This work is licensed under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
1. Introduction
Gastric cancer (GC) is the fifth most common cancer worldwide and the third leading cause of cancer-related mortality, with a 30% five-year survival rate for all stages [1, 2]. In addition, 25% of GC patients present with advanced disease, and another 25%–50% progress to metastatic disease [3]. The prognosis is especially poor for nonresponders to first-line (1L) chemotherapy, who face a challenging decision between supportive/palliative care and more aggressive intervention with taxanes, antiangiogenic therapy, or PD-1 blockade. Insurance claims data suggest that, as of 2012, a majority (54.5%) of GC patients who progress on 1L treatment go on to receive a second line of chemotherapy [4]. As novel therapies are incorporated into the second- and third-line (2L, 3L) treatment landscapes, further analysis is warranted to optimize quality-adjusted life years (QALYs) and determine the impact of personalized, biomarker-based treatment on the effectiveness and cost-effectiveness of treatment.
The 2018 National Comprehensive Cancer Network (NCCN) guidelines for treatment of chemorefractory, metastatic, or recurrent gastric cancer include the anti-PD-1 agent pembrolizumab (PEM), the VEGFR-2 antagonist ramucirumab (RAM), and a variety of taxanes, such as paclitaxel (PAC) monotherapy and its combination with RAM (RAM/PAC). Recommendations of RAM and PEM were primarily based on the outcomes of the RAINBOW and KEYNOTE-059 trials, respectively, and studies by Le et al. on deficient mismatch repair (dMMR) tumors (2015, 2017) [5–9]. The guidelines recommend PEM as 2L treatment for GC patients with high microsatellite instability (MSI-H) or deficient mismatch repair (dMMR) status and as 3L treatment for GC patients with positive PD-L1 expression using a 1% combined positive score (CPS) threshold [5].
The KEYNOTE-059 and KEYNOTE-061 trials showed promising results of durable response to PEM. Among PD-L1 + patients on PEM, median overall survival (OS) was 9.1 months and median duration of response was 15.7 months, with a range exceeding 23 months [10]. PAC monotherapy and RAM/PAC combination therapy showed similar OS rates, but much lower median durations of response (2.8 months and 4.4 months, respectively) [7]. This warrants further analysis to determine if durability of response makes PEM a cost-effective therapy.
Personalized or biomarker-based treatment may be crucial to the effectiveness and cost-effectiveness of the treatment landscape for advanced GC [11–13]. An estimated 14–24% of GC/GEJC patients express PD-L1 in tumor cells, and an estimated 35% in the tumor microenvironment [14]. The KEYNOTE-061 trial reported combined positive scores (CPS) for PD-L1 expression, which includes expression on both tumor and immune cells. Among patients treated with PEM, 66.2% (n = 196) of patients expressed PD-L1 at a 1% CPS threshold [10].
The Cancer Genome Atlas Research Network (TCGA) evaluated 295 primary gastric adenocarcinomas for molecular characteristics and found that 22% had high microsatellite instability (MSI-H) [15]. However, there is variability based on other published estimates. A recent review estimates that 10–39% of gastroesophageal cancers are MSI-H [14], but the proportion seems to be considerably smaller in stage IV tumors [6, 10, 16, 17]. A recent prospective genomic profiling study of metastatic esophagogastric patients reported that only 3% of patients were MSI-H (n = 318) [16].
MSI-H GC patients show significantly higher PD-L1 expression, compared to MSS GC patients (25.9% versus 8.4%,
Our analysis aimed to evaluate the impact of biomarker-based 2L GC treatment, compared to other commonly prescribed treatment regimens. In the biomarker-based strategies, patients with MSI-H/dMMR or PD-L1 positivity received PEM therapy, and the remaining patients received either PAC monotherapy or RAM/PAC combination therapy. We also evaluated best supportive care (BSC), PAC, PEM, and RAM/PAC for all GC patients on 2L treatment, regardless of biomarker status. The primary outcomes were QALYs as a measure of clinical effectiveness and incremental cost-effectiveness ratios (ICERs).
2. Methods
We utilized the CHEERS checklist for standardized methodology and reporting of cost-effectiveness analyses (Supplementary Table 2).
2.1. Patient Characteristics
Our model simulated a hypothetical cohort of patients, which was constructed using pooled patient characteristics from the KEYNOTE-059, KEYNOTE-061, REGARD, and RAINBOW trials (Supplementary Table 1) [6, 7, 10, 20]. The modeled cohort contained 60 year olds (70% male, 30% female) with unresectable recurrent/metastatic gastric adenocarcinomas undergoing second-line (2L) therapy. In accordance with the patient populations in the clinical trials, gastric adenocarcinomas include proximal, distal, and gastroesophageal junction (GEJ) cancers. The cohort entered the model following disease progression on a previous line of chemotherapy with a platinum and/or fluoropyrimidine, as well as trastuzumab in HER2 + patients. For the base case, we assumed that 40% of patients expressed PD-L1 at a CPS > 1% threshold and 10% of patients were MSI-H. These proportions were estimated based on proportions in the clinical trials and the literature [6, 10, 14–17, 21].
2.2. Treatment Model
A decision-analytic Markov model (Figure 1) was constructed in Python to analyze 2L treatments for GC patients. Patients could remain stable, experience disease progression, and die from cancer, severe adverse drug reactions, or age- and sex-specific all-cause mortality. Patients could present with treatment-related adverse events (trAEs) within the first 6 months of the model. After disease progression, patients were placed on best supportive care (BSC) as defined by the NCCN [5]. The model simulated a 60-month treatment and follow-up window, or 5-year time horizon, in monthly cycles. This time horizon was selected to capture the potential durable response to immunotherapy suggested in the literature [9, 16].
[figures omitted; refer to PDF]
We compared eight unique treatment strategies that are endorsed by current NCCN guidelines and also recently studied within clinical trials [5]. In the first four strategies, all patients received the same treatment, regardless of biomarker status. These strategies were (1) BSC with no active treatment, (2) PEM monotherapy (200 mg flat dose or 2 mg/kg every three weeks), (3) PAC monotherapy (80 mg/m2 three times per month), and (4) combination therapy with PAC (80 mg/m2 three times per month) and RAM (8 mg/kg; every two weeks). In the remaining four strategies, treatment was based on biomarker status: MSI/dMMR or PD-L1 CPS of 1%. Patients with a positive biomarker status received PEM, and the rest received either PAC monotherapy or RAM/PAC combination therapy.
Table 1
Summary of model inputs. Costs, probabilities, and utilities are per month unless otherwise specified.
| Parameter type | Parameter | Base case estimate |
| All treatment arms | ||
| Probabilities | Cancer-specific mortality on 3L best supportive care | 0.1476 [20] |
| trAE-related hospitalization | 0.0440 [4] | |
| Costs | Cost of GP follow-up | $179.39 [22] |
| Cost of oncology follow-up | $355.35 [22] | |
| Cost of radiology follow-up | $284.00 [22] | |
| One-time cost: PD-L1 testing (CPT 88342) | $118.51 [23] | |
| One-time cost: MSI-H testing (CPT 81301) | $348.56 [24] | |
| Utilities | 2L progression-free survival | 0.622 [25, 26] |
| 3L best supportive care | 0.362 [25, 26] | |
|
|
||
| Best supportive care | ||
| Probabilities | Disease progression | |
| Months 0–3 | 0.414 [20] | |
| Months 4–10 | 0.347 [20] | |
| Months 11+ | 0.251 [20] | |
| Cancer-specific mortality | 0.129 [20] | |
| Costs | Average cost of routine home care Medicare rate (2018) | $5169.60 [27, 28] |
|
|
||
| Pembrolizumab | ||
| Probabilities | Disease progression: biomarker agnostic | |
| Months 0–1 | 0.31 [10] | |
| Months 2–9 | 0.122 [10] | |
| Months 10+ | 0.014 [10] | |
| Cancer-specific mortality | 0.01857 [10] | |
| Disease progression: PDL1 + CPS > 1% | ||
| Months 0–3 | 0.2940 [10] | |
| Months 4–10 | 0.0998 [10] | |
| Months 11+ | 0.0127 [10] | |
| Cancer-specific mortality | 0.01179 [10] | |
| Disease progression: MSI-H | ||
| Months 0–3 | 0.0835 [10, 29] | |
| Months 4–10 | 0.0249 [10, 29] | |
| Months 11+ | 0.0134 [10, 29] | |
| Cancer-specific mortality | 0.0057 [10] | |
| Adverse events | ||
| Grade 1/2 | 0.1035 [6, 7, 10, 30, 31] | |
| Grade 3/4 | 0.0237 [6, 7, 10, 30, 31] | |
| Discontinuation | 0.0028 [6, 7, 10, 30, 31] | |
| Death | 0.00098 [6, 7, 10, 30, 31] | |
| Costs | Pembrolizumab | $12246.75 [32] |
| Drug administration | $470 [33] | |
| trAEs (grade 3/4) | $19487 [34, 35] | |
| Disutilities | trAEs (grade 1/2) | −0.086 [36] |
| trAEs (grade 3/4) | −0.165 [36] | |
|
|
||
| Paclitaxel | ||
| Probabilities | Disease progression | |
| Months 0–3 | 0.1870 [7] | |
| Months 4–10 | 0.1730 [7] | |
| Months 11+ | 0.1430 [7] | |
| Cancer-specific mortality | 0.028 [7] | |
| Adverse events | ||
| Grade 1/2 | 0.0864 [7, 10] | |
| Grade 3/4 | 0.0644 [7, 10] | |
| Discontinuation | 0.0085 [7, 10] | |
| Death | 0.0021 [7, 10] | |
| Costs | Paclitaxel | $66.53 [32] |
| Drug administration | $1412 [33] | |
| trAEs (grade 3/4) | $13198 [34, 35] | |
| Disutilities | trAEs (grade 1/2) | −0.071 [36–39] |
| trAEs (grade 3/4) | −0.180 [36–39] | |
| Ramucirumab + paclitaxel | ||
| Probabilities | Disease progression | |
| Months 0–1 | 0.1176 [7] | |
| Months 2–11 | 0.1843 [7] | |
| Months 12+ | 0.03297 [7] | |
| Cancer-specific mortality | 0.01235 [7] | |
| Adverse events | ||
| Grade 1/2 | 0.0306 [7] | |
| Grade 3/4 | 0.1773 [7] | |
| Discontinuation | 0.0210 [7] | |
| Death | 0.0034 [7] | |
| Costs | Ramucirumab + paclitaxel | $12974 [32] |
| Drug administration | $2118 [33] | |
| trAEs (grade 3/4) | $20658 [34, 35] | |
| Disutilities | trAEs (grade 1/2) | −0.110 [36] |
| trAEs (grade 3/4) | −0.250 [36] | |
2.3. 2L Cancer Progression and Mortality Estimates
Rates of disease progression and cancer mortality in each strategy were derived from the Kaplan–Meier (KM) estimates of overall survival (OS) and progression-free survival (PFS) of the respective clinical trials using piecewise linear fits to the curves (Table 1). Supplementary Figure 1 compares model outputs to clinical trial data. The PEM arms (including whole-population, MSI-H, and PD-L1 + subsets) were informed by data from the phase 3 open-label KEYNOTE-061 trial on pretreated gastric and GEJ adenocarcinomas [10]. PFS for the MSI-H subset was modeled using pooled data for all noncolorectal cancer sites [9]. Second-line treatment with PAC monotherapy and RAM/PAC was informed by data from the double-blind randomized phase 3 RAINBOW trial comparing the two treatments [7]. The BSC arm was informed by data from the placebo plus BSC group of the REGARD trial [20]. The same data were used to estimate the probability of cancer-specific mortality after disease progression and discontinuation of treatment in all strategies.
Age- and sex-specific all-cause mortality were estimated using 2014 US data from the Centers for Disease Control [40]. To be consistent with the patient population in the clinical trials, the probability of all-cause mortality was a weighted sum of male and female mortality data in a 70 : 30 ratio. When needed, the OS and PFS data were extrapolated beyond the time horizon of the clinical trials (∼24 months) by extending the KM curves and all-cause mortality rates.
2.4. Treatment-Related Adverse Events
The monthly probabilities of treatment-related adverse events (trAE) and related death or treatment discontinuation associated with each strategy were estimated as weighted averages from the safety data of the respective trials, namely, the KEYNOTE-012, KEYNOTE-059, KEYNOTE-061, and KEYNOTE-006 (melanoma) trials on PEM and the RAINBOW trial on RAM/PAC (Table 1) [6, 7, 10, 20, 30, 31]. These probabilities were multiplied by the proportion of patients receiving treatment in each cycle (i.e., patients with stable disease). Associated costs and disutilities were then applied based on the resulting percentages. We assumed that patients who discontinued treatment entered the progressive disease state. In addition, we assumed that trAEs occurred within the first six months of treatment based on estimates of the timing of trAEs in the literature [31, 41]. Late-onset trAEs were neglected due to insufficient data. We also assumed that the toxicity profile for PEM remained consistent across biomarker subgroups. Finally, we accounted for differences in hospitalization rates across treatment arms by modifying the percentage of the population experiencing a grade 3 or 4 trAE, and assuming that only this portion of the population would be eligible for inpatient admission.
2.5. Estimates of Costs and Quality of Life
Cost and quality of life model inputs are summarized in Table 1. We estimated costs of biomarker testing, drug acquisition and administration, and follow-up visits to general practitioners, oncologists, and radiologists from a US payer perspective. The costs of biomarker testing were estimated using the 2019 CMS Physician Fee Schedule and Clinical Diagnostic Laboratory Fee Schedule [23, 24]. Drug costs were estimated using the 2019 Medicare Average Sales Price Drug Pricing File, assuming an average patient weight of 65 kg and average body surface area of 1.85 m2 (weighted average for men and women in a 70 : 30 ratio to reflect clinical trial populations) [32, 42, 43]. Drug administration costs were derived from the literature and adjusted to reflect the number of infusions administered per month, multiple therapies, and associated costs of premedication [33].
The monetary costs associated with trAEs were assumed to be primarily those resulting from hospitalization costs. These were estimated as weighted averages of the costs associated with specific grades 3-4 trAEs and the frequency of occurrence of those events in the respective trials [22, 33, 34, 44, 45]. Hospitalization due to trAEs was assumed to occur for grades 3-4 only, at a rate that was estimated using insurance claims data [4]. Costs associated with trAEs managed in outpatient settings were assumed to be negligible. All costs were in US dollars (USD).
Quality-adjusted life years (QALYs) were derived by adjusting survival times by health state utility scores (0 = death, 1 = perfect health) as measures of quality of life (QoL). Utility scores associated with PFS and 3L BSC following progression were estimated from the literature and adjusted by the distributions of ECOG scores in clinical trials [25, 26]. Published estimates report utility score for a patient with an ECOG score of 1 is 0.1 less than the utility score of a patient with an ECOG score of 0. Reductions in QoL due to grades 1-2 and 3-4 trAEs were accounted for using disutility scores from a previous study on nivolumab for colorectal cancer [36]. As with costs, disutilities for trAEs were estimated as weighted averages for each treatment arm. All costs and utility scores were discounted by 3% annually [46].
2.6. Model Outcomes
The primary outcomes of the analysis were QALYs gained and ICERs, analyzed in the context of an efficiency frontier. ICERs were calculated as the ratio of differences in costs and QALYs between a strategy and the next best alternative. A willingness-to-pay (WTP) threshold of $100,000 per QALY gained was used in the base case as the cutoff for cost effectiveness [47]. Secondary outcomes were survival (unadjusted life expectancy) and total costs.
2.7. Sensitivity Analysis
We quantified uncertainty by measuring model output variation in response to changing input parameters via deterministic (one-way) and probabilistic sensitivity analyses (PSA). We focused on the ICER endpoint in these analyses in order to determine if cost-effectiveness results would change when changing input parameters. One-way sensitivity analyses were performed by varying one parameter at a time within prescribed bounds and recording the change in ICERs in a tornado diagram. In probabilistic sensitivity analyses, all parameters were sampled simultaneously from probability distributions in 10000 Monte Carlo samples per strategy, and the outcomes were recorded into cost-effectiveness planes. The ranges for the one-way sensitivity analyses and the distributions for the probabilistic sensitivity analyses are presented in Table 2, and detailed methods are given in the Supplementary Materials. Ranges for cancer mortality and cancer progression rates for MSI-H patients on PEM are depicted as ranges in KM curves in Supplementary Figure 3.
Table 2
Summary of parameters for sensitivity analyses.
| Parameter | Range (SD) | Distribution |
| Proportion MSI-H | 0.02–0.22 (0.05) | Beta |
| Probabilities | ||
| Probability of disease progression (MSI-H: PEM) | ±30% | Uniform |
| Probability of disease progression (all other strategies) | ±30% | Normal |
| Probability of cancer mortality on 3L best supportive care | ±30% | Normal |
| Costs (total) | ||
| Pembrolizumab | $10831–$15331 ($1354) | Gamma |
| Pembrolizumab trAEs (grade 3/4) | $14615–$24358 ($2436) | Gamma |
| Paclitaxel | $1843–$2343 ($230) | Gamma |
| Paclitaxel trAEs (grade 3/4) | $9898–$16497 ($1649) | Gamma |
| Ramucirumab + paclitaxel | $11996–$16996 ($1500) | Gamma |
| Ramucirumab + paclitaxel trAEs (grade 3/4) | $15493–$25822 ($2582) | Gamma |
| Best supportive care | $4136–$6136 ($311) | Gamma |
| Utilities/Disutilities | ||
| 2L progression-free survival | 0.55–0.69 | Uniform |
| 3L best supportive care following progression | 0.22–0.57 | Uniform |
| Pembrolizumab trAEs (grade 1/2) | 0.02–0.14 | Uniform |
| Pembrolizumab trAEs (grade 3/4) | 0.08–0.22 | Uniform |
| Paclitaxel trAEs (grade 1/2) | 0.05–0.13 | Uniform |
| Paclitaxel trAEs (grade 3/4) | 0.06–0.37 | Uniform |
| Ramucirumab + paclitaxel trAEs (grade 1/2) | 0.00–0.24 | Uniform |
| Ramucirumab + paclitaxel trAEs (grade 3/4) | 0.16–0.35 | Uniform |
Table 3
Summary of base case results.
| Treatment scenario | Cost (USD) | Unadjusted life years | QALY | ICER | |
| 1 | BSC, all | 29614 | 0.48 | 0.21 | –– |
| 2 | PAC, all | 40108 | 0.88 | 0.41 | 53705 |
| 4 | PEM all | 108408 | 0.98 | 0.47 | Dominated |
| 5 | PDL1 + (CPS > 1%): PEM PDL1-: PAC | 77359 | 0.98 | 0.47 | Dominated |
| 3 | RAM/PAC all | 128775 | 1.05 | 0.49 | Dominated |
| 6 | MSI-H: PEM MSS: PAC | 72442 | 1.05 | 0.51 | 325611 |
| 7 | PDL1 + (CPS > 1%): PEM PDL1-: RAM/PAC | 130560 | 1.09 | 0.52 | Weakly dominated |
| 8 | MSI-H: PEM MSS: RAM/PAC | 152242 | 1.2 | 0.58 | 1074620 |
3. Results
3.1. Base Case
The base case results for all strategies are presented in Table 3, Figures 2 and 3 (efficiency frontier). Overall survival and progression-free survival for strategies on the efficiency frontier are shown in Supplementary Figure 2. Biomarker-based strategies substantially increased quality-adjusted survival and unadjusted survival compared to BSC and PAC (Figure 2). All biomarker-based strategies produced similar QALY outputs, between 0.47 and 0.58 QALYs or a variation of only 1.32 months. The most effective strategy was PEM for MSI-H and RAM/PAC for MSS patients, with a total of 1.2 life years and 0.58 QALYs. This strategy increased unadjusted survival by 8.6 months compared to BSC and 3.8 months compared to PAC. In addition, QALYs increased by 4.4 months compared to BSC and 2.0 months compared to PAC.
[figure omitted; refer to PDF]
[figure omitted; refer to PDF]The effectiveness of biomarker-based strategies improved cost effectiveness, but the ICERs still surpassed the WTP threshold. PAC for all patients was the only cost-effective strategy, with an ICER of $53705/QALY. PEM for MSI-H patients and PAC for MSS patients resulted in an ICER of $325611/QALY, and PEM for MSI-H patients and RAM/PAC for MSS patients resulted in an ICER of $1074620/QALY.
3.2. Sensitivity Analyses
Deterministic and probabilistic sensitivity analyses indicated that our base case results were robust to uncertainty in model parameters. The tornado diagram in Figure 4 illustrates the results of a one-way sensitivity analysis for the biomarker-based strategy with the lowest ICER: PEM for MSI-H patients and PAC for MSS patients. The cost of PEM had the greatest effect on model outcomes. However, MSI-H: PEM/MSS: PAC was not cost-effective for any costs tested in the sensitivity analyses. Supplementary Figure 6 illustrates the results of the probabilistic sensitivity analysis for two main strategies on the efficiency frontier: (1) PAC versus BSC and (2) MSI-H: PEM/MSS: PAC versus PAC for all patients. In 96% of iterations, PAC remained a cost-effective strategy. In 87% of iterations, MSI-H: PEM/MSS: PAC was not cost-effective.
[figure omitted; refer to PDF]
Total costs and total QALYs increased with MSI-H prevalence, resulting in total costs between $47000 and $111000, and total QALYs between 0.43 and 0.63 (Supplementary Figure 4). However, the ICERs remained quite stable since biomarker prevalence drove both costs and QALYs.
4. Discussion
Our analysis used a decision-analytic framework to analyze the impact of personalized, biomarker-based regimens for second-line treatment of metastatic gastric cancer. The most effective treatment regimens were biomarker-based, with PEM for MSI-H patients and RAM/PAC for MSS patients resulting in the most QALYs. Our study highlights the benefit of the broader ongoing shift toward personalized, biomarker-based cancer treatment in patients who would have been offered supportive/palliative care in the past. Historically, only about 20% of GC patients went on to 2L therapy, but, with increasing efficacy in the 2L setting, that number has increased to over 50% [4, 48].
Perhaps reflecting the diversity of current treatment, the NCCN recommendations for this patient population encompass a broad range of approaches, including basic supportive care. Although our modeling analysis finds substantial benefit for targeted treatment compared to supportive care or conventional chemotherapy (paclitaxel), these newer strategies are expensive and not cost-effective. Improving the precision of predictive biomarkers of response and reducing the cost of immunotherapeutic and biologic agents could continue to improve the cost effectiveness of targeted therapies.
Our analysis provides important data for decision-making, as clinical trials directly comparing such a large number of potential treatment strategies are not feasible. As a model-based analysis, we were able to incorporate quality of life and cost considerations to estimate outcomes that are of interest to various stakeholders. We also developed our model utilizing the most current data available and provided extensive details regarding our approach and assumptions to provide transparency and diminish concerns about unknown biases in the model (see additional details in Supplementary Materials). Finally, we performed extensive sensitivity analyses to explore the impact of uncertainty in model parameters on analysis results.
We identified several limitations in the current study. In the absence of long-term follow-up data, we extended the Kaplan–Meier estimators of overall and progression-free survival beyond the endpoints of the associated clinical trials. In addition, we used data for all patients to inform the survival outcomes for MSS/PD-L1 patients receiving PAC or RAM/PAC. Because our model inputs were derived from clinical trial data collected from patients with high-performance status, the generalizability of results to those with limited performance may be limited. Nonetheless, patient characteristics across clinical trials were comparable (see Supplementary Materials). Finally, late-onset severe adverse events associated with targeted therapies and immunotherapies were not included in the model due to insufficient data.
Our analysis was based on currently available biomarkers and treatments. Biomarker discovery is an active area of investigation and future biomarkers that improve the precision of treatment selection could improve both the effectiveness and cost-effectiveness of novel strategies. Although the biomarker-based approach we assessed in our current analysis did not meet the willingness-to-pay threshold for cost effectiveness, the ability to further define the optimal treatment group might continue to reduce the ICER to a point where these therapies achieve cost effectiveness.
Primary drivers of the cost-effectiveness results were the current costs of newer therapeutic agents. The most effective strategies were expensive, rendering those strategies cost-ineffective. A threshold analysis indicated that the cost of PEM would have to be approximately $3200 per month in order for the MSI-H: PEM/MSS: PAC strategy to be cost-effective (Supplementary Figure 5). The cost of cancer is a serious matter, especially as more effective and more costly treatments enter the market. Emerging research has found high (28%–48%) rates of treatment-related financial toxicity in cancer patients, with negative consequences for patient-reported outcomes and treatment adherence [49]. A combination of improving precision medicine and lowering drug prices could achieve cost effectiveness and improve patient outcomes. Future clinical data will allow for improved model inputs and fewer assumptions than those made for the current analysis.
In conclusion, our modeling analysis finds that personalized, biomarker-based treatments improve both quality-adjusted and quality-unadjusted survival but are not cost-effective, largely because of the prices of therapeutic agents.
[1] J. Ferlay, I. Soerjomataram, R. Dikshit, "Cancer incidence and mortality worldwide: sources, methods and major patterns in GLOBOCAN 2012," International Journal of Cancer, vol. 136 no. 5, pp. E359-E386, DOI: 10.1002/ijc.29210, 2015.
[2] R. L. Siegel, K. D. Miller, A. Jemal, "Cancer statistics, 2016," CA: A Cancer Journal for Clinicians, vol. 66 no. 1,DOI: 10.3322/caac.21332, 2016.
[3] L. Procaccio, M. Schirripa, M. Fassan, "Immunotherapy in gastrointestinal cancers," BioMed Research International, vol. 2017,DOI: 10.1155/2017/4346576, 2017.
[4] L. M. Hess, D. Michael, D. S. Mytelka, J. Beyrer, A. M. Liepa, S. Nicol, "Chemotherapy treatment patterns, costs, and outcomes of patients with gastric cancer in the United States: a retrospective analysis of electronic medical record (EMR) and administrative claims data," Gastric Cancer, vol. 19 no. 2, pp. 607-615, DOI: 10.1007/s10120-015-0486-z, 2016.
[5] National Comprehensive Cancer Network, "NCCN clinical practice guidelines in oncology: gastric cancer (version 2)," 2018. https://www.nccn.org/professionals/physician_gls/pdf/gastric.pdf
[6] C. S. Fuchs, T. Doi, R. W.-J. Jang, "KEYNOTE-059 cohort 1: efficacy and safety of pembrolizumab (pembro) monotherapy in patients with previously treated advanced gastric cancer," Journal of Clinical Oncology, vol. 35 no. 15,DOI: 10.1200/jco.2017.35.15_suppl.4003, 2017.
[7] H. Wilke, K. Muro, E. Van Cutsem, "Ramucirumab plus paclitaxel versus placebo plus paclitaxel in patients with previously treated advanced gastric or gastro-oesophageal junction adenocarcinoma (RAINBOW): a double-blind, randomised phase 3 trial," The Lancet Oncology, vol. 15 no. 11, pp. 1224-1235, DOI: 10.1016/s1470-2045(14)70420-6, 2014.
[8] D. T. Le, J. N. Uram, H. Wang, "PD-1 blockade in tumors with mismatch-repair deficiency," The New England Journal of Medicine, vol. 372, pp. 2509-2520, DOI: 10.1056/NEJMoa1500596, 2015.
[9] D. T. Le, J. N. Durham, K. N. Smith, "Mismatch repair deficiency predicts response of solid tumors to PD-1 blockade," Science, vol. 357 no. 6349, pp. 409-413, 2017.
[10] K. Shitara, M. Özgüroğlu, Y.-J. Bang, "Pembrolizumab versus paclitaxel for previously treated, advanced gastric or gastro-oesophageal junction cancer (KEYNOTE-061): a randomised, open-label, controlled, phase 3 trial," The Lancet, vol. 392 no. 10142, pp. 123-133, 2018.
[11] F. Lordick, E. C. Smyth, "Two steps forward and one step back," Nature Reviews Clinical Oncology, vol. 16 no. 2, pp. 69-70, DOI: 10.1038/s41571-018-0154-4, 2019.
[12] E. C. Smyth, A. Cervantes, "Immunotherapy is not for all comers in chemotherapy-refractory advanced gastric cancer. better predictive biomarkers are needed," Annals of Oncology, vol. 29 no. 10, pp. 2027-2028, DOI: 10.1093/annonc/mdy331, 2018.
[13] E. C. Smyth, R. D. Petty, "Pembrolizumab versus paclitaxel in gastro-oesophageal adenocarcinoma," The Lancet, vol. 392 no. 10142, pp. 97-98, DOI: 10.1016/s0140-6736(18)31277-7, 2018.
[14] Z. Jin, H. H. Yoon, "The promise of PD-1 inhibitors in gastro-esophageal cancers: microsatellite instability vs. PD-L1," Journal of Gastrointestinal Oncology, vol. 7 no. 5, pp. 771-788, DOI: 10.21037/jgo.2016.08.06, 2016.
[15] The Cancer Genome Atlas Research Network, "Comprehensive molecular characterization of gastric adenocarcinoma," Nature, vol. 513, 2014.
[16] Y. Y. Janjigian, F. Sanchez-Vega, P. Jonsson, "Genetic predictors of response to systemic therapy in esophagogastric cancer," Cancer Discovery, vol. 8 no. 8, pp. 49-58, DOI: 10.1158/2159-8290.CD-17-0787, 2018.
[17] H. Kim, J. Y. An, S. H. Noh, S. K. Shin, Y. C. Lee, H. Kim, "High microsatellite instability predicts good prognosis in intestinal-type gastric cancers," Journal of Gastroenterology and Hepatology, vol. 26 no. 3, pp. 585-592, DOI: 10.1111/j.1440-1746.2010.06487.x, 2011.
[18] M. E. Salem, A. Puccini, A. Grothey, "Landscape of tumor mutation load, mismatch repair deficiency, and PD-L1 expression in a large patient cohort of gastrointestinal cancers," Molecular Cancer Research, vol. 16 no. 5, pp. 805-812, DOI: 10.1158/1541-7786.mcr-17-0735, 2018.
[19] M. Ratti, A. Lampis, J. C. Hahne, R. Passalacqua, N. Valeri, "Microsatellite instability in gastric cancer: molecular bases, clinical perspectives, and new treatment approaches," Cellular and Molecular Life Sciences, vol. 75 no. 22, pp. 4151-4162, DOI: 10.1007/s00018-018-2906-9, 2018.
[20] C. S. Fuchs, J. Tomasek, C. J. Yong, "Ramucirumab monotherapy for previously treated advanced gastric or gastro-oesophageal junction adenocarcinoma (REGARD): an international, randomised, multicentre, placebo-controlled, phase 3 trial," The Lancet, vol. 383 no. 9911, pp. 31-39, DOI: 10.1016/s0140-6736(13)61719-5, 2014.
[21] C. Böger, H.-M. Behrens, M. Mathiak, S. Krüger, H. Kalthoff, C. Röcken, "PD-L1 is an independent prognostic predictor in gastric cancer of Western patients," Oncotarget, vol. 7 no. 17, pp. 24269-24283, DOI: 10.18632/oncotarget.8169, 2016.
[22] A. Haiderali, L. Menditto, M. Good, A. Teitelbaum, J. Wegner, "Impact on daily functioning and indirect/direct costs associated with chemotherapy-induced nausea and vomiting (CINV) in a US population," Supportive Care in Cancer, vol. 19 no. 6, pp. 843-851, DOI: 10.1007/s00520-010-0915-9, 2011.
[23] Centers for Medicare & Medicaid Services, Physician Fee Schedule Search, 2019.
[24] Centers for Medicare & Medicaid Services, Clinical Diagnostic Laboratory Fee Schedule, 2019.
[25] A. S. Pickard, M. P. Neary, D. Cella, "Estimation of minimally important differences in EQ-5D utility and VAS scores in cancer," Health and Quality of Life Outcomes, vol. 5 no. 1,DOI: 10.1186/1477-7525-5-70, 2007.
[26] S. W. Lam, M. Wai, J. E. Lau, M. McNamara, M. Earl, B. Udeh, "Cost-effectiveness analysis of second-line chemotherapy agents for advanced gastric cancer," Pharmacotherapy: The Journal of Human Pharmacology and Drug Therapy, vol. 37 no. 1, pp. 94-103, DOI: 10.1002/phar.1870, 2017.
[27] Centers for Medicare & Medicaid Services, Annual Change in Medicaid Hospice Payment Rates, 2018. https://www.medicaid.gov/medicaid/benefits/downloads/medicaid-hospice-rates-ffy-2018.pdf
[28] Centers for Medicare & Medicaid Services, Medicare Claims Processing Manual, Chapter 11, 2017.
[29] D. T. Le, J. N. Durham, K. N. Smith, "Mismatch repair deficiency predicts response of solid tumors to PD-1 blockade," Science, vol. 357 no. 357, pp. 409-413, DOI: 10.1126/science.aan6733, 2017.
[30] K. Muro, H. C. Chung, V. Shankaran, "Pembrolizumab for patients with PD-L1-positive advanced gastric cancer (KEYNOTE-012): a multicentre, open-label, phase 1b trial," The Lancet Oncology, vol. 17 no. 6, pp. 717-726, DOI: 10.1016/s1470-2045(16)00175-3, 2016.
[31] C. Robert, J. Schachter, G. V. Long, "Pembrolizumab versus ipilimumab in advanced melanoma," New England Journal of Medicine, vol. 372 no. 26, pp. 2521-2532, DOI: 10.1056/nejmoa1503093, 2015.
[32] Centers for Medicare & Medicaid Services, ASP Drug Pricing Files, 2019. https://www.cms.gov/Medicare/Medicare-Fee-for-Service-Part-B-Drugs/McrPartBDrugAvgSalesPrice/2019ASPFiles.html
[33] G. B. Kruse, M. M. Amonkar, G. Smith, D. C. Skonieczny, S. Stavrakas, "Analysis of costs associated with administration of intravenous single-drug therapies in metastatic breast cancer in a U.S. population," Journal of Managed Care Pharmacy, vol. 14 no. 9, pp. 844-857, DOI: 10.18553/jmcp.2008.14.9.844, 2008.
[34] C. Copley-Merriman, K. Stevinson, F. X. Liu, "Direct costs associated with adverse events of systemic therapies for advanced melanoma," Medicine, vol. 97 no. 31,DOI: 10.1097/md.0000000000011736, 2018.
[35] D. A. Goldstein, K. Krishna, C. R. Flowers, "Cost description of chemotherapy regimens for the treatment of metastatic pancreas cancer," Medical Oncology, vol. 33 no. 5,DOI: 10.1007/s12032-016-0762-8, 2016.
[36] J. N. Chu, J. Choi, S. Ostvar, "Chin cost-effectiveness of immune checkpoint inhibitors for microsatellite instability-high/mismatch repair-deficient metastatic colorectal cancer," Cancer, vol. 125 no. 2, pp. 278-289, 2018.
[37] B. Nafees, A. J. Lloyd, S. Dewilde, N. Rajan, M. Lorenzo, "Health state utilities in non-small cell lung cancer: an international study," Asia-Pacific Journal of Clinical Oncology, vol. 13 no. 5, pp. e195-e203, DOI: 10.1111/ajco.12477, 2017.
[38] F. H. Shabaruddin, L.-C. Chen, R. A. Elliott, K. Payne, "A systematic review of utility values for chemotherapy-related adverse events," PharmacoEconomics, vol. 31 no. 4, pp. 277-288, DOI: 10.1007/s40273-013-0033-x, 2013.
[39] E. M. Stein, M. Yang, A. Guerin, "Assessing utility values for treatment-related health states of acute myeloid leukemia in the United States," Health and Quality of Life Outcomes, vol. 16 no. 1,DOI: 10.1186/s12955-018-1013-9, 2018.
[40] E. Arias, M. Heron, J. Xu, "National vital statistics reports: United States life tables," 2014. https://www.cdc.gov/nchs/data/nvsr/nvsr66/nvsr66_04.pdf
[41] M. A. Postow, R. Sidlow, M. D. Hellmann, "Immune-related adverse events associated with immune checkpoint blockade," New England Journal of Medicine, vol. 378 no. 2, pp. 158-168, DOI: 10.1056/nejmra1703481, 2018.
[42] J. J. Sacco, J. Botten, F. Macbeth, A. Bagust, P. Clark, "The average body surface area of adult cancer patients in the UK: a multicentre retrospective study," PLoS One, vol. 5 no. 1,DOI: 10.1371/journal.pone.0008933, 2010.
[43] K. Sánchez-Lara, E. Ugalde-Morales, D. Motola-Kuba, D. Green, "Gastrointestinal symptoms and weight loss in cancer patients receiving chemotherapy," British Journal of Nutrition, vol. 109 no. 5, pp. 894-897, DOI: 10.1017/s0007114512002073, 2013.
[44] Centers for Medicare & Medicaid Services, Medicare Claims Processing Manual, 2017.
[45] D. A. Goldstein, K. Krishna, C. Flowers, B. F. El-Rayes, T. S. Bekaii-Saab, A. M. Noonan, "Cost description of chemotherapy regimens for the treatment of metastatic pancreas cancer (mPC)," Journal of Clinical Oncology, vol. 33 no. 3,DOI: 10.1200/jco.2015.33.3_suppl.368, 2015.
[46] M. F. Drummond, M. J. Sculpher, K. Claxton, Methods for the Economic Evaluation of Health Care Programmes, 2015.
[47] P. J. Neumann, J. T. Cohen, M. C. Weinstein, "Updating cost-effectiveness-the curious resilience of the $50,000-per-QALY threshold," New England Journal of Medicine, vol. 371 no. 9, pp. 796-797, DOI: 10.1056/nejmp1405158, 2014.
[48] M. Salati, K. Di Emidio, V. Tarantino, S. Cascinu, "Second-line treatments: moving towards an opportunity to improve survival in advanced gastric cancer?," ESMO Open, vol. 2 no. 3,DOI: 10.1136/esmoopen-2017-000206, 2017.
[49] L. G. Gordon, K. M. D. Merollini, A. Lowe, R. J. Chan, "A systematic review of financial toxicity among cancer survivors: we can’t pay the co-pay," The Patient-Patient-Centered Outcomes Research, vol. 10 no. 3, pp. 295-309, DOI: 10.1007/s40271-016-0204-x, 2017.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Copyright © 2020 Brianna Lauren et al. This work is licensed under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Abstract
Background. The 5-year survival rate of patients with metastatic gastric cancer (GC) is only 5%. However, trials have demonstrated promising antitumor activity for targeted therapies/immunotherapies among chemorefractory metastatic GC patients. Pembrolizumab has shown particular efficacy among patients with programmed death ligand-1 (PD-L1) expression and high microsatellite instability (MSI-H). The aim of this study was to assess the effectiveness and cost-effectiveness of biomarker-guided second-line GC treatment. Methods. We constructed a Markov decision-analytic model using clinical trial data. Our model compared pembrolizumab monotherapy and ramucirumab/paclitaxel combination therapy for all patients and pembrolizumab for patients based on MSI status or PD-L1 expression. Paclitaxel monotherapy and best supportive care for all patients were additional comparators. Costs of drugs, treatment administration, follow-up, and management of adverse events were estimated from a US payer perspective. The primary outcomes were quality-adjusted life years (QALYs) and incremental cost-effectiveness ratios (ICERs) with a willingness-to-pay threshold of $100,000/QALY over 60 months. Secondary outcomes were unadjusted life years (survival) and costs. Deterministic and probabilistic sensitivity analyses were performed to evaluate model uncertainty. Results. The most effective strategy was pembrolizumab for MSI-H patients and ramucirumab/paclitaxel for all other patients, adding 3.8 months or 2.0 quality-adjusted months compared to paclitaxel. However, this strategy resulted in a prohibitively high ICER of $1,074,620/QALY. The only cost-effective strategy was paclitaxel monotherapy for all patients, with an ICER of $53,705/QALY. Conclusion. Biomarker-based treatments with targeted therapies/immunotherapies for second-line metastatic GC patients substantially improve unadjusted and quality-adjusted survival but are not cost-effective at current drug prices.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
; Ostvar, Sassan 1
; Silver, Elisabeth 1 ; Ingram, Myles 1 ; Oh, Aaron 1 ; Kumble, Lindsay 1 ; Laszkowska, Monika 1 ; Chu, Jacqueline N 2 ; Hershman, Dawn L 3 ; Manji, Gulam 3 ; Neugut, Alfred I 4 ; Hur, Chin 3
1 Columbia University Medical Center, New York, NY, USA
2 Massachusetts General Hospital, Boston, MA, USA
3 Columbia University Medical Center, New York, NY, USA; Columbia University Irving Cancer Research Center, New York, NY, USA
4 Columbia University Irving Cancer Research Center, New York, NY, USA