Abstract
Background
Immune checkpoint inhibitors (ICI) are increasingly used across multiple cancer types and stages and little is known about real-world outcomes. This study sought to determine healthcare utilization, costs, immune-related adverse events (irAEs), and all-cause mortality of single-agent versus combination ICI in the USA.
Materials and methods
This is a retrospective study conducted with 2016–2018 data from the HealthCore Integrated Research Database, consisting of commercial and Medicare-insured adult patients with a cancer diagnosis using ICI in the USA. Outcomes were healthcare utilization, costs, and irAEs (FDA-recognized and others) up to 1-year post-index between patients using ICI monotherapy (mono, PD-1/PD-L1 inhibitor) and combination therapy (combo, PD-1/PD-L1 with CTLA-4 inhibitors).
Results
In total, 9084 patients received monotherapy and 904 patients received combo therapy. Mean age 65 years for mono and 58 years for combo. Overall, the combo arm had higher rates of FDA-recognized irAEs (67.4% vs. 45.9%), especially endocrinopathies (27.7% vs 14.7%) and dermatitis (25.9% vs. 12.4%). All-cause mortality over 1-year follow-up was similar, 30.7% in mono vs 30.8% in combo arms. The combo group had higher rates of all-cause inpatient hospitalizations (55.4% mono vs 65.6% combo) and emergency department (ED) visits (33.7% mono vs 41.4% combo). IrAE-related hospitalizations were higher in combo (55.2% vs 42.1%). IrAE-related ED visits were 15.7% mono vs 22.7% combo. This increased toxicity and health care utilization was reflected in significant differences in healthcare costs. Stark differences were seen in all-cause medical costs as well as costs related to inpatient and ED utilization and costs attributed to irAEs.
Conclusions
Higher rates of irAEs, healthcare utilization, and costs occur with combination immunotherapy. As further indications are approved for combination ICI, our study highlights the real-world tradeoffs involved with combination therapy regarding burdens of toxicity and increased healthcare utilization.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
ICI therapy was initially approved in 2011 for melanoma. Since then, utilization of ICI has amplified across different tumor types and stages. ICI are also being approved in combination with chemotherapy, biotherapy, and targeted therapy in the treatment of various malignancies. In 2011, < 2% of cancer patients were eligible for ICI and in 2019, this number had increased to 40% [1]. Despite the promise of ICI in controlling disease and sometimes extending survival, their use is limited by immune-related adverse events (irAEs). The cost effectiveness of ICI is not fully understood and little is known about factors associated with irAEs and mortality from these agents.
To evaluate the healthcare utilization and cost in clinical practice in the USA, we retrospectively reviewed the data from HealthCore Integrated Research Database (HIRD), a large database of clinical data from a large payer program [2]. We reviewed healthcare utilization, cost, all-cause mortality, and irAEs in patients utilizing ICI as monotherapy or in combination with another ICI up to 1-year post-index. Study subjects had commercial or Medicare Advantage insurances. We hypothesize that study findings will help assess the impact of the emerging trend of combination therapy (addition of CTLA-4 inhibitors to PD-1 or PD-L1 inhibitors) regarding the adverse event risk and associated costs. These data may inform clinical guideline development and choices by patients and physicians in the context of shared decision-making.
The primary objective of this retrospective study was to evaluate healthcare utilization and cost up to 1-year post-index between patients using ICI monotherapy (PD-1/PD-L1 inhibitor) and combination therapy (PD-1/PD-L1 with CTLA-4 inhibitors) among the commercial and Medicare insured population. Secondary objectives include comparing the rates of all-cause mortality and irAEs in these same cohorts.
Materials and methods
In this retrospective cohort analysis, we used claims from April 2016 to December 2018 to identify members with ≥ 1 claim for any ICI. The index date was assigned as first claim for the ICI. The baseline period was calculated 6 months prior to index date and the follow-up period was assigned from index date until the earliest of the end of eligibility (due to disenrollment or death), or the end of index date plus 1 year. The study cohort consisted of patients aged 18 or greater using ICI in the time period from April 2016 to December 2018 with ≥ 1 inpatient/ER or ≥ 2 outpatient claims with a cancer diagnosis within the preceding 6 months. Continuous medical and pharmacy eligibility in the 6 months prior to index date was required. No eligibility was required in the follow-up period. The eFigure in the Supplement illustrates our cohort definition procedure, including inclusion and exclusion criteria. After applying inclusion/exclusion criteria, the following two groups were created:
-
PD-1/PD-L1 inhibitor monotherapy — members who received a PD-1 or PD-L1 inhibitor agent without a concurrent CTLA-4 inhibitor within 30 days of index PD-1/PD-L1 claim. Members were excluded if they had any of the study immunotherapy agents in the 6-month baseline period.
-
PD-1/PD-L1 inhibitor combination therapy with CTLA-4 inhibitor — members who have used a PD-1 or PD-L1 inhibitor agent with a concurrent CTLA-4 inhibitor within 30 days of index PD-1/PD-L1 claim. Members were excluded if they had any of the study immunotherapy agents in the 6-month baseline period.
Mortality and irAEs
Mortality at 1 year was determined from the Social Security Death Index [3], hospital claim discharge records, or health plan disenrollment records.
We used irAEs from FDA Label information [4] and other exploratory irAEs; the full list of individual irAEs and their respective ICD10 diagnosis codes are listed in eTables 1 and 2. We defined new incidence of irAEs in the post-index period as those where the irAEs did not exist in the baseline period.
Post-index all-cause and irAE-related utilization and cost
Cost and utilization outcomes consisted of measures that included all-cause and irAE-related hospitalizations, emergency department (ED) visits, physician office visits, and physician office visits related to Hematology-Oncology providers. All-cause and irAE-related total, health plan paid, and patient paid costs for healthcare utilization were also assessed. Claims with any irAE condition in any of the diagnosis fields were considered for irAE-related utilization and cost. Costs are presented per-patient-per-month (PPPM).
Covariates
Baseline demographic characteristics included age, sex, region, health plan type, index year, and other additional information obtained at 9-digit zip code level (e.g., race/ethnicity, median household income, Socio-economic category, and level of education). Baseline 6-month clinical characteristics consisted of the Deyo-Charlson Comorbidity Index (DCI) score excluding malignancy, weight, and claims-based ECOG score categories [5]. Important comorbidities like autoimmune conditions (rheumatoid arthritis, psoriasis/psoriatic arthritis, ulcerative colitis, Crohn’s disease, ankylosing spondylitis, juvenile chronic polyarthritis, hypo/hyper thyroid [including thyroid replacement treatment]), immune-compromised conditions (HIV, stem cell transplants), type of cancer (breast, lung, colorectal, melanoma, renal cell, bladder, head neck, gastric, esophageal, hepatocellular, lymphoma, squamous cell carcinoma, merkel cell carcinoma), and baseline irAEs were collected. Baseline medication captured included prior chemotherapy use, other immunosuppressive therapy (infliximab, vedolizumab, mycophenolate mofetil, intravenous immunoglobulin, plasmapheresis, rituximab, tacrolimus, tocilizumab, cyclosporine, cyclophosphamide, methotrexate, sulfasalazine, leflunomide), and antibiotic use (oral and IV). Other baseline measures included BMI ≥ 30, utilization, and cost.
Statistical analysis
Patient demographic baseline and post-index unadjusted characteristics were summarized as means with standard deviations and medians with interquartile range for continuous variables and number and proportions for categorical variables. Differences in baseline characteristics were compared between monotherapy and combination therapy, using T-test (or Wilcoxon rank-sum test for non-normal distributions) for continuous variables and chi-square or Fisher’s exact test for categorical variables.
For adjusted analysis, we used multivariable Cox proportional hazards regression model to report the hazard ratio (HR) and 95% confidence intervals (CI) for irAE incident outcome measures. Cost and utilization outcomes were analyzed using multivariable logistic regression for binary variables, Poisson regression for count variables, and model with gamma distribution for cost variables. Regression analyses adjusted for age, sex, region, insurance plan type, index year, Deyo-Charlson Comorbidity Index score, selected cancer type (lung, melanoma, renal cell, and head/neck), prior chemotherapy, high-dose corticosteroids, and antibiotics use. All analyses were conducted using SAS Enterprise Guide, version 7.15 (SAS Institute Inc.). Statistical significance was set at a 2-sided p = 0.05.
Results
In this analysis, 9084 patients received PD-1/PD-L1 monotherapy (mono) and 904 patients received combination (combo) of CTLA-4 with PD-1/PD-L1 therapy. The patient characteristics and tumor types are presented in Tables 1 and 2. In the 1-year post-index period of this study, the average follow-up time was similar between two groups (7.6 [4.4] months in mono vs. 7.8 [4.5] months in combo therapy, p = 0.379). We found that the majority of patients received monotherapy in comparison to combination therapy. Lung and melanoma were the leading cancer types treated in the mono arm, melanoma, and lung in combo arm. Patients treated in the combo arm were younger and male predominant compared to mono arm. The ECOG performance status was similar in both arms. The mono group had a higher rate of prior chemotherapy utilization.
Overall, the combo arm had higher rates of irAEs. The combo group also experienced higher rates of other types of incident irAEs. All-cause mortality over 1-year follow-up was similar in both arms, 30.7% in mono vs 30.8 in combo arms with HR 1.56 (1.37–1.79). The combo group had higher rates of all cause inpatient hospitalizations (55.4% in mono vs 65.6% in combo) and emergency department (ED) visits (33.7% in mono vs 41.4% in combo). IrAE-related hospitalizations in the mono arm were 42.1% vs 55.2% in combo with OR 2.17 (CI 1.87–2.53). IrAE-related ED visits were 15.7% in mono vs 22.7% in combo. Table 3 outlines significant differences in medical costs between mono and combo ICI therapy and Table 4 outlines unadjusted and adjusted means for total medical costs. Differences are noted in total medical costs, inpatient utilization costs, and ED and outpatient costs. These differences are seen in health-plan costs, but, importantly, are also seen in patient costs. The adjusted means can be quite different, leading to the results seen in Tables 3 and 4. The purpose of showing the adjusted differences was to show that the differences between combination and monotherapy were statistically significant (confidence interval does not contain 0).
The unadjusted FDA and exploratory irAEs are shown in Figs. 1 and 2, and the results of the adjusted Cox regression for incident irAE outcomes are presented in Table 2. The overall utilization and cost outcomes are presented in Tables 3 and 4.
Discussion
To our knowledge, this is the first large retrospective study examining utilization and costs of ICI in the standard clinical practice setting. This study’s primary objective was to evaluate healthcare utilization and cost of mono and combination ICI therapy among the commercial and Medicare Advantage population up to 1-year post-index. We also compared rates of all-cause mortality and irAEs in this population.
A key element of this study was enumerating the incidence of irAEs in patients receiving both mono and combo therapy and assessing the differences. From other studies, such as published by Brown et al., showed that 61.8% experienced irAEs with ICI [6] and fatal irAEs occurred at 0.3–1.3% and often resulted in rapid clinical deterioration [7]. In our study, we observed these irAEs were a leading cause of toxicity in monotherapy: endocrinopathies, nephritis, dermatitis, hepatitis, and neuropathy and in combination therapy: endocrinopathies, dermatitis, nephritis, hepatitis, colitis, and neuropathy. As expected, it was observed that the combo arm had a greater rate of irAES. This was associated with an increase in all-cause hospitalizations, all-cause ED visits, and irAE-associated hospitalizations and ED visits. Our objective of the study was to capture important symptoms that patients experienced as well as more defined clinical diagnoses reflected in the claims. It is important to note that we used a broad definition of irAEs for the purposes of our study. This led to the identification of more irAEs than were reported in other single institution studies looking at chart-reviewed ED visits for patients undergoing ICI therapy [8, 9]. It is worth noting that the safety data concerning ICI therapy is limited to outpatients with good performance status. All-cause mortality was similar in both groups, which could be related to clinicians developing skills in identifying and treating toxicities earlier.
There is still much to understand about irAEs and multiple societal guidelines for irAE and ICI usage such as ASCO, ESMO, and MASCC are available to guide clinicians [10,11,12]. For example, it is not clear who is at highest risk for these toxicities, or why severe toxicities happen in certain populations. To develop and validate a prediction tool for irAEs, the SouthWest Oncology Cancer Research Network (SWOG) is currently enrolling solid tumor patients who are receiving ICI as mono or in combination with other ICIs (Immune Checkpoint Inhibitor Toxicity (I-CHECKIT).
This study is the first study reporting the healthcare utilization and cost in commercial and Medicare Advantage insured patients in the USA, which reflects the majority of clinical practice. Data from this study can support proper use of ICI in clinical practice and educate clinicians about the toxicity, care utilization, and cost.
Several limitations must be noted due to the retrospective and claims-based nature of our data. First, there were some missing data. For example, not all patients had performance status scores reported for their respective cancers. To address this, we used a claims-based algorithm as a proxy for ECOG status, which mapped well to patients who did have existing ECOG scores. We did not know the grade of tumor or stage of cancer, which may have affected selection of treatment and complicates the interpretation of all-cause mortality. ICD codes were used to identify cancers, irAEs, and comorbid conditions. There may have been errors or inaccuracies in coding. Moreover, we could not determine causal relationships between irAEs and use of ICIs. It is recognized that there are differences in reporting of various irAEs in our dataset compared to other publications. Our data reflects a large patient population across all types of practice settings, and diagnoses are based on coding of claims data. These methods reflect real-world practice. Some irAEs such as nephritis appear high and may also reflect an under appreciation of this potential toxicity in clinical practice. However, we tried to mitigate this by using incident, rather than prevalent irAEs. Finally, the study population consisted of patients with commercial or Medicare Advantage insurance in the USA and these data may not be generalizable to other populations such as the Medicaid population and outside of the USA.
Conclusions
This large retrospective analysis of healthcare utilization and cost in commercial and Medicare Advantage patients receiving ICI in 1-year post-index period showed higher rates of irAEs, all-cause hospitalization and ED visits, irAE-related hospitalizations, and ED visits with combination ICI compared to monotherapy. These data provide useful estimates to help inform clinicians on the effects of combination therapy and for guideline development and application of relative clinical value frameworks in oncology. There are an increasing number of indications with combination ICI across multiple tumor types, and this study brings attention to the realities related to toxicity, utilization, and costs for clinicians who engage in shared decision-making with cancer patients. Based on published clinical trial data alone, it is far too easy to overlook the scope and importance of toxicities and costs for exciting new realms of cancer therapy.
Data availability
We do not have full control of the primary data and thus, data are not available for sharing.
Code availability
Code is not available for sharing due to use of proprietary software for data acquisition.
References
Gill J, Prasad V (2019) A reality check of the accelerated approval of immune-checkpoint inhibitors. Nat Rev Clin Oncol 16(11):656–658
Fishman E, Barron J, Liu Y et al (2019) Using claims data to attribute patients with breast, lung, or colorectal cancer to prescribing oncologists. Pragmat Obs Res 10:15–22
Ashana DC, Chen X, Agiro A, et al. Advance care planning claims and health care utilization among seriously ill patients near the end of life. JAMA Netw Open. 2019;2(11):e1914471.
Wang Q, Xu R (2019) Immunotherapy-related adverse events (irAEs): extraction from FDA drug labels and comparative analysis. JAMIA Open 2(1):173–178
Sheffield KM, Bowman L, Smith DM et al (2018) Development and validation of a claims-based approach to proxy ECOG performance status across ten tumor groups. J Comp Eff Res 7(3):193–208
Brown VT, Antol DD, Racsa PN, Ward MA, Naidoo J. Real-world incidence and management of immune-related adverse events from immune checkpoint inhibitors: retrospective claims-based analysis. Cancer Invest. 2021:1–23.
Wang DY, Salem JE, Cohen JV et al (2018) Fatal toxic effects associated with immune checkpoint inhibitors: a systematic review and meta-analysis. JAMA Oncol 4(12):1721–1728
Cooksley T, Gupta A, Al-Sayed T, Lorigan P (2020) Emergency presentations in patients treated with immune checkpoint inhibitors. Eur J Cancer 130:193–197
El Majzoub I, Qdaisat A, Thein KZ et al (2019) Adverse effects of immune checkpoint therapy in cancer patients visiting the emergency department of a comprehensive cancer center. Ann Emerg Med 73(1):79–87
Schneider BJ, Naidoo J, Santomasso BD et al (2021) Management of immune-related adverse events in patients treated with immune checkpoint inhibitor therapy: ASCO guideline update. J Clin Oncol 39(36):4073–4126
Haanen J, Carbonnel F, Robert C, et al. Management of toxicities from immunotherapy: ESMO clinical practice guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2018;29(Suppl 4):iv264-iv266.
Rapoport BL, Anderson R, Cooksley T, Johnson DB (2020) MASCC 2020 recommendations for the management of immune-related adverse events of patients undergoing treatment with immune checkpoint inhibitors. Support Care Cancer 28(12):6107–6110
Funding
Funding for this research was provided by Anthem, Inc.
Author information
Authors and Affiliations
Contributions
All authors contributed to the conception and design. Data acquisition and analysis were performed by Timothy Pham and Sonali Shambhu. Krishna Gunturu, Michael Fisch, John Barron, and David Debono interpreted the data. Krishna Gunturu wrote the first draft and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Ethics approval
This observational study, conducted under the Research Exception provisions of Privacy Rule 45 CFR 164.514(e), was exempt from Institutional Board Review because researchers accessed a limited dataset for analysis which was devoid of individual patient identifiers, and complied with all relevant provisions of the Health Insurance Portability and Accountability Act. Institutional review board exemption was not necessary because the study was an analysis of the managed care organization’s membership data for the purposes of health plan treatment, planning, and operations.
Consent to participate
Not applicable.
Consent for publication
Not applicable.
Conflict of interest
Timothy Pham, Sonali Shambhu, and John Barron were full-time employees of HealthCore, a subsidiary of Anthem at the time of writing. David Debono is a full-time employee of Anthem. Michael Fisch is a full-time employee of AIM Specialty Health, a subsidiary of Anthem. Krishna Gunturu has no relevant financial or non-financial interests to disclose.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Implications for practice
The present study sought to determine the healthcare utilization, costs, and irAEs of monotherapy and combination therapy ICI in the real-world setting. We found higher rates of irAEs, healthcare utilization, and costs with combination ICI compared to monotherapy. Immune-related AEs and related healthcare utilization such as emergency department visits and hospitalizations are increased with combination ICI and should be considered in the shared decision-making regarding cancer treatment. Results also provide useful estimates to help inform clinicians on the outcomes of combination therapy and for guideline development and application of relative clinical value frameworks in oncology.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Gunturu, K.S., Pham, T.T., Shambhu, S. et al. Immune checkpoint inhibitors: immune-related adverse events, healthcare utilization, and costs among commercial and Medicare Advantage patients. Support Care Cancer 30, 4019–4026 (2022). https://doi.org/10.1007/s00520-022-06826-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00520-022-06826-9