Figures
Abstract
Background
Immune checkpoint inhibitors (ICIs) for treatment of non-small cell lung cancer (NSCLC) have been rapidly evolving. ICIs are likely to be more effective but also lead to escalating healthcare costs.
Objectives
The aim of this study was to evaluate the cost effectiveness of immune checkpoint inhibitors (ICIs) for treatment of non-small cell lung cancer (NSCLC).
Methods
We searched the PubMed, Web of Science, and Cochrane Library for studies comparing the cost effectiveness of ICIs for NSCLC. Potential studies identified were independently checked for eligibility by two authors, with disagreement resolved by a third reviewer. Quality of the included studies was evaluated using Consolidated Health Economic Evaluation Reporting Standards checklists.
Results
A total of 22 economic studies were included. Overall reporting of the identified studies largely met CHEERS recommendations. In the first-line setting, for advanced or metastatic NSCLC patients with PD-L1 ≥ 50%, pembrolizumab appeared cost-effective compared with platinum-based chemotherapy in the US and Hong Kong (China), but not in the UK and China. The cost-effectiveness of pembrolizumab versus chemotherapy for first-line treatment of NSCLC in PD-L1 ≥ 1% patients remained obscure. Regardless of PD-L1 expression status, pembrolizumab in combination with chemotherapy could be a cost-effective first-line therapy in the US. On the contrary, addition of atezolizumab to the combination of bevacizumab and chemotherapy was not cost-effective for patients with metastatic non-squamous NSCLC from the US payer perspective. In the second-line setting compared with docetaxel, pembrolizumab was cost-effective; though nivolumab was not cost-effective in the base case, it could be by increased PD-L1 threshold. Results of the cost-effectiveness of atezolizumab second-line treatment remained inconsistent. In addition, the adoption of durvalumab consolidation therapy after chemoradiotherapy could be cost-effective versus no consolidation therapy for patients with stage III NSCLC.
Citation: Ding H, Xin W, Tong Y, Sun J, Xu G, Ye Z, et al. (2020) Cost effectiveness of immune checkpoint inhibitors for treatment of non-small cell lung cancer: A systematic review. PLoS ONE 15(9): e0238536. https://doi.org/10.1371/journal.pone.0238536
Editor: Isabelle Durand-Zaleski, URCEco Ile de France Hopital de l’Hotel Dieu, FRANCE
Received: April 3, 2020; Accepted: August 18, 2020; Published: September 2, 2020
Copyright: © 2020 Ding et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the manuscript and its Supporting Information files.
Funding: The financial disclosure should be revised as follows: Financial Disclosure: This work was supported by Natural Science Foundation of Zhejiang Province (LQ19H280001); Projects of Medical and Health Technology Program in Zhejiang Province (2019KY037).
Competing interests: The authors have declared that no competing interests exist.
Introduction
Lung cancer is the most common cancer and the leading cause of cancer mortality worldwide, with an estimated incidence of more than 2 million cases and approximately 1.8 million deaths [1]. Non-small cell lung cancer (NSCLC) accounts for 80–90% of lung cancer. Up to approximately 55% of cases are diagnosed at a metastatic stage, which leads to poor long-term prognosis [2].
Patients with targetable genetic aberrations gain significant benefits from targeted therapies; however, the subsets represent a small fraction of patients with NSCLC [3]. Over a long period in the past, the majority of patients without an identified molecular subtype relied primarily on traditional chemotherapy with modest improvement in outcome. The recent introduction of immune checkpoint inhibitors (ICIs), namely monoclonal antibodies directed against programmed death receptor 1 (PD-1), programmed death ligand 1 (PD-L1) and cytotoxic T-cell lymphocyte antigen-4 (CTLA-4) monoclonal antibodies, has resulted in an increase in overall survival (OS) rates of patients with advanced NSCLC on the basis of numerous clinical trials [4–10]. Therefore, ICIs have become the standard of care in appropriate clinical circumstances for patients with NSCLC.
Given the rising economic burden of cancer care, for example, cancer care in the United States is expected to reach $173 billion by 2020, cost is becoming an increasingly critical consideration in cancer care other than clinical benefit and toxicity [11]. Cost-effectiveness analysis is an important strategy to assess whether new interventions provide clinical benefit at a reasonable cost, which has major implications on health policy and public policy [12, 13]. As such, evaluating the cost effectiveness of new and expensive oncology therapies is of great concern.
ICIs represent the fastest growing part of the oncology therapeutics market, heightening the need for economic evaluation of these novel agents [14, 15]. Verma V. et al. conducted a systematic review to evaluate the economic impact of ICIs, and analyzed studies of head/neck, lung, genitourinary, and melanoma malignancies treated with ICIs, demonstrating that pembrolizumab was cost-effective for NSCLC while nivolumab was not [16]. However, plenty of new cost-effectiveness investigations associated with ICIs for treatment of NSCLC have been published along with constantly updated ICIs clinical trials, which could substantially alter the above-mentioned conclusions.
Objectives
As expansion in the availability of immune checkpoint inhibitors in NSCLC continues, the aim of this review was to make an overview of the currently available literature on cost-effectiveness of immune checkpoint inhibitors in treatment of NSCLC and to satisfy the need of decision makers to maximize benefits under resource constraints.
Methods
Databases and search strategy
The systematic review was performed following the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines (S1 File) [17]. We searched the PubMed, Web of Science, Cochrane CENTRAL databases in December of 2019. The main search terms included non-small cell lung cancer, immunotherapy, immune checkpoint inhibitor, PD-1, PD-L1, cost, and economic. Based on guidelines for management of NSCLC, we also included the following agents in the search: pembrolizumab, nivolumab, atezolizumab, ipilimumab and durvalumab. No language or date restrictions were initially imposed. The detailed search strategy is shown in the S2 File. Moreover, references cited in the identified studies, recent review articles and other relevant studies were also scrutinized to identify potentially relevant articles that may have been missed in the original search. Unpublished abstracts were not included due to the inability to fully evaluate validity and methodologies. We de-duplicated the identified results using EndNote® (Clarivate Analytics) [18].
Eligibility criteria
Studies were eligible for review if they performed a cost-effectiveness analysis (CEA) or cost-utility analysis (CUA) that assessed the immune checkpoint inhibitors for NSCLC. The related immune checkpoint inhibitors for NSCLC include anti-PD-1 agents (nivolumab and pembrolizumab), anti-PD-L1 agents (atezolizumab and durvalumab) and anti-CTLA-4 agents (ipilimumab). Studies were excluded if they (1) assessed only the cost or effectiveness of therapeutic regimens; (2) did not report the effectiveness as quality-adjusted life year (QALY); (3) absence of a report summarizing statistical result, such as an incremental cost-effectiveness ratio (ICER); (4) were not written in English; or (5) were case reports, letters, news, comments, editorials, conference abstracts, or systematic reviews.
Review for inclusion
The titles and abstracts of all potential studies identified were checked for eligibility independently by two investigators. The eligible studies were proceeded to a full-text review by the two investigators to finalize study selection. Disagreement between the two investigators were resolved by a third investigator.
Data extraction and synthesis
Data from the selected studies were extracted and synthesized in Microsoft Excel. Data collected included first author, country, publication year, sponsorship source, study population, study design (type of economic evaluation), study perspective (societal, health provider, payer, etc.), model structure, time horizon, interventions, year of costing, type of currency, source of cost, source of effectiveness, outcome measure, sensitivity analysis, willingness-to-pay threshold, results (total costs, effectiveness and ICER, etc.) and conclusion.
Quality assessment
Quality assessment was independently performed by two investigators using the CHEERS (Consolidated Health Economic Evaluation Reporting Standards) checklist, which was developed by a task force supported by the International Society for Pharmacoeconomics and Outcomes Research (ISPOR) [19]. The CHEERS checklist, aiming to optimize reporting of health economic evaluations, comprises 24 items which are subdivided into six categories: (1) title and abstract, (2) introduction, (3) methods, (4) results, (5) discussion, and (6) other.
Data analysis
Total costs, effectiveness (QALYs), and ICERs were compared among the included studies, stratified by treatment line. To make a comparison between the different currencies used in different countries, the reported costs were converted into US dollars (2019) using a web-based tool. In addition, the authors’ conclusions regarding their modeled interventions were reported.
Results
In the initial search, 510 records were identified from the databases (Fig 1). Following removal of duplicates, titles and abstracts of 368 studies were screened. Of these, 341 irrelevant records were excluded. A total of 27 articles were then fully reviewed and assessed for eligibility. Finally, 22 studies were included in this systematic review [20–41].
PRISMA, Preferred Reporting Items for Systematic Reviews and Meta-Analyses.
Characteristics of the included studies
The characteristics of all included studies are presented in S1 Table. Most of the studies were conducted in 2019 [28–41]. Studies were conducted from countries all over the world, with ten from the USA [22–27, 29, 30, 32, 33], seven from China (one from HongKong) [34–36, 38–41], two from Canada [20, 37], and one each from Australia [31], France [28] and Switzerland [21]. Most studies were assessed from the perspective of health care system (N = 12) [20–22, 25, 26, 28–31, 35, 37, 40], some used a payer perspective (N = 8) [23, 24, 27, 32, 33, 38, 39, 41], and the remainder used a perspective of society (N = 1) [34] and hospital authority (N = 1) [36].
The majority of the studies (N = 14) [23, 25–28, 30, 32–34, 36, 38–41] analyzed the cost-effectiveness of ICIs in the first-line treatment of NSCLC, of which one study was for patients with squamous cell carcinoma (SCC) and four studies were for non-SCC, while 7 studies [20–22, 24, 31, 35, 37] in second-line treatment (one study for SCC and two studies for non-SCC) and one study in stage III NSCLC after chemoradiotherapy [29]. Treatments compared in each study varied across studies. Among studies analyzing the first-line treatment, most studies compared pembrolizumab with platinum-based chemotherapy based on KEYNOTE 024 [9] or KEYNOTE 042 trial [42] (N = 10) [23, 25, 26, 28, 32, 34, 36, 38, 40, 41]. The remainders evaluated pembrolizumab plus chemotherapy versus chemotherapy alone or pembrolizumab alone, combination of atezolizumab and chemotherapy versus chemotherapy. As for second-line treatment, the majority of the studies assessed nivolumab versus docetaxel (N = 4). In total, the most commonly modeled intervention was pembrolizumab (N = 13), followed by nivolumab (N = 5), atezolizumab (N = 3), durvalumab (N = 1) and a mix of treatment options (N = 1).
All of the included studies built economic models to assess the cost-effectiveness of ICIs. Of these, ten studies used Markov model, five studies used a partitioned survival model and two studies adopted both. Other models included decision-analytic model, cohort simulation model and microsimulation model. The time horizon evaluated by the studies varied significantly. Most studies evaluated a time horizon of lifetime, and the shortest time horizon included was 5 years in the study assessing durvalumab consolidation therapy, whereas one study did not report the time horizon of analysis.
Cost-effectiveness outcomes
Table 1 summarizes the outcomes of the included studies according to treatment line (first-line, second-line and locally advanced cancer) and PD-L1 expression level (Table 1).
In the first-line treatment setting, studies were differentiated according to PD-L1 expression levels (PD-L1 ≥ 50%; PD-L1 ≥ 1%; all PD-L1 expression levels). For patients with PD-L1 ≥ 50%, pembrolizumab could be a cost-effective first-line treatment compared with platinum-based chemotherapy from the perspective of US health care system or third-party payer [23, 25], French healthcare system [28] and Hospital Authority in Hong Kong (China) [36], while not cost-effective in the UK [25, 26], France [28] or China [34]. Four studies evaluated the cost-effectiveness of first-line treatments in PD-L1 ≥ 1% patients [32, 38, 40, 41]. Of these, one study indicated that pembrolizumab was cost-effective compared with platinum-based chemotherapy in patients with all PD-L1 expression level (≥ 50%, ≥ 20%, and ≥ 1%) from the US health care perspective [40]. Nevertheless, another study analyzed from the perspective of US third-party public healthcare payer showed that pembrolizumab was cost-effective in patients with PD-L1 ≥ 1%, but not in the subgroup with PD-L1 1~49% [32]. Similarly, She et al. concluded that pembrolizumab was cost-effective in PD-L1 positive patients (PD-L1 ≥ 50%), but not in the PD-L1 ≥ 20% and ≥ 1% populations in the US [38]. Additionally, Zhou et al. assessed the cost-effectiveness of pembrolizumab from Chinese perspective and found that pembrolizumab is not cost-effective compared with PBC regardless of PD-L1 expression level (≥ 50%, ≥ 20%, and ≥ 1%) [41]. Pembrolizumab and atezolizumab are recommended for use in combination with chemotherapy as first-line treatment regardless of PD-L1 expression status based on KEYNOTE 189, KEYNOTE 407 trial and IMpower150 trial [5, 6, 43]. Insinga et al. [27, 33] evaluated the cost-effectiveness of pembrolizumab plus chemotherapy versus chemotherapy and pembrolizumab monotherapy from the US third-party healthcare payer perspective, and found that this combination might be cost-effective in the first-line treatment of both squamous and non-squamous NSCLC cancer. Two studies investigated the cost-effectiveness of atezolizumab, and results showed that addition of atezolizumab to the combination of bevacizumab, carboplatin, and paclitaxel was not cost-effective for patients with metastatic non-squamous NSCLC from the US payer perspective [30, 39].
Apart from the above-mentioned researches about first-line treatments, six studies assessed the second-line treatments. The earliest study was conducted in 2016 in Canada, from a perspective of publicly-funded healthcare system [20]. This study estimated the cost-effectiveness of nivolumab compared with docetaxel or erlotinib in the second-line treatment of advanced squamous NSCLC, and compared the results using partitioned survival and Markov models, demonstrating these two modelling approaches produced very similar estimates of expected cost, outcomes, and ICER. However, no particular willingness-to-pay (WTP) threshold was mentioned in this study. Subsequently, plenty of economic studies around the world also evaluated the cost-effectiveness of second-line therapies for patients with recurrent NSCLC. Three studies, one each from Switzerland, US and China, showed that nivolumab is not cost-effective compared with docetaxel for patients with previously treated advanced NSCLC [21, 31, 35]. Huang et al. [24] found that pembrolizumab is cost-effective versus docetaxel in pre-treated advanced NSCLC patients with PD-L1 ≥ 50% from the US third-party payer perspective. Additionally, atezolizumab was proved to be a cost-effective therapeutic option in Canada for the treatment of patients with advanced NSCLC who progressed after first-line chemotherapy [37]. Given various options for second-line treatment of advanced NSCLC, Aguiar et al. [22] assessed the cost-effectiveness and economic impact of PD-L1 testing and the above-mentioned three second-line ICIs versus docetaxel. Relative to docetaxel, atezolizumab is not cost-effective; pembrolizumab is cost-effective; though nivolumab is not cost-effective in the base case, it can be cost-effective by increased PD-L1 threshold.
In addition, a study evaluated the cost-effectiveness and potential economic implications of durvalumab, which is the first immunotherapy to be approved for adjuvant treatment of patients with unresectable stage III NSCLC who has not progressed after chemoradiotherapy, in the context of the US health care system [29]. Results demonstrated that durvalumab consolidation therapy can be cost-effective versus no consolidation therapy.
Quality assessment
The included studies had a good reporting quality as per the CHEERS checklist (Fig 2 and S3 File). The least commonly reported item in the included studies was “characterizing heterogeneity,” followed by “assumptions” and “currency, price date, and conversion.” With regard to parameter uncertainty, twenty studies performed one-way sensitivity analysis, twenty studies performed probabilistic sensitivity analysis (PSA), and two studies performed alternative scenario analysis.
Discussion
In this systematic review, we identified and included 22 studies that evaluated the cost-effectiveness of immune checkpoint inhibitors for treatment of NSCLC. Overall reporting of the identified studies largely met CHEERS recommendations.
In the first-line setting, for patients with PD-L1 ≥ 50%, pembrolizumab appears cost-effective compared with platinum-based chemotherapy in the US and Hong Kong (China), but not in the UK and China. The disparity of the results can be explained by different WTP thresholds across different countries. The conclusions of several studies changed as the WTP threshold increased. Taking various ICER results into account, pembrolizumab could be a cost-effective first-line treatment if WTP threshold set as $100,000/QALY in PD-L1 ≥ 50% patients. The cost-effectiveness of pembrolizumab versus chemotherapy for first-line treatment of NSCLC in PD-L1 ≥1% patients remained obscure. Various factors may explain the difference in the results including variation of drug cost in different countries as well as discrepancy in model parameters. Regardless of PD-L1 expression status, pembrolizumab in combination with chemotherapy can be a cost-effective first-line therapy in the US. On the contrary, addition of atezolizumab to the combination of bevacizumab, carboplatin, and paclitaxel is not cost-effective for patients with metastatic non-squamous NSCLC from the US payer perspective. Even if the threshold is raised to $150,000/QALY, atezolizumab combination cannot be an economic solution in the first-line setting.
In the second-line setting compared with docetaxel, pembrolizumab is cost-effective; though nivolumab is not cost-effective in the base case, it can be cost-effective by increased PD-L1 threshold. It indicates that the use of PD-L1 expression as a biomarker improves the cost-effectiveness of second-line immunotherapy. Results of the cost-effectiveness of atezolizumab second-line treatment remains inconsistent. This is due in part to differences in currencies and healthcare systems between countries and different models adopted for simulation.
In addition, the adoption of durvalumab consolidation therapy after chemoradiotherapy can be cost-effective versus no consolidation therapy for patients with stage III NSCLC, representing an indication that treating with expensive immunotherapy earlier in the course of cancer progression can also provide significant value.
The published systematic reviews of cost-effectiveness studies in immune checkpoint inhibitors are limited. A systematic review by Verma et al. [16] was the first known comprehensive review of cost-effectiveness analysis pertaining to immune checkpoint inhibitors. Since a great many new cost-effectiveness analysis studies were published thereafter, we searched broader databases and included several additional studies for NSCLC treatment. In addition, we summarized and compared more detailed methodological information of the included studies. Subsequently, Addeo et al. [44] evaluated the cost-effectiveness of checkpoint inhibitors plus chemotherapy compared with chemotherapy alone for the first-line treatment of patients with advanced NSCLC. Our results are not directly comparable as this review focused solely on combination of immunotherapy with chemotherapy.
Of note, both abovementioned systematic reviews did not perform quality assessment on the methodological aspects of the included studies. Quality assessment is one of the important steps in developing a good systematic review of cost-effectiveness studies. The most commonly adopted instruments for quality assessment include CHEERS checklist, Quality of Health Economics Studies (QHES) instrument, the Philips and the Drummond checklists, et al. CHEERS checklist was developed by international experts, and jointly endorsed by many journals [19, 45, 46]. A plenty of previous studies have adopted the CHEERS checklist for assessing the quality of published economic studies [47, 48]. Therefore, the quality assessment was conducted using the CHEERS checklists in the present systematic review. Overall, quality of the included studies was high with majority of studies reported strictly according to the CHEERS checklist.
As far as we know, this is the first systematic review to assess the cost-effectiveness of immune checkpoint inhibitors for patients with NSCLC. The majority of published literature reporting cost-effectiveness evaluation pertaining to immunotherapies for NSCLC treatment was included in our analysis, including first-line and second-line treatment for advanced or metastatic disease as well as earlier treatment for stage III carcinoma. Nevertheless, our review has some limitations. First, we restricted our review to studies written in English. In addition, some of the relevant studies may not have been retrieved despite the use of broad search terms in commonly used databases. Finally, the studies included in this review were conducted from different perspectives and countries, and adopting different WTP threshold, leading to difficulties in interpreting the conclusions.
Conclusion
For patients with NSCLC, immunotherapy can be a cost-effective strategy in several scenarios. A discount of the agents or the use of PD-L1 expression as a biomarker improves the cost-effectiveness of immunotherapy. Future publications of economic evaluation pertaining to immune checkpoint inhibitors for treatment of NSCLC could alter conclusions from this review.
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