Although the use of biologics over the last decade has revolutionized treatment for patients with axial spondyloarthritis (axSpA), only up to 60% and 40% of patients reach partial remission and inactive disease, respectively (1). This is partly because axSpA is a heterogeneous disease with a wide range of clinical presentations, disease severity, and inflammatory burden, often posing diagnostic and management challenges. In the absence of objective markers that reliably predict which subgroup of patients with axSpA will respond to a particular therapy, we currently rely on a “trial and error” approach for treatment. Among the available markers, C-reactive protein (CRP) testing and magnetic resonance imaging (MRI) are increasingly being performed at baseline in patients with axSpA. Leveraging this readily available information to aid our treatment decision would be optimal for clinical practice.

It is plausible that a combination of CRP levels and MRI findings at baseline may provide better insight as to the inflammatory burden of axSpA than either factor alone. Elevated CRP levels are associated with a favorable treatment response in axSpA; however, the association of inflammation on MRI with treatment response is unclear (2,3). The CRP level is elevated in only 40% to 50% of patients with axSpA; however, when present, it correlates well with disease activity (4,5). CRP levels do not always correlate with MRI findings, and MRI inflammation could be noted in patients with normal CRP levels (6–8). Furthermore, the correlation between inflammation on MRI and disease activity is low, so MRI may provide additional information about disease activity (9). A more nuanced understanding of the relationships between CRP levels, MRI findings, and treatment response could help identify specific subpopulations of patients who might benefit from targeted therapeutic approaches. Understanding differences in treatment response across subpopulations with differing inflammatory burdens could pave the way for personalized medicine strategies in axSpA.

Although some randomized controlled trials (RCTs) have examined treatment efficacy based on CRP and MRI subgroups, the trials themselves are not powered to examine subgroups. A systematic review and meta-analysis of subgroup data from these trials can yield better insight. Therefore, we performed a systematic review and meta-analysis of subgroup data (four subgroups: MRI+/CRP+, MRI+/CRP−, MRI−/CRP+, MRI−/CRP−) from available RCTs to determine if treatment efficacy differed based on MRI and CRP findings.

The systematic review was conducted according to a protocol submitted to the Spondyloarthritis Research and Therapy Network. A comprehensive search of several databases and abstracts from inception to January 11, 2022, was performed using a search strategy designed and conducted by an experienced librarian with input from the study's principal investigator (Supplementary Material 1).

We included RCTs (phase II and III) fulfilling the following criteria: 1) adults (≥18 years) with axSpA (radiographic axSpA [r-axSpA] and nonradiographic axSpA [nr-axSpA]), 2) treatment response assessed using quantitative scoring, 3) treatment efficacy reported for a particular therapy compared with placebo, 4) treatment efficacy reported by different MRI and CRP subgroups, and 5) MRI sacroiliac joint (SIJ) and CRP testing performed at baseline for more than 50% of participants. Data from long-term extension studies and experimental medications not approved by the US Food and Drug Administration for any other disease were excluded. The Preferred Reporting Items for Systematic Reviews and Meta-Analyses statement for reporting systematic reviews was followed (Figure 1) (10). Two authors (PK and RS) screened abstracts for eligibility, retrieved full texts, and excluded irrelevant articles. Disagreements were resolved by a discussion on eligibility. Bibliographies belonging to the included studies, reviews, and relevant articles were screened for additional studies. No language restrictions were made.

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Figure 1. Flowchart describing systematic search and study selection process. CRP, C-reactive protein; MRI, magnetic resonance imaging; nr-axSpA, nonradiographic axial spondylarthritis; r-axSpA, radiographic axial spondylarthritis.

Relevant data were extracted by one investigator (PK) and checked by two other authors (SG and RS). Full texts were considered in preference to conference abstracts unless the abstracts contained updated results. Additional summary data on subgroups were requested from pharmaceutical companies funding the RCTs and authors of the articles for investigator-initiated RCTs, where required.

Study outcomes were the difference in the Assessment of Spondyloarthritis International Society 40 (ASAS40) and Bath Ankylosing Spondylitis Disease Activity Index 50 (BASDAI50) in the drug versus placebo group. ASAS40 and BASDAI50 were chosen based on our preliminary review, which showed that most studies reported these measures. Additionally, these measures did not include the CRP, which is a criterion for our subgroup classification. We compared these measures between drug and placebo groups in the four different subgroups based on MRI positivity (MRI+) and elevated CRP levels (CRP+) at baseline: 1) MRI+/CRP+, 2) MRI+/CRP−, 3) MRI−/CRP+, and 4) MRI−/CRP−. The fourth subgroup (MRI−/CRP−) was not included in most trials because this group typically would not fulfill the ASAS40 classification criteria for axSpA (11).

Data from included studies were combined for meta-analysis using Review Manager (RevMan) version 5.4. Study-specific risk ratios (RRs) (at 12-16 weeks) were pooled using a random-effects model (12). The number needed to treat (NNT) was calculated as the inverse of the risk difference. Subgroup analyses were performed by treatment groups (eg, tumor necrosis factor inhibitors [TNFi] and interleukin-17 inhibitors [IL-17i]).

Studies were independently evaluated by two reviewers for risk of bias using the revised Cochrane risk of bias tool (RoB 2.0) for RCTs (13). We reviewed the subgroup analysis (post hoc) study together with its original RCT and substudies while assessing the risk of bias. The certainty in evidence was evaluated using the Grading of Recommendations, Assessment, Development, and Evaluation methodology (14). Publication bias was assessed visually using funnel plots (Supplementary Material 2). Between-study heterogeneity was assessed using I² statistics (ie, <30% = low heterogeneity, 30%-60% = moderate, and >60% = high) (15). Sensitivity analyses were performed to explore the likely causes of heterogeneity.

Of 2952 studies screened, five RCTs fulfilled our inclusion criteria. Among the included studies, there were three abstracts (16–18), one RCT article (19), and one post hoc analysis of an RCT (20) (Table 1). All studies included patients with nr-axSpA, and we did not find any r-axSpA studies fulfilling our inclusion criteria. Post hoc analysis of Ixekizumab in bDMARD-Naive and TNF Inhibitor Experienced Participants With Radiographic Axial Spondyloarthritis (COAST-V and COAST-W respectively) in r-axSpA could not be included because this study only provided data on treatment efficacy based on the MRI and CRP subgroups alone, and data on the four exclusive groups were not available (21). nr-axSpA was defined in the included studies based on ASAS classification criteria for nr-axSpA (11). MRI positivity (MRI+) was defined by the presence of inflammatory lesions on the SIJ according to the ASAS definition (22). All studies had a central reader for MRI interpretation, except the study comparing etanercept against a placebo for etanercept on a background nonsteroidal anti-inflammatory drug in the treatment of early spondyloarthritis patients who do not have x-ray structural changes (EMBARK) study, in which a single reader (one of the two radiologists) read the MRI. Only one study used a Spondyloarthritis Research Consortium of Canada (SPARCC) score of 2 or more as a criterion for defining MRI+ (21). CRP positivity (CRP+) was defined as a value above the upper limit of normal, and the cutoffs varied from 0 to 10 mg/l. MRI and CRP measures were obtained during the initial screening period for all the included studies.

Table 1 Baseline characteristics of the included studies

Abbreviations: ASAS, Assessment of Spondyloarthritis International Society; ASDAS, Ankylosing Spondylitis Disease Activity Score; BASDAI50, Bath Ankylosing Spondylitis Disease Activity Index; C-axSpAnd, Certolizumab Pegol Compared to Placebo in Subjects With axSpA Without X-ray Evidence of AS; COAST-X, Ixekizumab (LY2439821) in Participants With Nonradiographic Axial Spondyloarthritis; CRP, C-reactive protein; CS, systemic corticosteroids; CZP, certolizumab pegol; DMARD, disease-modifying antirheumatic drug; EMBARK, Study Comparing Etanercept Against a Placebo for Etanercept on a Background Nonsteroidal Anti-Inflammatory Drug in the Treatment of Early Spondyloarthritis Patients Who do Not Have X-ray Structural Changes; ETN, etanercept; GO-AHEAD, Effect of Golimumab in Participants With Active Axial Spondyloarthritis; GOL, golimumab; HCQ, hydroxychloroquine; hsCRP, high-sensitivity C-reactive protein; IXE, ixekizumab; LDA, low-disease activity; MI, major improvement; MRI, magnetic resonance imaging; MTX, methotrexate; nr-axSpA, nonradiographic axial spondylarthritis; NSAID, nonsteroidal antiinflammatory drug; PBO, placebo; PR, Partial Response; PREVENT, Study of Efficacy and Safety of Secukinumab in Patients With Non-radiographic Axial Spondyloarthritis; ULN, upper limit of normal; SEC, secukinumab; SF-36 PCS, Short Form 36 physical component summary; SPARCC, Spondyloarthritis Research Consortium of Canada; SSZ, sulfasalazine.

^aControlled phase duration.

All included studies were double-blind RCTs using placebo as the control group. The drugs studied were TNFi in three studies (N = 729) (16,18,20) and IL-17i in two studies (N = 794) (17,19). The effect of golimumab in participants with active axial spondyloarthritis (GO-AHEAD) study using golimumab (GOL) allowed concomitant use of only nonsteroidal antiinflammatory drugs (NSAIDs) (16); however, the other four studies continued to receive concomitant medications, including NSAIDs, corticosteroids of less than 10 mg, and conventional disease-modifying antirheumatic drugs. Among the TNFi, the follow-up duration was 12 weeks for etanercept and certolizumab studies (18,20) and 16 weeks for the GOL study (16). In the IL-17i studies, both studies had a controlled phase duration of 16 weeks (17,19). Detailed baseline characteristics by MRI and CRP subgroups were not available for most studies; however, the number of patients seemed balanced in the drug and placebo groups by different subgroups (Table 2).

Table 2 ASAS40 and BASDAI50 responses in the MRI/CRP subgroups of the included studies

Abbreviations: ASAS, Assessment of Spondyloarthritis International Society; BASDAI50, Bath Ankylosing Spondylitis Disease Activity Index; CRP, C-reactive protein; CZP, certolizumab pegol; ETN, etanercept; GLM, golimumab; IXE, ixekizumab; MRI, magnetic resonance imaging; NA, not applicable; Q2W, every 2 weeks; Q4W, every 4 weeks; SEC, secukinumab.

^aControlled phase duration.

All studies included ASAS40 as their primary outcome, except the subgroup analysis from the certolizumab pegol compared to placebo in subjects with axspa without x-ray evidence of as (C-axSpAnd) study (18). This study also reported the Ankylosing Spondylitis Disease Activity Score (ASDAS) major improvement; however, no studies reported BASDAI50. All other studies reported BASDAI50 as their secondary outcome (Table 1). Stratified analyses on baseline MRI and CRP were prespecified for all the included studies.

There was no significant difference in ASAS40 (P = 0.65, I² = 0%) or BASDAI50 (P = 0.27, I² = 24.1%) between the MRI and CRP subgroups. Treatment efficacy compared with placebo was statistically significant for the subgroups, except for the CRP−/MRI− subgroup (Figures 2 and 3), which included only two studies with 65 patients (Table 2) (20,23). The NNT was lower for the CRP+ compared with the CRP− subgroup. For ASAS40, NNTs were three for the CRP+/MRI+ and CRP+/MRI− subgroups and six for the CRP−/MRI+ and CRP−/MRI− subgroups. For BASDAI50, NNTs were three for the CRP+/MRI+ and CRP+/MRI− subgroups, eight for the CRP−/MRI+ subgroup, and 10 for the CRP−/MRI− subgroup. A sensitivity analysis on TNFi and IL-17i studies separately showed no difference between subgroups in terms of ASAS40 (TNFi, P = 0.88; IL-17i, P = 0.28) or BASDAI50 (TNFi, P = 0.34; IL-17i, P = 0.18) (Supplementary Materials 4 and 5). Similarly, when we examined subgroups based on either MRI or CRP, there were no statistically significant differences in MRI+ versus MRI− subgroups (P = 0.46, I² = 0%) and CRP+ versus CRP− subgroups (P = 0.27, I² = 26.1) (Supplementary Materials 6 and 7). However, numerically higher efficacy was noted in the CRP+ compared with the CRP− subgroup, and NNTs for CRP+ and CRP− were three and six, respectively. NNTs for MRI+ and MRI− were the same (four for both groups).

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Figure 2. Forest plot of ASAS40 response in the study drug (TNFi and IL-17i) versus placebo in the four MRI/CRP subgroups. ASAS40, Assessment of Spondyloarthritis International Society 40; CI, confidence interval; CRP, C-reactive protein; df, degrees of freedom; IL-17i, interleukin-17 inhibitor; IV, Inverse variance; MRI, magnetic resonance imaging; PBO, placebo; TNFi, tumor necrosis factor inhibitor.

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Figure 3. Forest plot of BASDAI50 response in the study drug (TNFi and IL-17i) versus placebo in the four MRI/CRP subgroups. BASDAI50, Bath Ankylosing Spondylitis Disease Activity Index 50; CI, confidence interval; CRP, C-reactive protein; df, degrees of freedom; IL-17i, interleukin-17 inhibitor; IV, Inverse variance; MRI, magnetic resonance imaging; PBO, placebo; TNFi, tumor necrosis factor inhibitor.

Statistical evaluation of publication bias was not feasible because only five trials were available. The included studies were judged to have low risk of bias (Supplementary Material 3A). Between-study heterogeneity within each subgroup assessed using I² statistics was low to moderate. Certainty in evidence for the outcome of efficacy rate when comparing all biologics with placebo was moderate despite some indirectness due to variation in MRI approaches and not taking into account the degree of inflammation (eg, SPARCC score), and some inconsistency between the estimates (Supplemental Material 3B).

This systematic review of five RCTs showed that all MRI and CRP subgroups in nr-axSpA showed treatment efficacy (in terms of ASAS40 or BASDAI50), except the CRP−/MRI− subgroup, which was underpowered and reported in only two studies. No significant difference in outcomes was noted between the subgroups based on MRI and CRP positivity. Although somewhat numerically higher treatment efficacy was noted in the CRP+ group, treatment efficacy was not different based on MRI positivity.

Our study showed numerically higher treatment efficacy in the CRP+ subgroup compared with the CRP− subgroup (RR 2.5 vs. 1.9), and the NNT was lowest for the CRP+ subgroup (NNT 3 vs. 6). However, the difference in treatment efficacy among the CRP subgroups was not statistically different (P = 0.24). Several studies have shown that baseline CRP can be a predictor of treatment response to biologics in axSpA (24). A real-world study of 1250 patients with ankylosing spondylitis (AS) showed a 7% increase in the likelihood of achieving ASAS40 response at week 12 of TNFi therapy with each 1-mg/dl increase in the CRP level (25). Similarly, the treatment response seen in the RAPID-axSpA trial, which required an elevated CRP level (CRP > 7.9 mg/l) even in the r-axSpA group, was much better compared with other studies (26). Most studies included in our analysis did not show a significant difference between treatment responses in drug versus placebo groups in the CRP− subgroup (16,19–21). However, our pooled analysis showed drug efficacy in this CRP− subgroup as well (Supplemental Materials 7A and B). The individual studies had a large confidence interval for their RRs and were most likely underpowered to show a difference within this CRP− subgroup.

Our study did not find a difference in the treatment efficacy based on MRI positivity. In fact, the NNTs for both MRI+ and MRI− groups were the same (NNT = 4). Studies examining the association between MRI positivity and treatment response in axSpA show disparate results. This is likely related to the definition of MRI+ used in the studies. MRI+ was defined by fulfillment of ASAS classification criteria in all but one study (21) in our systematic review. All nr-axSpA clinical trials require fulfillment of ASAS classification criteria for MRI if CRP is negative. However, this does not necessarily translate to a higher burden of axSpA. Similar to our study, Rudwaleit et al did not find a statistically significant association of MRI SIJ inflammation, and only high CRP levels and widespread inflammation of the spine were associated with a BASDAI50 response in this study of patients from two different RCTs with longstanding AS (mean disease duration 14 years) (2). Similarly, a subgroup analysis of patients from the adalimumab in patients with non-radiographic axial spondyloarthritis (ABILITY-1) study did not show a difference in ASAS40 response based on the presence of MRI SIJ inflammation or a SPARCC score of 2 or more with TNFi efficacy in axSpA (2,27). The latter study, however, did show a numerically higher response to adalimumab with a SPARCC score of 2 or more. More recently, a post hoc analysis of the ABILITY-3 study showed that higher SPARCC MRI SIJ scores predicted clinical remission (ASDAS ID (inactive disease) and ASAS ID (inactive disease) in active nr-axSpA at weeks 12 and 28 following treatment with adalimumab (28,29). Therefore, validated quantitative MRI scoring systems, such as the SPARCC scoring method for inflammation, are likely better predictors of treatment efficacy compared with MRI positivity according to ASAS criteria (30).

Some studies have suggested a graded treatment response based on MRI and CRP status, with the best response seen in double-positive (MRI+/CRP+) patients (18,20). The differences between the MRI and CRP subgroups were smaller when ASAS40 and BASDAI50 were examined as opposed to ASDAS (18), which includes CRP as one of the main contributing factors. Similarly, our pooled analysis did not show a significant difference in the ASAS40 and BASDAI50 responses among the MRI and CRP subgroups. The sensitivity analysis with subgroups based on either MRI or CRP alone (MRI+ vs. MRI− and CRP+ vs. CRP−) also suggested no significant difference. Therefore, our study showed that TNFi and IL-17i efficacy in nr-axSpA might not be significantly different among the MRI and CRP subgroups. Beyond the included studies, post hoc analysis of the COAST-V/W trials in r-axSpA did not find any difference in treatment efficacy among the MRI and CRP subgroups, and treatment efficacy was noted irrespective of baseline serum CRP levels or spinal MRI score (21). Of note, the study examined MRI spinal SPARCC scores and not SIJ. This study did not report exclusive MRI and CRP subgroups as outlined in our inclusion criteria and hence excluded. Only two of the studies in our systematic review included patients with MRI− and CRP− fulfilling the clinical arm of the ASAS classification (HLA-B27+/MRI−). No superior efficacy was noted in the treatment arm compared with the placebo arm in this subgroup, which was likely underpowered to note a difference (20,23). Also, a possibility of a wrong axSpA diagnosis should be considered in this subgroup, as is recommended with nonresponse by the 2022 ASAS European alliance of associations for rheumatology (EULAR) guidelines (31). Therefore, there is an unmet need to study this subgroup.

Our systematic review has several limitations. First, our study was limited to patients with nr-axSpA, and it is unclear if the study results are generalizable to r-axSpA. Next, we were not able to study patients in the CRP−/MRI− subgroup, and only two studies reported data on this subgroup and were underpowered. Third, the definitions of MRI and CRP positivity varied among the included studies, and a binary classification may not accurately capture the spectrum of CRP or MRI changes. The ASAS definition of MRI+ used in most studies may not amount to significant bone marrow edema; therefore, future studies should define MRI+ in terms of SPARCC scores with a uniform cutoff. Lastly, between-study heterogeneity was low to moderate. The sensitivity analysis for studies with TNFi and IL-17i compared with placebo did not show any statistically significant difference between the groups in terms of ASAS40 or BASDAI50. This stratification by therapy reduced some within-group heterogeneity, but it does not explain all of it.

In conclusion, our systematic review showed that there was no difference in outcomes between subgroups based on MRI and CRP characteristics. Although numerically higher treatment responses were noted with high baseline CRP levels, treatments were effective regardless of MRI and CRP positivity. Future studies should investigate the association of the degree of MRI inflammation (eg, SPARCC scores) and CRP elevation with treatment response in axSpA.

We would like to thank our librarian, Larry Prokop, for his help with the extensive search strategy.

All authors were involved in drafting the article and revising it critically for important intellectual content, and all authors approved the final version to be published. Dr. Karmacharya had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.

Gensler.

Karmacharya, Gensler.

Karmacharya, Gupta, Shahukhal, Khanal, Murad, Gensler.