Background
Systemic therapy for metastatic non-small cell lung cancer (NSCLC) varies according to tumor histology and mutation status of patients. Epidermal growth factor receptor (EGFR) mutation-positive tumors are highly responsive to EGFR-tyrosine kinase inhibitor (TKI) therapy [
1‐
5]. EGFR-TKIs provide improved clinical benefits, quality of life, and are considered more tolerable than chemotherapy [
1‐
5]. Clinical guidelines recommend routine mutation testing and identification of EGFR mutations in all patients with NSCLC of non-squamous cell carcinoma (non-SCC) histology to identify who may benefit from approved EGFR-TKIs [
6‐
8]. However, most patients develop resistance to first- or second-generation EGFR-TKIs [
9], with T790M, a resistance mutation in the EGFR gene, observed in approximately 50% of these patients [
10,
11]. EGFR T790M results in reduced binding of first- or second-generation EGFR-TKIs, lessening EGFR-TKI-mediated inhibition and leading to disease progression [
12,
13]. Identification of T790M prompted development of different therapeutic strategies to overcome resistance to EGFR-TKIs.
Osimertinib, a third-generation irreversible EGFR-TKI, selectively inhibits both EGFR-TKI sensitizing mutations and T790M. In November 2015, osimertinib received accelerated approval by the US Food and Drug Administration (FDA) to treat patients with EGFR T790M positive NSCLC whose disease progresses on or after prior treatment with EGFR-TKIs [
14]. In April 2018, the FDA approved osimertinib as a first-line (1 L) treatment option for patients with EGFR exon 19 deletion (ex19del)/L858R-positive metastatic NSCLC [
15]. Furthermore, final overall survival results from the FLAURA study demonstrated significantly longer overall survival in those who received osimertinib versus comparator EGFR-TKI, with a 20% lower risk of death among patients with untreated advanced NSCLC with an EGFR-TKI sensitizing mutation [
16]. Therefore, improved understanding of how EGFR mutation testing and treatment patterns have evolved in real-world practice among patients with metastatic NSCLC treated with first- or second-generation EGFR-TKIs, since approval of osimertinib, is needed. Clinical guidelines recommend T790M testing for patients with resistance to first- or second-generation EGFR-TKIs, yet uptake of such testing in real-world practice is unknown [
17]. In this real-world study, we aimed to describe the utilization of EGFR mutation testing of patients on progression with first- or second-generation EGFR-TKIs, subsequent treatments received, and the proportion of T790M positive patients treated with osimertinib.
Methods
Data source
This study used data from January 1, 2011 to September 30, 2017 from the Flatiron Health database, which is derived from electronic health records (EHR) containing longitudinal, patient-level data from a demographically and geographically diverse, nationally representative population in the US [
18]. Additional data modules, including data on progression, site of metastases, and histology, were acquired for patients with metastatic NSCLC who received subsequent therapy after treatment with first- or second-generation EGFR-TKI to confirm disease progression. The data are de-identified, with provisions in place to prevent re-identification to protect patient confidentiality, in accordance with the 1996 Health Information Portability and Accountability Act.
Study design and study population
A retrospective longitudinal cohort study was conducted among adult patients with metastatic NSCLC treated with a first- or second-generation EGFR-TKI. To evaluate EGFR mutation testing and treatment patterns after first FDA approval of osimertinib (November 2015), patients were selected based on use of EGFR-TKI on or after November 1, 2015. Patients included had a diagnosis of lung cancer (International Classification of Diseases, 9th Revision, Clinical Modification diagnosis code: 162.x; International Classification of Diseases, 10th Revision, Clinical Modification diagnosis code: C34x, C39.9), at least two clinical visits on or after January 1, 2011, pathology consistent with NSCLC, and a diagnosis of stage IIIB–IV NSCLC or early-stage NSCLC and subsequent development of recurrent or progressive disease on or after January 1, 2011. Additionally, patients had to be aged 18 years or more at the time of their diagnosis, treated with a first- or second-generation EGFR-TKI (erlotinib, afatinib, or gefitinib) on or after November 1, 2015, have had at least one clinical visit within 3 months prior to EGFR-TKI initiation, and have initiated a first- or second-generation EGFR-TKI at least 6 months prior to end of data (September 30, 2017) to avoid right censoring. Patients with simultaneous use of multiple EGFR-TKI therapies were excluded. The index date was the date of initiation of EGFR-TKI treatment. The observation period extended from index date to study end date (date of death, end of clinical activity, or data cutoff).
Study measures
Demographic and clinical characteristic data collected included age at metastatic NSCLC diagnosis, sex, race, geographical region, physician practice type, insurance type, history of smoking, line of therapy for first- or second-generation EGFR-TKI, time from diagnosis (date of first recurrence or progressive disease after initial NSCLC diagnosis) to those who initiated EGFR-TKI in 1 L or second or later line (2 L+), and Eastern Cooperative Oncology Group (ECOG) performance status. Treatment patterns were assessed and included subsequent therapies following first- or second-generation EGFR-TKI. NSCLC therapies were classified according to chemotherapies, immunotherapies, and targeted therapies (Table
1). Specifically, subsequent therapy was defined as a change in treatment after receiving a first- or second-generation EGFR-TKI. Patients who received the same EGFR-TKI agent in their index and subsequent therapy were considered to have continued on their initial EGFR-TKI therapy as subsequent therapy. Patients could have been classified into multiple therapy groups if receiving combination therapy (Table
2). Data on rates and results of EGFR mutation testing were reported for two time periods: 1) from metastatic NSCLC diagnosis to index date, 2) from after index date to date of initiation of subsequent therapy. For patients with multiple EGFR mutation tests, the test closest to index date was chosen for the baseline period, and the test closest to initiation of subsequent therapy was chosen for the observation period. In the database, EGFR and T790M were tested and reported together. Different types of mutations were also reported (i.e. T790M, ex19del, L858R point mutation in exon 2, other mutation types) for patients who were tested for EGFR and had positive results.
Table 1Chemotherapies, immunotherapies, and targeted therapies for metastatic NSCLC
Traditional Chemotherapies |
Platinum monotherapy | Carboplatin, Cisplatin |
Platinum doublet therapy |
With cisplatin | Docetaxel, Etoposide, Gemcitabine, Irinotecan, Paclitaxel, Pemetrexed, Vinorelbine |
With carboplatin | Docetaxel, Gemcitabine, Paclitaxel, Pemetrexed, Vinorelbine |
Non-platinum based combination therapies | Gemcitabine/Docetaxel, Gemcitabine/Paclitaxel, Gemcitabine/Vinorelbine, Paclitaxel/Vinorelbine, Pemetrexed/Gemcitabine |
Maintenance therapy | Docetaxel, Gemcitabine, Pemetrexed |
Immunotherapies | Atezolizumab, Nivolumab, Pembrolizumab |
Targeted Therapies |
ALK inhibitors | Alectinib, Brigatinib, Ceritinib, Crizotinib |
Angiogenesis inhibitors | Bevacizumab, Ramucirumab |
BRAF inhibitor | Vemurafenib |
CDK4/6 inhibitor | Palbociclib |
EGFR monoclonal antibody inhibitor | Cetuximab, Necitumumab |
EGFR tyrosine kinase inhibitors | Afatinib, Erlotinib, Gefitinib, Osimertinib |
MEK inhibitor | Trametinib |
Other monoclonal antibody inhibitors | Ipilimumab, Trastuzumab |
Table 2Treatment combinations among patients with a subsequent line of therapy
Chemotherapy alone | 25 (15.6) | 29 (21.6) |
Immunotherapy alone | 22 (13.8) | 55 (41.0) |
Targeted therapies | | |
EGFR-TKI | | |
Alone | 93 (58.1) | 23 (17.2) |
Plus chemotherapy | 3 (1.9) | 3 (2.2) |
Plus immunotherapy | 3 (1.9) | 2 (1.5) |
Plus other targeted therapies | 2 (1.3) | 2 (1.5) |
Plus chemotherapy, other targeted therapies | 1 (0.6) | 3 (2.2) |
Other targeted therapies | | |
Alone | 4 (2.5) | 2 (1.5) |
Plus chemotherapy | 6 (3.8) | 14 (10.4) |
Clinical study druga | 1 (0.6) | 1 (0.7) |
Patients with subsequent therapy following EGFR-TKI treatment were identified, and additional data abstraction was conducted to identify disease progression. Clinician documentation in medical charts, radiographic assessment, and/or pathology reports from the progression module in the database were reviewed to confirm whether disease progression occurred after EGFR-TKI initiation. Death of patients was determined from EHR and two external sources, including Social Security Death Index, and a commercial death dataset which collects information from obituaries, funeral homes and other sources to provide date of death within a week of death [
19]. Patients without any clinical activity 3 months before data cutoff (i.e. July 1, 2017 to September 30, 2017) were considered lost to follow-up. Patients still treated with first EGFR-TKI therapy in the month prior to data cutoff were considered remaining on therapy. Patients not treated with first EGFR-TKI therapy in the month prior to data cutoff, but with evidence of clinical activity during the 3 months prior to data cutoff, were considered as having discontinued therapy.
Statistical analyses
Patient characteristics were described overall and separately for patients who received EGFR-TKI in the 1 L and 2 L+. Means (standard deviations) and medians were reported for continuous variables, and frequencies and proportions were reported for categorical variables. For patients who received EGFR-TKI in 1 L versus 2 L+, results were compared using Wilcoxon rank sum test for continuous variables and chi-squares tests for categorical variables. The frequency and proportion of patients with EGFR mutation testing and specific results of testing from metastatic NSCLC diagnosis to index date were reported for the overall study population. Results of EGFR mutation testing between index date and subsequent therapy were reported for those who received subsequent therapy. The frequency and proportion of patients treated with specific types of subsequent therapies were described. The frequency and proportion of patients tested for EGFR (including T790M), testing results, and specific subsequent therapies received, were reported.
Discussion
This study provided a novel opportunity to document treatment patterns, use of EGFR mutation testing, and how patients with metastatic NSCLC are managed in a real-world clinical setting based on data from EHR used by US-based cancer care providers. These data illuminated several notable gaps in care. Despite clinical treatment guidelines recommending routine EGFR testing for all patients with metastatic NSCLC of non-SCC histology [
6‐
8], here only 71% of newly diagnosed patients underwent EGFR testing prior to EGFR-TKI initiation. Consistent with this observation, another observational research study showed rates of documented EGFR testing rate to range between 41 and 97% in patients with newly-diagnosed metastatic NSCLC initiating systemic therapy (including EGFR-TKIs) [
20]. Furthermore, the 30% rate of EGFR testing before subsequent therapy is consistent with previous estimates (30–48%) [
21‐
23] and emphasizes that, during the study period, a substantial proportion of patients initiated a subsequent therapy without updated information on the molecular profile of the tumor.
In this study, 87% of patients were treated in the community setting. Community-based practices may not be implementing standard testing guidelines or may have barriers related to EGFR mutation testing. Prior research has highlighted logistical challenges for community-based oncologists regarding mutation testing, such as coordination of sample handling, long turnaround times, and test reimbursements, which may affect adherence to testing guidelines during the treatment process for patients with NSCLC [
24]. Lastly, other barriers in all settings include inability to wait for testing and delay start of treatment, tissue insufficiency, potential harm from repeat biopsies, poor patient health and inability to undergo testing [
24,
25]. Of note, 12.5% of included patients had SCC, and these patients are less likely to have undergone testing due to the low frequency of EGFR mutations and differences in clinical guidelines [
6‐
8].
Our study reported median time from metastatic NSCLC diagnosis to EGFR-TKI initiation in 1 L of 62 days. A recent scoping review reported mean/median time from NSCLC diagnosis to treatment ranging from 15 to 60 days in the US [
26]. There are limited studies evaluating time from metastatic NSCLC diagnosis to treatment; however, one study reported 29% of patients waited more than 90 days from initial presentation to clinician to treatment, of whom 49% were stage IIIA-IV [
27]. Prior studies have suggested challenges to achieving shorter time to treatment, including delayed return of results and lack of communication of positive findings to the clinician and/or patient, while some are administrative including changes in insurance for patients [
26,
27]. This underscores the need for broad-based education throughout the oncology community, plus further research to understand EGFR mutation testing uptake and barriers to accessing current state technologies.
Since 2013, clinical guidelines recommend repeat molecular testing upon progression on first- and second-generation EGFR-TKIs to detect mutations such as T790M [
7]. Prior to 2015, there were no standard therapeutic options for patients with metastatic NSCLC with acquired resistance to initial EGFR-TKI [
28]. Osimertinib has led to a paradigm shift in the management of patients with metastatic NSCLC who develop T790M and experience disease progression on first- or second-generation EGFR-TKIs. The need for tumor genotyping is thus highly supported at least at time of diagnosis and disease progression on or after first- or second-generation EGFR-TKIs for mutation evaluation. Nevertheless, only approximately 30% of patients in this study who received first- or second-generation EGFR-TKIs and progressed were tested for T790M prior to initiating subsequent therapy. The proportion of patients tested for EGFR mutations on progression prior to initiating subsequent therapy was lower in patients treated with an EGFR-TKI in 1 L versus 2 L+ (39% versus 19%). Among patients tested for T790M, 28% were positive and mostly received osimertinib. One rationale for the lower proportion of patients tested for EGFR mutations on progression may be that EGFR testing was not recommended prior to FDA approval of osimertinib [
6‐
8]; therefore, EGFR testing following progression was slowly being adopted during this study. In any case, 30% of patients who received first- or second-generation EGFR-TKI died before receiving any subsequent therapy and only 38% of patients treated with EGFR-TKI had subsequent therapy. Another recent study reported that 30% of patients with EGFR mutations were not treated with subsequent therapy due to fast disease progression and death [
29].
In previous studies among patients with NSCLC who progressed on 1 L EGFR-TKI therapy, approximately 50% were T790M positive [
10,
11]. Our study indicates a lower proportion of T790M positive patients (1 L = 37%, 2 L+ =8%). This lower rate is at least partially due to the fact that almost half of patients included in our study lacked evidence of EGFR-TKI sensitizing mutations at baseline. Lower rates of T790M detection may also be attributed to use of plasma/serum (blood) for EGFR testing, and sensitivities of laboratory techniques in the detection of the mutation [
30,
31]. Recent prospective studies showed higher T790M detection rates in tissue versus plasma samples [
30,
32]. In our study, either tissue (1 L = 57%; 2 L+ =38%) or blood (1 L = 48%; 2 L+ =44%) was used for EGFR testing upon progression. Depending on the laboratory technique used to detect T790M, sensitivities can range from as low as 29–82%, and specificities from 83 to 100% [
31]. Laboratory techniques with lower sensitivities may not accurately identify T790M. The database does not detail methods of detection (e.g. Cobas [Roche], ddPCR [Bio-Rad]) used to identify T790M; therefore, we cannot be certain that observed lower T790M detection rates are attributable to detection methods associated with low sensitivities.
In April 2018, osimertinib received approval as 1 L treatment in patients with EGFR ex19del/L858R-positive metastatic NSCLC [
33]. The approval was based on the FLAURA trial which demonstrated that, in previously-untreated EGFR mutation-positive NSCLC, median progression-free survival (osimertinib = 18.9 months, comparator = 10.2 months, hazard ratio = 0.46) and overall survival (osimertinib = 38.6 months, comparator = 31.8 months, hazard ratio = 0.80) were longer among patients receiving osimertinib compared with standard EGFR-TKIs [
4,
16]. More recently, a global multicenter retrospective (GioTag) study demonstrated a median time on chemotherapy-free treatment of 27.6 months among patients with metastatic NSCLC with EGFR- mutation (ex19del/L858R) who received 1 L afatinib followed by second-line osimertinib [
34]. Although there was clinical benefit in sequential treatment of afatinib followed by osimertinib, findings from the current study show that 30% of the patients who received first- or second-generation EGFR-TKI died before receiving any subsequent therapy, and only 30% were tested for T790M upon progression, resulting in a small number of patients (47 [16%]) actually receiving osimertinib as a subsequent therapy option. Consequently, many patients with metastatic NSCLC may not have survived long enough to be EGFR-tested and treated with osimertinib as subsequent therapy. The low rate of documented EGFR mutation positivity at baseline may have contributed to this high mortality rate, since EGFR-TKI therapy may have suboptimal efficacy in this setting. Given the results from FLAURA, considering 1 L treatment that could maximize clinical benefit for all eligible EGFR mutation-positive patients will be an important treatment decision for patients moving forward. Since there has been evolution in the treatment landscape of EGFR mutation-positive patients with approval of 1 L osimertinib, future research is needed to evaluate its impact on treatment patterns, outcomes in the real-world setting, and the molecular basis of acquired resistance to osimertinib.
This study has several strengths. First, with a nationally representative dataset including both structured and unstructured data processing, the database offers a unique opportunity to study disease progression among cancer patients. Second, the large patient population was drawn primarily from community-based practices (> 85%); results of this study are generalizable to US community-based oncology practices [
35]. Third, slightly more patients who were T790M negative received immunotherapy alone (1 L = 20%) vs chemotherapy alone (1 L = 18%) as subsequent therapy, despite clinical guidelines recommending chemotherapy in the second-line setting for T790M negative patients [
6]. These unique findings provide invaluable insight to real-world community practice patterns. Lastly, we evaluated testing and treatment patterns in the overall study sample, and further stratified patients who received EGFR-TKI in 1 L and 2 L+, enabling assessment of characteristics of testing and treatment patterns by line of therapy.
Some limitations of the study should be noted. First, data on some clinically important patient characteristics were not available in the database. For example, ECOG performance status was available for approximately 50% of patients, therefore description of patient characteristics is based on available data. Second, the indication for erlotinib changed in late 2016 for patients with NSCLC receiving maintenance or 2 L+ treatment, to limit use to those whose tumors have EGFR ex19del or L858R mutations [
36]. Therefore, some patients in the current study who were not EGFR mutation-positive may have received erlotinib as second-line or maintenance therapy. The subset of patients who received EGFR-TKI in 1 L may thus be more reflective of real-world mutation testing and treatment practices. Lastly, since data are drawn from community oncology centers, results may not be representative of practice at US academic medical centers.
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