Methotrexate (MTX) Plus Hydroxychloroquine versus MTX Plus Leflunomide in Patients with MTX-Resistant Active Rheumatoid Arthritis: A 2-Year Cohort Study in Real World.

PURPOSE: To compare the efficacy, safety, and cost-effectiveness of methotrexate (MTX) plus hydroxychloroquine (HCQ) vs MTX plus leflunomide (LEF) in established rheumatoid arthritis (RA) with inadequate response to MTX monotherapy in a real-world Chinese cohort. PATIENTS AND METHODS: A prospective RA cohort (n=549) was screened with eligible patients who had inadequate response (disease activity score in 28 joints using erythrocyte sedimentation rate, DAS28-ESR>3.2) to initial MTX monotherapy and subsequently received either MTX+HCQ or MTX+LEF. Propensity score matching (PSM) was applied to adjust the possible baseline confounders between two groups. The primary outcome was the proportion of patients achieving first remission (DAS28-ESR<2.6) during follow-up by log rank test. Secondary outcomes were changes of DAS28, glucocorticoids (GCs) exposure, safety, cost-effectiveness, sustained remission, and low disease activity (LDA) rate after 24-month follow-up.
RESULTS: Overall, 222 eligible patients were subjected to the aforementioned two treatment protocols (MTX+HCQ, n=102; MTX+LEF, n=120). After PSM adjustment, 97 patients in each group were analyzed. A higher remission rate was observed in the MTX+HCQ group than in the MTX+LEF group (70.1% vs 56.7%, P=0.048). The median time to remission was 11 and 16 months in the two groups, respectively. At the endpoint, more patients achieved remission (46.8% vs 32.5%, P=0.063) and maintained sustained LDA in the HCQ group (53.2% vs 38.6%, P=0.062) and also more patients withdrew GCs in this group (32% vs 16.7%, P=0.053) than those in the LEF group. Safety profiles were non-alarming, with no significant difference between the two groups. The incremental cost-effectiveness ratio yielded by MTX+HCQ over MTX+LEF was $1,111.8 per quality-adjusted life-year (QALY), within the cost-effective threshold set as the per capita gross domestic product (GDP) of China.
CONCLUSION: The MTX+HCQ combination was seemingly superior to MTX+LEF in a real-world cohort of Chinese RA patients with inadequate response to methotrexate monotherapy in respect of the efficacy and cost-effectiveness.

Introduction

Methotrexate (MTX) is recommended as the cornerstone of initial treatment for rheumatoid arthritis (RA).1 However, approximately 50% patients who experience failure in the first course of methotrexate monotherapy2–4 will require an escalated treatment according to the treat-to-target strategy.5,6 Previous clinical trials have compared the effectiveness of different approaches among such MTX inadequate responders, which mainly can be divided into two protocols, ie, combination of conventional synthetic disease-modifying antirheumatic drugs (csDMARDs) with or without the use of glucocorticoids;7–9 or escaping to more powerful, yet costly, targeted therapies.10–13

Previous studies demonstrated that the global disease burden of RA ranked fifth in musculoskeletal diseases, and its average annual direct cost in China could reach $3,069.14,15 The increasing disease burden in light of pharmacoeconomic analysis is at least partially relevant to the emerging targeted therapies. Therefore, in the real-world practice, to give the csDMARDs a “second chance” is always a serious consideration for both health providers and patients.

In this regard, the inevitable next question is, “what would be the best combination of csDMARDs?” The “triple therapy” combining MTX, sulfasalazine (SSZ), and hydroxychloroquine (HCQ) is the most representative protocol with abundant evidence.4,16,17 Other combinations, such as MTX+SSZ and MTX+HCQ have also been extensively studied.18–20 Leflunomide (LEF), with a comparable potency to MTX alone, has become an alternative option.21,22 To answer the question in a real-world setting, the compliance issue should always be taken into account because non-compliance will largely impede the treat-to-target achievement.23 According to previous data,24 the rule of thumb is “the more pills, the less compliance”.

Therefore, we investigated two commonly used simple combinations in real-world, MTX+HCQ vs MTX+LEF, in a prospective cohort of established RA with inadequate response to initial MTX monotherapy. The aim of this study is to fill the gap that the efficacy, safety, and cost-effectiveness of MTX+HCQ and MTX+LEF has never been compared, and moreover it is highly probable that a randomized head-to-head comparison of these two combinations will never be performed.

Materials and Methods

Study Design

This observational cohort was established following the OPCSP trial (ClinicalTrials.gov ID: NCT03024307), a randomized trial on a compliance improvement program among rheumatic patients by a multidisciplinary team. The research protocol was approved by Shanghai Jiaotong University School of Medicine, Renji Hospital Ethics Committee (approval No.[2016]216K). All participating patients provided written informed consent.

Eligible patients’ data were extracted when the following inclusion criteria were met; 1) all patients fulfilled 2010 criteria for RA of the American College of Rheumatology or European League Against Rheumatism;25 2) they had an inadequate response to initial MTX monotherapy, defined as DAS28-ESR>3.2 (28-joint disease activity score using erythrocyte sedimentation rate) after receiving MTX for at least 6 months with a stable route of administration and more than 10 mg weekly for at least 3 months prior to the baseline visit; and 3) subsequently using either MTX+HCQ or MTX+LEF treatments according to routine clinical practice. Patients were excluded if they were illiterate, had severe mental disorders, had serious physical constraints, or were over the age of 85. Nonsteroidal anti-inflammatory agents (NSAIDs) and glucocorticoids (GCs) were allowed to administrate at stable doses if needed. If an improvement in disease activity was achieved by the judgment of the investigator, the dose of GCs could be reduced, but tapering could not be changed within the 2 weeks before assessment. A single intra-articular injection of glucocorticoids was allowed during the study; the injected joint was considered to be non-evaluable for subsequent study visits.

Outcome Assessment

DAS28 scores, laboratory values, quality-of-life assessments by EQ5D (EuroQol five-dimensions questionnaire),26 and medications (eg, NSAIDs and GCs) during the follow-up were recorded. The primary outcome was the proportion of patients having reached at least one remission (DAS28-ESR<2.6) over 2 years among propensity score matched (PSM) patients,20,27 the low disease activity (LDA) rate and treatment retention were also calculated. Switching therapies were documented for up to 2 years. When switching of therapies occurred, the original therapy was defined as failure. Secondary outcomes were the changes of DAS28, average daily exposure to GCs, proportion of patients who withdrew from GCs, and cost-effectiveness by the available extended 2-year data in matched patients. Data from patients who completed 2-year follow-up were analyzed to determine whether the remission and LDA response observed over 12 months of two groups would be sustained over 24 months. The participants reported the possible side-effects of the treatment at each follow-up and all records were included in the safety analysis whether the participants completed the 2-year follow-up schedules or not.

Statistical Analysis

The comparisons between the study groups were performed with the use of Student’s t-test for continuous measures and the chi-square test (or Fisher’s exact test) for categorical measures. The primary comparison between two groups was the time until first moment of DAS28 remission by Kaplan–Meier survival analysis with Log rank testing. The rate of LDA and retention of the treatment were also compared by Kaplan–Meier survival analysis with Log rank testing. The changes of DAS28 over time were compared by specifying a linear mixed model with treatment and time as fixed factors, and was performed with baseline DAS28 score as a covariate. As the visit schedules were slightly different between both cohorts, only baseline, 12-month, and 24-month data were included for the analysis of the secondary outcomes and we allowed a 2-month window (the closest information to the time within 2 months before or after this time). Results were presented as all observed data, without imputation for missing values. All statistical calculations were performed using the statistical software package IBM SPSS version 25.0 for mac (IBM, Armonk, NY, USA). For all tests, P<0.05 was considered to be significant.

Considering the baseline difference caused by possible selection bias, PSM was applied to adjust the baseline confounders. The matching was based on prognostic factors, including number of previous DMARDs used, daily GCs exposure dose, and DAS28-ESR.28,29 The nearest neighbor method was used for 1:1 matching, and the caliper value was set to 0.02.

Cost-Effectiveness Analysis

We established a decision tree model to evaluate the mean between-group difference in costs and quality-adjusted life-years (QALYs) gained over 24 months among the patients completing 2-year follow-up without switching therapy. Since two brands of hydroxychloroquine were included in this study, we calculated the weighed price of a hydroxychloroquine treatment group according to the proportion of two bands in the study. We estimated QALYs from the health utility value, derived from EQ-5D questionnaire responses and assessed value of the EQ-5D using Chinese time trade-off values.26,30 An incremental cost-effectiveness ratio was calculated by dividing the cost difference by the QALY difference per pair of treatment schemes.15 The 10,000 iterations Monte Carlo simulation was implemented to get the cost-effectiveness acceptability curve to analyze the preferred treatment group between different willingness-to-pay (WTP) thresholds. The WTP threshold under the per capita gross domestic product (GDP) of China was considered cost-effective, $10,279 in 2019.

Results

Cohort Baseline

Two hundred and twenty-two out of 549 patients of the cohort were eligible participants, and 102 of them were administered MTX+HCQ, and 120 MTX+LEF (Figure 1). Baseline demographic and clinical characteristics of participants are summarized in Table 1. In this study, two care programs were proportionately distributed in two analyzed groups. The average disease duration was 3 years and all of them had a diagnosis of RA longer than 1 year. The proportion of patients with positive ACPA and/or RF was over 85%. The disease activity was similar in both groups, such as DAS28-ESR (4.3 vs 4.4, P=0.394). The proportion of patients with moderate disease activity (80.4% vs 80.8%, P=0.934) and high disease activity (19.6% vs 19.2%, P=0.934) were similar between the two groups. The average weekly dose of MTX was 10 mg, which was equally distributed in the two groups. The average daily dose of HCQ and LEF were 200 mg and 10 mg, respectively. After PSM, the distribution of baseline parameters was further balanced. Sixty-two patients (63.9%) received GCs in the HCQ group at an average daily dose of 9 mg, whereas 75 patients (77.3%) received GCs in the LEF group at an average daily dose of 8.5 mg (P=0.464).

Figure 1

Flow diagram of the analyzed study population.

Table 1

Baseline Characteristics of Patients Before and After Propensity Score Matching

Characteristics	Overall Sample (n=222)			Matched Patients (n=194)
	MTX+HCQ (n=102)	MTX+LEF (n=120)	P-value	MTX+HCQ (n=97)	MTX+LEF (n=97)	P-value
Age, mean (SD), years	51.0 (14.2)	53.3 (10.9)	0.179	50.2 (13.8)	53.3 (10.8)	0.083
Female, n (%)	85 (83.3)	88 (73.3)	0.077	81 (83.5)	72 (74.2)	0.113
BMI, mean (SD)	21.5 (3.0)	22.2 (3.0)	0.090	21.6 (3.0)	22.0 (3.0)	0.282
Smoking history, n (%)	7 (6.9)	7 (5.8)	0.788	7 (7.2)	5 (5.2)	0.767
Drinking history, n (%)	6 (5.9)	4 (3.3)	0.519	6 (6.2)	1 (1.0)	0.118
Disease duration, median (IQR), years	3 (2–6)	3 (2–8)	0.556	5.5 (6.1)	5.3 (5.1)	0.780
Comorbidities, n (%)	45 (44.1)	45 (37.5)	0.526	42 (43.3)	31 (32.0)	0.103
0	57 (55.9)	75 (62.5)		54 (55.7)	66 (68.0)
1	32 (31.4)	28 (23.3)		31 (32.0)	17 (17.5)
2	9 (8.8)	9 (7.5)		12 (12.4)	14 (14.4)
≥3	4 (3.9)	8 (6.6)		0	0
ACPA+*, n (%)	79 (85.9)	14 (86.9)	0.830	76 (87.4)	75 (86.2)	0.823
RF+**, n (%)	71 (85.5)	81 (91.0)	0.264	70 (87.5)	63 (90.0)	0.630
DAS28-ESR, mean (S.D.)	4.3 (0.8)	4.4 (0.8)	0.394	4.3 (0.8)	4.5 (0.9)	0.143
DAS28-CRP, mean (S.D.)	3.9 (0.8)	3.9 (0.8)	0.519	3.8 (0.7)	4.0 (0.8)	0.189
MDA rate, n (%)	82 (80.4)	97 (80.8)	0.934	78 (80.4)	76 (78.4)	0.723
HDA rate, n (%)	20 (19.6)	23 (19.2)	0.934	19 (19.6)	21 (21.6)	0.723
EQ-5D index, mean (SD)	0.7 (0.2)	0.7 (0.2)	0.960	0.7 (0.2)	0.7 (0.2)	0.789
GCs usage, n (%)	64 (62.7)	92 (76.7)	0.024	62 (63.9)	75 (77.3)	0.058
GCs dosage#, mean (SD), mg	9.2 (5.4)	8.1 (3.8)	0.135	9.0 (5.4)	8.5 (3.9)	0.464
Weekly dose of MTX, mean (SD), mg	10.6 (1.9)	10.4 (1.6)	0.450	10.6 (1.9)	10.4 (1.4)	0.329
Prior DMARDs, n (%)	1.3 (0.6)	1.2 (0.5)	0.318	1.2 (0.5)	1.2 (0.5)	0.888
bDMARD, n (%)	2 (2.0)	0	0.210	2 (2.1)	0	0.497
Use of NSAID, n (%)	7 (6.9)	7 (5.8)	0.788	7 (7.2)	7 (7.2)	1.000
Multidisciplinary care, n (%)	60 (58.8)	68 (56.7)	0.746	58 (59.8)	57 (58.8)	0.884

Notes: *23 Missing data were excluded in calculating the positive proportion. **50 Missing data were excluded in calculating the positive proportion. #Average daily dose of GCs was calculated in prescribed patients.

Abbreviations: IQR, interquartile range; MTX, methotrexate; HCQ, hydroxychloroquine; LEF, leflunomide; BMI, body mass index; ACPA, anticitrullinated protein antibody; RF, rheumatoid factor; DAS28-ESR, disease activity score in 28 joints using erythrocyte sedimentation rate; DAS28-CRP, disease activity score in 28 joints using c-reactive protein; MDA, moderate disease activity; HDA, high disease activity; EQ-5D, EuroQol five-dimensions questionnaire; GC, glucocorticoid; DMARDs, disease-modifying antirheumatic drugs; bDMARDs, biological DMARDs; NSAID, non-steroidal anti-inflammatory drug.

Efficacy

Adjusted by PSM, 97 participants were matched in both groups and the proportion at some point during follow-up achieving DAS28 remission were higher in the MTX+HCQ group (70.1% vs 56.7%, P=0.048) (Figure 2A), while the LDA rate was not significantly different (76.3% vs 69.1%, P=0.125) (Figure 2B). Median time to remission was 11 months in the MTX+HCQ group (95% confidence interval [CI]=5.7–16.3) vs 16 months in the MTX+LEF group (95% CI=6.8–25.2); the median time to LDA was 6 months in the HCQ group (95% CI=4.8–7.2) and 10 months in the LEF group (95% CI=5.7–14.3), respectively. The drug retention rate of two regimens was similar (88.7% vs 82.5%, P=0.292) (Figure 2C).

Figure 2

Kaplan–Meier curve for time to first remission (A), LDA (B), and drug retention (C) among matched patients. The solid line represents MTX+HCQ, and the dashed line represents MTX+LEF.

The secondary efficacy endpoints at 24 months are illustrated in Table 2. Among the 162 matched patients who completed the follow-up, the remission rate was marginally higher in the HCQ group than in the LEF group (46.8% vs 32.5%, P=0.063), with 25.3% of patients achieving sustained remission from 12 months to the endpoint in the HCQ group and 15.7% in the LEF group (P=0.127). The LDA rate was 65.8% in the HCQ group and 56.6% in the LEF group (P=0.230), with 53.2% of patients achieving sustained LDA in the HCQ group and 38.6% in the LEF group (P=0.062). The mean score of DAS28-ESR was 2.7 in the MTX+HCQ group, whereas it was 2.9 in the MTX+LEF group (P=0.246). The net changes of DAS28-ESR score over 2 years were similar with a slight, yet significant, greater DAS28-ESR reduction in the MTX+HCQ group than in the MTX+LEF group (95% CI=0.006–0.478, P=0.044) (). The VAS pain (2.6 vs 2.3, P=0.328) and EQ5D-index (0.812 vs 0.771, P=0.169) were similar between groups. In respect of the concomitant medication, a smaller proportion of patients were prescribed with GCs at 24 months in the HCQ group (45.6% vs 69.9%, P=0.002). In addition, more patients tapered off and finally withdrew GCs in the MTX+HCQ group (16, 32.0%) than in the MTX+LEF group (11, 16.7%) at the endpoint (P=0.053), while no significant difference was observed about the daily dose of GCs among the 94 patients (58.0%) still receiving GCs (6.7 mg vs 6.2 mg, P=0.592).

Table 2

Secondary Efficacy Endpoints

Measure	Month 0			Month 12			Month 24
	MTX+HCQ (n=97)	MTX+LEF (n=97)	P-value	MTX+HCQ (n=86)	MTX+LEF (n=87)	P-value	MTX+HCQ (n=79)	MTX+LEF (n=83)	P-value
DAS28-ESR, mean (SD)	4.3 (0.8)	4.5 (0.9)	0.143	2.9 (1.1)	3.2 (1.0)	0.066	2.7 (1.1)	2.9 (1.1)	0.246
DAS28-CRP, mean (SD)	3.8 (0.7)	4.0 (0.8)	0.189	2.2 (0.9)	2.4 (0.9)	0.157	2.5 (0.9)	2.6 (0.9)	0.525
VAS pain, mean (SD)	4.9 (1.6)	4.7 (1.9)	0.312	2.8 (1.8)	2.8 (1.9)	0.960	2.6 (1.7)	2.3 (1.9)	0.328
Remission rate, n (%)	0	0	/	35 (40.7)	30 (34.5)	0.399	37 (46.8)	27 (32.5)	0.063
Sustained remission rate, n (%)	/	/	/	/	/	/	20 (25.3)	13 (15.7)	0.127
LDA rate, n (%)	0	0	/	51 (59.3)	42 (48.3)	0.146	52 (65.8)	47 (56.6)	0.230
Sustained LDA rate, n (%)	/	/	/	/	/	/	42 (53.2)	32 (38.6)	0.062
EQ5D, mean (SD)	0.712 (0.2)	0.705 (0.2)	0.789	0.796 (0.1)	0.765 (0.2)	0.137	0.812 (0.2)	0.771 (0.2)	0.169
GCs usage, n (%)	62 (63.9)	75 (77.3)	0.058	46 (53.5)	61 (70.1)	0.029	36 (45.6)	58 (69.9)	0.002
Withdrawal from GCs*, n (%)	/	/	/	10 (18.5)	10 (14.9)	0.597	16 (32.0)	11 (16.7)	0.053
GCs dose#, mean (SD), mg	9.0 (5.4)	8.5 (3.9)	0.464	7.5 (3.6)	7.2 (4.0)	0.688	6.7 (4.2)	6.2 (3.8)	0.592
Use of NSAID, n (%)	7 (7.2)	7 (7.2)	1.000	2 (2.3)	3 (3.4)	1.000	3 (3.8)	1 (1.2)	0.358

Notes: *Proportion of patients who withdrew from GCs was calculated in prescribed patients still under follow-up. At 12 months, 54 patients were prescribed GC at baseline in the HCQ group and 67 in the LEF group. At 24 months, 50 patients were prescribed GC at baseline in the HCQ group and 66 in the LEF group. #Average daily dose of GCs was calculated in prescribed patients.

Abbreviations: MTX, methotrexate; HCQ, hydroxychloroquine; LEF, leflunomide; DAS28-ESR, disease activity score in 28 joints using erythrocyte sedimentation rate; DAS28-CRP, disease activity score in 28 joints using c-reactive protein; VAS pain, visual analogscale for pain (0–10); LDA, low disease activity; EQ-5D, EuroQol five-dimensions questionnaire; GC, glucocorticoid; NSAID, non-steroidal anti-inflammatory drug.

Cost-Effectiveness Analysis

Medication costs and QALYs for each treatment group are presented in Table 3. The medication cost for 2 years in the MTX+HCQ group was $547.2 and $516.4 in the MTX+LEF group. The patients gained an average 1.603 QALYs in MTX+HCQ group and 1.575 in the MTX+LEF group. The incremental cost-effectiveness ratio (ICER) yielded by MTX+HCQ therapy was $1,111.8 per QALY, compared with the MTX+LEF therapy. Cost-effectiveness acceptability curves also indicated that MTX+HCQ was the more cost-effective when the per capita GDP of China ($10,279) was set as a possible willingness-to-pay threshold ().

Table 3

Medication Costs and QALYs Over 24 Months

Measure	MTX+HCQ (n=68)	MTX+LEF (n=67)
Medication costs (US$)	547.2	516.4
Δ Costs (US$)	30.8	Reference
QALYs	1.603	1.575
Δ QALYs	0.028	Reference
Average C/E ($/QALY)	327.8	327.8
ICER ($/QALY)	1,111.8	Reference

Abbreviations: MTX, methotrexate; HCQ, hydroxychloroquine; LEF, leflunomide; ICER, incremental cost-effectiveness ratio; QALY, quality-adjusted life years; Average C/E, average cost-effectiveness ratio.

Safety Analysis

There were no serious adverse effects observed during the follow-up, and also no difference in the proportion of participants who experienced comorbidity (46.1% vs 45.8%, P=0.971) or side-effects (22.5% vs 20.8%, P=0.870) across treatment groups (Table 4). In our study cohort, the most common comorbidity with RA was osteoporosis (19.8%), followed by cardiovascular diseases (10.8%), digestive system diseases (9.5%), and other rheumatic diseases (5.0%). The most frequently reported side-effects were gastrointestinal reactions (5.9%), followed by infections (4.5%), hepatotoxicity (3.6%), and leukopenia (2.3%).

Table 4

Safety Outcomes (n=222)

Measure	MTX+HCQ (n=102)	MTX+LEF (n=120)	P-value
Comorbidities, n (%)	47 (46.1)	55 (45.8)	0.971
0	55 (53.9)	65 (54.2)
1	33 (32.4)	38 (31.7)
2	10 (9.8)	9 (7.5)
≥3	4 (4.8)	8 (6.6)
Osteoporosis	19 (18.6)	25 (20.8)
Cardiovascular diseases	11 (10.8)	13 (10.8)
Digestive system diseases	10 (9.8)	11 (19.2)
Other rheumatic diseases	7 (6.9)	4 (3.3)
Endocrine system	6 (5.9)	9 (7.5)
Respiratory diseases	5 (4.9)	6 (5)
Musculoskeletal diseases	3 (2.9)	3 (2.5)
Hematological system diseases	2 (2.0)	2 (1.7)
Renal disease	2 (2.0)	5 (4.2)
Nervous system	0	3 (2.5)
Adverse effects, n (%)	23 (22.5)	25 (20.8)	0.870
0	79 (77.5)	95 (79.2)
1	20 (19.6)	24 (20)
2	3 (2.9)	1 (0.8)
Gastrointestinal response	6 (5.9)	7 (5.8)
Infection	6 (5.9)	4 (3.3)
Hepatotoxicity	2 (2.0)	6 (5.0)
Leukopenia	2 (2.0)	3 (2.5)
Musculoskeletal diseases	3 (2.9)	1 (0.8)
Blurred vision	2 (2.0)	0
Alopecia	1 (1.0)	2 (1.8)
Rash	0	1 (0.8)

Abbreviations: MTX, methotrexate; HCQ, hydroxychloroquine; LEF, leflunomide.

Discussion

In this observational cohort study, the combination of MTX plus HCQ or LEF was compared in established RA who had inadequate response to MTX monotherapy with moderate or high disease activity. After adjustment by PSM, the first time to remission over 2 years favored MTX+HCQ over MTX+LEF combination. At 24 months, we also observed a high remission rate and sustained LDA rate in the HCQ group, though the statistical difference was at the critical value. In addition, significantly fewer patients were administered GCs in the HCQ group than that in the LEF group at the endpoint.

Previous studies in patients with inadequate response to MTX showed that the initial combination therapy of target agents and MTX appeared to be more effective than it alone;8,31–34 the triple combination of MTX+SSZ+HCQ was not inferior to etanercept plus MTX. In spite of this knowledge, considerable patients still prefer the conventional combination therapy after failure in the first course of MTX monotherapy for the sake of the cost of biological agents.20 Also, patients receiving target agents were likely to discontinue treatment for economic factors.23,35 On account of the cost and compliance issues, a combination of conventional DMARDs should be considered in the real-world setting when initial MTX monotherapy was suboptimal. However, the limited research on hydroxychloroquine mainly focused on triple combined therapy with a relatively high dose of MTX and SSZ.7,36 It was not quite feasible for real-world practice, for concerns about patient compliance and unfavorable side-effects due to the differences in ethnic adaptability,36 a maximum dose of 16 mg MTX weekly in a Japanese population.1,37 According to our data, a combination of 10 mg MTX weekly plus hydroxychloroquine 200 mg daily in patients with a low body mass index (BMI) of 21.9 on average was safe and more effective than plus 10 mg LEF daily. Indeed, a previous pharmacokinetic study had underscored a synergistic effect of the MTX+HCQ combination.38 On the other hand, the classic triple therapy of MTX+SSZ+HCQ, which bore abundant evidence in terms of efficacy;8,17 however, its compliance was problematic in Chinese patients according to our previous real-world data.14 The main reason seemed to be that patients were reluctant to take an extra 4–8 SSZ tablets each day (with a therapeutic dose of 1–2 gram/day). MTX+LEF apparently provided an alternative option; and within the dose range the safety profile was good. However, our data supported that MTX+HCQ had a better remission response over MTX+LEF combination at a low dose in the patients with a low BMI.

Admittedly, the average daily exposure to GCs in this study was higher than previously reported, but still within the recommended dose of 7.5 mg or less.1 The tapering scheme of GCs could be optimized. GCs should primarily be used as a bridging therapy until DMARDs exhibit their efficacy and should be tapering off as rapidly as clinically feasible. However, the participants of this study preferred conservative treatment, they neither accepted target agents, nor step-up DMARDs dosage. In real-world practice, the compliance, preference, and economy of patients should always be considered when we provide therapies. Because of the inability to switch to more effective DMARD treatment, GC was administrated to control the disease activity. From our results, fewer patients were administered GCs in the HCQ group and more of them tapered off and finally withdrew it than in the LEF group at the endpoint. This result suggested that MTX+HCQ might be of more benefit than LEF for these difficult patients.

Previous cost-effectiveness analyses on RA were mainly centered on bioDMARDs vs csDMARDs.39–42 The comparison among the conventional combinations were limited,43 especially the cost-effectiveness of MTX+HCQ over MTX+LEF. This study provided direct evidence that in China mainland, the ICER yielded by MTX+HCQ was $1,111.8 per QALY greater than MTX+LEF. Within the cost-effective threshold set as the per capita GDP of China, our data indicated a favorable cost-effectiveness with MTX+HCQ combination. This analysis was of greater reference value for patients in other countries such as in South America and Europe, because the price of leflunomide in these countries was often much higher than that of hydroxychloroquine. In view of these conditions, the findings of our study on the effectiveness and economy of methotrexate add-on hydroxychloroquine suggested that this combination could be a superior option for these patients.

There were several limitations with this study. First, unlike in a randomized-controlled trial, selection bias was inevitable in this real-world analysis. Although adjusted by propensity score matching with the baseline disease activity, GCs, and previous DMARDs exposure, the possibility of other potential confounders that exerted impact on the outcome measurements could not be excluded. What’s more, patients did not strictly follow the visit schedules in the study. Consequently, only baseline, 12-month, and 24-month data were included for the analysis of the secondary outcomes and we allowed a 2-month window. Second, as a single center cohort study in China, caution should be taken when extrapolating our results to a larger population or area.

Conclusion

In conclusion, methotrexate plus hydroxychloroquine was seemingly better in terms of remission response with a favorable cost-effectiveness for established RA patients with inadequate response to MTX monotherapy in a Chinese cohort, compared with the combination of methotrexate and leflunomide.