explain these differences between studies is that the median thiopurine use at the time of inclusion in the previous study was shorter (1.1 years) compared to our cohort (6.7 years) [
19]. The laboratory toxicity, AEs, and discontinuation rates are higher in the early phases of thiopurine use and may explain the differences between the two cohorts [
3,
4,
6‐
11,
13,
15‐
19]. Furthermore, metabolite level-driven dose adjustments were performed in our study and this could have resulted in less AEs.
In our study, incidence rates of myelotoxicity and hepatotoxicity were 12.9% and 16.5%, respectively, but none resulted in therapy adjustments. In previous studies, aberrant laboratory results, independent of therapeutic consequences, had a broad range (0.5–32.7% myelosuppression versus 3.2–24.3% hepatotoxicity) [
3‐
10,
12,
13,
15,
16,
18,
19,
21,
22,
29,
36]. More importantly, the observed laboratory toxicity in our study were transient, not severe, and did not have therapeutic consequences. This is in line with the literature showing that laboratory toxicity requiring therapy adjustment after long-term thiopurine use remains low (0.6–1.4% leucopenia, 2.1–3.2% hepatotoxicity) [
3,
16,
19,
29].
In the current study, enrolled patients with stable remission of their IBD on long-term thiopurine therapy developed AEs but only few required thiopurine therapy adjustments or discontinuation. It is well known that AEs often occur in the first 6 to 12 months after thiopurine initiation [
3‐
14]. Importantly, a previous cohort study observed lower incidence rates of infection, myelotoxicity, hepatotoxicity, pancreatitis, and neoplasms in patients with IBD using thiopurines for more than 4 years compared to patients with a median exposure of only 1 year since thiopurine initiation [
13]. Moreover, thiopurine discontinuation predominantly occurred within the first 3 months of therapy [
10]. In our study, the 3 thiopurine-related AEs that resulted in treatment cessation occurred after a median 6.7 years of thiopurine use.
An important question is whether we missed AEs due to a reduced frequency of monitoring. Previous cohort studies suggest that most cases of severe leukopenia occurred abruptly (within 1 month) [
7]. We still observed a diverse number of AEs and laboratory toxicity that did not result in therapy adjustments, emphasizing that following a reduced monitoring strategy still results in a sufficient detection of AEs. Most of the AEs did not result in therapy adjustments and carry less clinical relevance, and this is in line with the previous studies [
8,
10,
15,
29]. Second, AEs that needed therapy adjustment included clinical symptoms and probably would not have been detected with laboratory monitoring. Third, therapy adjustment based on monitoring of 6-TGN and 6-MMP levels, as applied in our study, may have reduced the risk of laboratory toxicity.
We observed a net benefit of 136 euro per patient for IBD-related health care use when scheduling outpatient visits and laboratory assessment every 6 months instead of every 3 to 4 months. We did not include medication costs, travel costs, work disability, or absenteeism. Including these items would likely increase the net benefit even more but a full cost-effectiveness analysis was beyond the scope of this study.
The strengths of this study include the careful selection of our study population with stable remission and long duration of thiopurine use prior to enrollment. Secondly, the prospective design and the extensive collection of AEs during 12 months is an addition to previously reported research of mostly retrospective nature. Our study also comes with several limitations. The main limitation is the lack of a control group monitored at the conventional 3-monthly strategy. To overcome this limitation, we compared our results with other cohorts [
10,
19], however, previous cohorts and selected outcomes differed in methodology including selection criteria and design, not allowing for a comprehensive comparison. Second, the reduction of monitoring frequency resulted in fewer assessments and thereby a possible reduction in the detection rate of AEs. This could have resulted in an underestimation of the true AE incidence rates. It is likely that the strategy of reduced monitoring resulted in a more on-demand-based clinical health care as indicated by the additional non-scheduled contacts with physicians by patients. Third, the relatively low dosing of AZA (0.8 mg/kg, in part due to combination therapy with allopurinol) and the total drop-out (
n = 39) after 24 months of follow-up reduced the generalizability of this study, although most patients (66.7%,
n = 26) discontinued thiopurine because of stable remission rather than disease activity or AEs. The long median thiopurine exposure of 6.7 years should be taken into account as well. This suggests that gastroenterologists could consider thiopurine discontinuation in a group of patients with quiescent IBD tolerating long-term thiopurine therapy, but it is unclear whether these results can be extrapolated to patients with shorter duration of thiopurine use.
Overall, AEs that resulted in thiopurine therapy interventions were rare and the detected laboratory toxicity were transient and did not require therapy adjustments. In accordance with the current literature, most AEs were observed within the first 6 to 12 months after start of thiopurines [
3‐
14].
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