Economic Value of Anti–Vascular Endothelial Growth Factor Treatment for Patients With Wet Age-Related Macular Degeneration in the United States

Karen Mulligan; Seth A Seabury; Pravin U Dugel; Jill F Blim; Dana P Goldman; Mark S Humayun

doi:10.1001/jamaophthalmol.2019.4557

. 2019 Nov 14;138(1):40–47. doi: 10.1001/jamaophthalmol.2019.4557

Economic Value of Anti–Vascular Endothelial Growth Factor Treatment for Patients With Wet Age-Related Macular Degeneration in the United States

Karen Mulligan ^1,^6,^✉, Seth A Seabury ^2,⁶, Pravin U Dugel ^3,⁴, Jill F Blim ⁵, Dana P Goldman ^1,^2,⁶, Mark S Humayun ^4,⁷

¹Sol Price School of Public Policy, University of Southern California, Los Angeles

²School of Pharmacy, University of Southern California, Los Angeles

³Retinal Research Institute, LLC, Phoenix, Arizona

⁴Roski Eye Institute, University of Southern California, Los Angeles

⁵American Society of Retina Specialists, Chicago, Illinois

⁶Leonard D. Schaeffer Center for Health Policy & Economics, University of Southern California, Los Angeles

⁷Ginsburg Institute for Biomedical Therapeutics, University of Southern California, Los Angeles

Accepted for Publication: September 16, 2019.

Published Online: November 14, 2019. doi:10.1001/jamaophthalmol.2019.4557

Correction: This article was corrected on December 19, 2019, to fix Dr Goldman’s affiliations.

^✉

Corresponding Author: Karen Mulligan, PhD, Sol Price School of Public Policy, Leonard D. Schaeffer Center for Health Policy & Economics, University of Southern California, 635 Downey Way, Verna & Peter Dauterive Hall, Los Angeles, CA 90089 (karenmul@usc.edu).

Author Contributions: Drs Mulligan and Seabury had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

Concept and design: All authors.

Acquisition, analysis, or interpretation of data: Mulligan, Seabury, Dugel, Blim, Goldman.

Drafting of the manuscript: Mulligan, Seabury, Dugel.

Critical revision of the manuscript for important intellectual content: All authors.

Statistical analysis: Mulligan, Seabury, Dugel.

Obtained funding: Seabury, Goldman.

Administrative, technical, or material support: Seabury, Dugel, Blim, Humayun.

Supervision: Seabury, Dugel, Goldman.

Conflict of Interest Disclosures: Drs Mulligan and Seabury reported receiving unrestricted gifts from the American Society of Retina Specialists (ASRS) during the conduct of the study and receiving personal fees from Precision Health Economics outside the submitted work. Dr Dugel reported receiving personal fees from Alcon, Novartis, Genentech, Roche, Bausch, Allergan, Regenxbio, Oxurion, Clearside Biomedical, Aerpio, Opthea, Spark, Graybug Vision, Zeiss Group, Beyeonics, PanOptica, Chengdu Kanghong Biotech, SciFluor, Boehringer Ingelheim, Kodiak, Oculis SA, Eyepoint, Aerie, Pieris, Gemini, Ionis, Reneuron, Merck, Daiichi Sankyo, AsclepiX, Fox Kiser, Arctic Vision, Nan Fung Group, and Allegro outside the submitted work; and serving on scientific advisory boards for Allergan, Genentech, Roche, Regeneron, Novartis, and Oxurion. Dr Goldman reported receiving an unrestricted gift from the ASRS and other funds from the University of Southern California (Leonard D. Schaeffer Center for Health Policy & Economics) during the conduct of the study; receiving personal fees and consulting fees from Precision Health Economics LLC outside the submitted work; owning (<1%) in the parent company, Precision for Medicine; receiving speaker fees or honoraria unrelated to this work from Allergan, Amgen, Avanir, Cedars-Sinai Medical Center, Celgene, Claremont College, Columbia University, FAIR Health, LA Biomed, Novartis, Novo Nordisk, Stanford University, University of Arizona, University of California, University of Chicago, and Western University College of Pharmacy; serving as a paid scientific advisor to the Aspen Institute, Congressional Budget Office, Fred Hutchinson Cancer Institute, and ACADIA Pharmaceuticals; and serving as the Director of the Leonard D. Schaeffer Center for Health Policy & Economics, which is supported by grants and gifts from individuals, corporations, and associations; by government grants and contracts; and by private foundations (see https://healthpolicy.usc.edu for specific information related to funding sources). Dr Humayun reported receiving consulting fees and honorarium from Allergan outside the submitted work; receiving consulting fees from and holding equity in MTTR outside the submitted work; receiving consulting fees from Outlook Therapeutics outside the submitted work; receiving consulting fees, patents, and royalties, and being an equity owner for Replenish outside the submitted work; and serving as the co-director of the USC Roski Eye Institute, which receives restricted support from Research to Prevent Blindness.

Funding/Support: Partial funding for this project was provided by an unrestricted gift from the American Society of Retina Specialists (ASRS) to the authors affiliated with the USC Schaeffer Center (Drs Mulligan, Seabury, and Goldman).

Role of the Funder/Sponsor: Drs Dugel and Humayun serve as leadership for ASRS, and Ms Blim is an employee of ASRS. Other than as indicated, ASRS had no role in the design and conduct of the study; collection, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and the decision to submit the manuscript for publication.

Disclaimer: This study was conceived by the authors and not supported by any particular donor, and the authors are solely responsible for the design and analysis of this study and its findings.

Additional Contributions: Sarah Brandon, BA, and Rocio Ribero, PhD, provided valuable research support, and Karen Van Nuys, PhD, provided feedback.

^✉

Corresponding author.

PMCID: PMC6865322 PMID: 31725830

This economic evaluation study estimates the value generated by anti–vascular endothelial growth factor treatment for patients with wet age-related macular degeneration and society in the United States.

Key Points

Question

How much economic value do anti–vascular endothelial growth factor (anti-VEGF) treatments generate for patients with wet age-related macular degeneration and society in the United States?

Findings

In this economic evaluation study, visual acuity improvement associated with anti-VEGF treatments generated $5.1 billion to $8.2 billion in patient benefits and $0.9 billion to $3.0 billion in societal value (patient benefits net of treatment costs) across 3 years. Treatment innovations associated with improved adherence generated an additional $7.3 billion to $15.0 billion in patient benefits and $0.9 million to $4.3 billion in societal value compared with current treatment scenarios.

Meaning

This study’s findings suggest that improved visual acuity associated with anti-VEGF treatment may provide economic value, and future innovations may result in added economic benefit.

Abstract

Importance

Anti–vascular endothelial growth factor (anti-VEGF) is a breakthrough treatment for wet age-related macular degeneration (wAMD), the most common cause of blindness in western countries. Anti-VEGF treatment prevents vision loss and has been shown to produce vision gains lasting as long as 5 years. Although this treatment is costly, the benefits associated with vision gains are large.

Objective

To estimate the economic value of benefits, costs for patients with wAMD, and societal value in the United States generated from vision improvement associated with anti-VEGF treatment.

Design, Setting, and Participants

This economic evaluation study used data from the published literature to simulate vision outcomes for a cohort of 168 820 patients with wAMD aged 65 years or older and to translate them into economic variables. Data were collected and analyzed from March 2018 to November 2018.

Main Outcomes and Measures

Main outcomes included patient benefits, costs, and societal value. Each outcome was estimated for a newly diagnosed cohort and the full population across 5 years, with a focus on year 3 as the primary outcome because data beyond that point may be less representative of the general population. Drug costs were the weighted mean across anti-VEGF therapies. Two current treatment scenarios were considered: less frequent injections (mean [SD], 8.2 [1.6] injections annually) and more frequent injections (mean [range], 10.5 [6.8-13.1] injections annually). The 2 treatment innovation scenarios, improved adherence and best case, had the same vision outcomes as the current treatment scenarios had but included more patients treated from higher initiation and lower discontinuation.

Results

The study population included 168 820 patients aged 65 years at the time of diagnosis with wAMD. The underlying clinical trials that were used to parameterize the model did not stratify visual acuity outcomes or treatment frequency by sex; therefore, the model parameters could not be stratified by sex. The current treatment scenario of less frequent injections generated $1.1 billion for the full population in year 1 and $5.1 billion in year 3, whereas the scenario of more frequent injections generated $1.6 billion (year 1) and $8.2 billion (year 3). Three-year benefits ranged from $7.3 billion to $11.4 billion in the improved adherence scenario and from $9.7 billion to $15.0 billion if 100% of the patients initiated anti-VEGF treatment and the discontinuation rates were 6% per year or equivalent to clinical trial discontinuation (best-case scenario). Societal value (patient benefits net of treatment cost) ranged from $0.9 billion to $3.0 billion across 3 years in the current treatment scenarios and from $0.9 billion to $4.3 billion in the treatment innovation scenarios.

Conclusions and Relevance

This study’s findings suggest that improved vision associated with anti-VEGF treatment may provide economic value to patients and society if the outcomes match published outcomes data used in these analyses; however, future innovations that increase treatment utilization may result in added economic benefit.

Introduction

Age-related macular degeneration (AMD) is an eye condition that affects approximately 11 million individuals in the United States.¹ It results in vision loss and could lead to blindness, which is associated with an economic burden of $9 billion per year.² This eye condition is categorized as either dry or wet, with the latter manifesting with choroidal neovascularization. Treatments for patients diagnosed with dry AMD are limited to nutritional supplements and lifestyle changes that may slow the progression of the condition but do not provide vision improvement.³ In contrast, substantial innovation has occurred for wet AMD (wAMD), which accounts for approximately 10% of all AMD cases.^1,4 The wAMD treatments (anti–vascular endothelial growth factor [anti-VEGF]) not only prevent further vision loss, but also produce vision improvement lasting as long as 5 years.^5,6

Although multiple anti-VEGF therapies exist, unmet need remains high owing to treatment underutilization, driven primarily by insufficient uptake and high discontinuation.⁷ Approximately 53% to 58% of Medicare patients discontinue treatment within the first year.^7,8 Although cost is cited as a treatment barrier, a less expensive anti-VEGF treatment with similar efficacy and safety as one of the US Food and Drug Administration–approved therapies is available off-label.⁹ Other reasons for discontinuation include fear or discomfort associated with injections to the eye or lack of perceived need.¹⁰

Monthly anti-VEGF treatment has been standard in clinical trials and is associated with better vision improvement. However, regular treatment and monitoring requires substantial time commitment¹¹ and may contribute to poor compliance. This treatment burden has been recognized by ophthalmologists¹²; consequently, personalized treatment strategies attempt to balance the treatment burden against potentially reduced efficacy.

One strategy follows a treat-as-needed approach. Clinical trials have reported similar vision outcomes with monthly treatments during the first year; however, improvement in visual acuity was less likely to be maintained after 2 years.⁹ Moreover, even though patients are treated only as needed, they still receive a monthly examination. Alternatively, a treat-and-extend (TE) approach reduces treatments and visits. After 3 monthly injections, the interval between injections is extended up to 12 weeks based on patient response, and examinations are not needed between treatments.^12,13 Most ophthalmologists (70%) primarily use the TE approach compared with 10% who use the as-needed approach, and 2% who treat monthly (the remaining 18% use a mixture of treatment strategies).¹⁴

Understanding the economic value associated with anti-VEGF therapies as a class may provide insight into the gains from current treatment and future innovations. Although some authors have focused on the cost of anti-VEGF treatment, their work does not consider the benefits of that spending.^15,16 To quantify the economic value of anti-VEGF treatment in the United States, we estimated the value of vision improvements associated with this therapy across 5 years. We considered scenarios that reflected the trade-off between treatment burden and efficacy. To explore the potential value from future innovations that improve treatment compliance, we modeled scenarios that increased the number of treated patients relative to current estimates. Finally, we quantified the potential economic benefit from a best-case, idealized scenario to represent the unmet need that could be addressed by future treatment advances.

Methods

The data were collected and analyzed from March 2018 to November 2018. In this economic evaluation study, we simulated visual acuity (VA) for a cohort of patients with wAMD aged 65 years across 5 years, and translated VA into quality-adjusted life-years (QALYs).¹⁷ Our cohort of 168 820 adults was derived by applying the wAMD incidence rate to the total population of the United States aged 50 years or older.^18,19 We assumed the cohort was 65 years old and incorporated mortality risk using 5-year age-adjusted mortality rates from the National Vital Statistics.²⁰ Mortality was adjusted to account for increased mortality associated with poor VA (adjusted for age, sex, and other confounders).²¹ Baseline VA was 55 letters (modal VA at diagnosis across 7 community-based studies²²). Treatment was initiated in year 1, and we allowed for discontinuation each year. Patients underwent fluorescein angiography at their first visit and optical coherence tomography at noninjection visits. During injection visits, patients received anti-VEGF treatment and optical coherence tomography. Model variables were drawn from the published literature and are described in the eMethods, eTable 1, eTable 2, eTable 3, eTable 4, and eTable 5 in the Supplement, along with a full description of model assumptions. The institutional review board at the University of Southern California approved the study and deemed it exempt from review because it does not involve human subjects.

Model Scenarios

Current Treatment Scenarios

All scenarios were compared with a baseline no-treatment scenario, which assumed that all patients in the cohort were untreated. To estimate the value of current therapy, we considered 2 scenarios that reflected the treatment strategies used by ophthalmologists. The first scenario (less frequent injections) is based on the study by Mrejen et al²³ and assumes that patients receive a mean (SD) of approximately 8.2 (1.6) anti-VEGF injections per year under a TE regimen.

The second scenario (more frequent injections) is based on the study by Peden et al⁵ and assumes that patients receive a mean (range) of 10.5 (6.8-13.1) injections annually. This scenario approximates the label indication for ranibizumab, which recommends monthly injections.²⁴ Table 1 provides VA changes and injection frequencies for both scenarios.

Table 1. Model Scenarios.

Scenario (Source)	Description	Year 1		Year 2		Year 3		Year 4		Year 5
Scenario (Source)	Description	VA Change^a	Injections, No.	VA Change^a	Injections, No.	VA Change^a	Injections, No.	VA Change^a	Injections, No.	VA Change^a	Injections, No.
Baseline scenario
No treatment^b (HORIZON²⁵)	Patients do not receive anti-VEGF therapy	−10.1	0	−9.6	0	−11.8	0	−11.8	0	−16.1	0
Current treatment scenarios
Less frequent injections (Mrejen et al,²³ 2015)	Patients receive anti-VEGF therapy following a TE regimen	6.5	8.96	6.5	7.78	6.0	7.94	4.5	8.03	-0.5	8.12
More frequent injections (Peden et al,⁵ 2015)	Patients receive anti-VEGF therapy (10.5 injections annually)	13.2	10.5	16.1	10.5	15.4	10.5	14.6	10.5	14.0	10.5

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Abbreviations: TE, treat and extend; VA, visual acuity; VEGF, vascular endothelial growth factor.

^{^a}

Visual acuity change is the change from baseline VA and is measured in Early Treatment Diabetic Retinopathy Study letter score.

^{^b}

The HORIZON VA and injection parameters correspond to the control group.

Treatment Innovation Scenarios

To explore the value of improved adherence, we considered several treatment innovation scenarios. For each current treatment scenario, we estimated innovation scenarios that assumed VA outcomes and injection frequencies were the same but with modified treatment uptake and discontinuation.

The improved adherence scenario assumed that 80% of patients initiated therapy vs 65% in current treatment scenarios.⁷ In addition, discontinuation rates were only 17% in year 1 and increased annually, reaching 50% in year 5.²³ We also considered a best-case scenario that estimated an upper bound on the potential value from current treatments. In these scenarios, 100% of patients with wAMD initiated therapy, and discontinuation rates were 6% annually, which was the rate observed in clinical trials.²⁵ Finally, to understand the potential value gains from future therapies with better VA outcomes compared with current anti-VEGF treatments, we considered the hypothetical cure scenario, which assumed that all patients with wAMD received a 1-time treatment resulting in permanent 20/40 visual acuity.

Statistical Analysis

Model Outcomes

Microsoft Excel was used for the study analyses. We estimated the following outcomes for each scenario: number treated, patient benefits, and total costs. Patient benefits equal the total QALYs from VA improvements multiplied by $150 000 (assumed based on the literature).^26,27 Total costs include drug and clinical treatment costs.^28,29 We assumed a per-injection drug cost of $896, which represents the weighted average of ranibizumab ($1865), aflibercept ($1938), and bevacizumab ($77). Weights were based on a study of commercially insured and Medicare Advantage patients.³⁰ Treatment cost included the costs of injection visits ($225) and noninjection visits ($122). Future dollar values were discounted at 3% per year. Societal value estimates were calculated as the difference between patient benefits and total costs. All outcomes are presented for a single incident (ie, newly diagnosed) cohort and at the population level, which assumed that new incident cohorts entered the model annually.

Sensitivity Analysis

We ran sensitivity analyses for key parameters for all scenarios. Our first sensitivity analysis varied drug utilization weights, which altered the total cost. We also conducted a sensitivity analysis on the assumed value for QALYs. Because patient benefits are derived from VA improvements, we performed sensitivity analyses that varied VA-related parameters, as follows: (1) baseline VA; (2) annual VA changes; and (3) simultaneously varied baseline VA and annual changes. Finally, we considered alternative scenarios that used injection frequency data from the study by Peden et al⁵ and VA outcome data from the study by Mrejen et al²³ and vice versa as well as scenarios with subgroup data (subgroups are classified by neovascular subtype). Parameters used in sensitivity analyses are provided in eTable 10, eTable 13, and eTable 15 in the Supplement.

Results

Benefits for a Single Patient

The study population included 168 820 patients aged 65 years or older and diagnosed with wAMD. The underlying clinical trials that were used to parameterize the model did not stratify visual acuity outcomes or treatment frequency by sex; therefore, the model parameters could not be stratified by sex. To provide a sense of the magnitude of dollar benefits generated from VA improvements, we presented the benefits for a single patient who received the anti-VEGF treatment for the full 5-years. Visual acuity improvements from the less frequent injections scenario translated into $10 918 in benefits after 1 year, which increased to $32 158 at 3 years and $49 558 at 5 years. The more frequent injections scenario generated $15 525, $50 839, and $84 873 in benefits at 1, 3, and 5 years, respectively. The hypothetical cure scenario measured unmet need as follows: increasing VA to 20/40 permanently generated $29 215 in benefits at 1 year, $63 506 at 3 years, and $98 308 at 5 years.

Current Treatment Scenarios

The studies used for VA outcomes experienced attrition over time and therefore may be less representative of the general population, particularly after year 3. Rather than truncate our model horizon, we provided results for the time frame for which we had data (5 years) in eTable 6, eTable 7, eTable 8, and eTable 9 in the Supplement and focused on year 3 results because estimates in later years may be less generalizable.

Figure 1 shows cumulative patient benefits, total costs, and societal value for current treatment scenarios for the full population. Year 1 results for the full population include only 1 cohort and therefore are identical to 1-year single incident cohort results (eTable 6 in the Supplement). Compared with the no-treatment scenario, the less frequent injections scenario generated $1.1 billion in patient benefits in year 1 vs $1.6 billion generated by the more frequent injections scenario. At 3 years, patient benefits from the less frequent injections scenario increased to $5.1 billion, and patient benefits from the more frequent injections scenario increased to $8.2 billion.

In the single incident cohort, the total costs incurred were $1.7 billion across 3 years for the less frequent injections scenario and $2.2 billion for the more frequent injections scenario, reflecting the higher number of injections. At the population level, 3-year total costs were $4.3 billion for the less frequent injections scenario and $5.2 billion for the more frequent injections scenario. Societal value (patient benefits net of treatment cost) ranged from $0.9 billion to $3.0 billion across 3 years in the current treatment scenarios (eTable 8 and eTable 9 in the Supplement). Across 3 years, societal value for less frequent injections was $0.9 billion for the full population. In comparison, the more frequent injections scenario generated $2.1 billion additional societal value across 3 years. Therefore, even though the more frequent injections scenario incurred additional costs, the additional patient benefits were substantially higher than those of the less frequent injections scenario, resulting in higher societal value.

Treatment Innovation Scenarios

Figure 2 shows patient benefits for the treatment innovation scenarios, which reflect the potential value of innovation compared with the corresponding current treatment scenario. The improved adherence scenario generated $3.5 billion to $5.6 billion in patient benefits (single incident cohort) and $7.3 billion to $11.4 billion (full population) across 3 years. Results for scenarios that only include individual effects (eg, only modify adherence or only modify discontinuation) are provided in eTable 8 and eTable 9 in the Supplement.

The best-case less frequent injections scenario generated $9.7 billion in patient benefits for the full population across 3 years, which corresponds to an approximately 42% increase in patient benefits compared with that of the improved adherence scenario ($7.3 billion) and an 89% increase compared with that of the less frequent injections scenario ($5.1 billion). Similarly, the best-case more frequent injections scenario generated $15.0 billion in patient benefits for the full population across 3 years, or almost double that of the more frequent injections scenario ($8.2 billion). We compared the patient benefits for both current treatment scenarios along with their corresponding best-case scenarios with the hypothetical cure scenario in Table 2. For the full population, hypothetical cure would generate $6.8 billion in patient benefits at year 1 and $23.7 billion at year 3.

Table 2. Patient Benefits From Treatment Innovation Relative to No Treatment^a.

Patient Benefit	Less Frequent Injections	More Frequent Injections	Best-Case Less Frequent Injections	Best-Case More Frequent Injections	Hypothetical Cure
For single incident cohort, billion $
Year 1	1.1	1.6	1.8	2.5	4.8
Year 3	2.3	3.8	4.8	7.6	10.1
Year 5	2.6	5.0	6.6	11.7	14.9
For entire population, billion $
Year 1	1.1	1.6	1.8	2.5	6.8
Year 3	5.1	8.2	9.7	15.0	23.7
Year 5	9.9	17.0	21.5	35.3	47.7

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^{^a}

Less and more frequent injection scenarios assume 65% uptake and 50% discontinuation (annually). Best case assumes 100% uptake and 6% discontinuation annually. Visual acuity in best case less (more) frequent injections is equivalent to that in less (more) frequent injections. Hypothetical cure assumes that patients receive 1-time treatment resulting in 20/40 visual acuity. Future values are discounted at 3%.

Sensitivity Analyses

Full results for sensitivity analyses are provided in eTable 11, eTable 12, eTable 14, eTable 16, eFigure 1, and eFigure 2 in the Supplement. Patient benefits from the more frequent injections scenario were positive under all parameter values tested. Less frequent injections also generated positive patient benefits under all values except for low baseline VA sensitivities.

Drug utilization shares altered societal value through drug costs. For the full population, if we reduced the share of bevacizumab from 55% to 28%, the societal value across 3 years was −$964 million to $783 million. Conversely, if we increased the bevacizumab share to 72%, the 3-year societal value for the full population increased from $2.0 billion to $4.4 billion.

Alternative scenarios that combined VA and injection parameters from the studies by Peden et al⁵ and Mrejen et al²³ provided insight into how societal value changed if the relationship between VA and injection frequency were reversed. The scenario with relatively low VA (Mrejen et al²³) and relatively high injection frequency (Peden et al⁵) resulted in negative societal value estimates. Conversely, a scenario with relatively high VA (Peden et al⁵) and relatively low injection frequency (Mrejen et al²³) generated almost $1 billion more in societal value across 3 years compared with more frequent injections because the same patient benefit is obtained at lower cost. Similarly, subgroup analyses show a range of societal values, suggesting that more injections will generate higher value only if patients experience better VA outcomes than with fewer injections.

Discussion

We estimated patient benefits, total costs, and societal value generated from anti-VEGF treatment for wAMD across several scenarios. We found that the current treatment scenarios generated substantial value, which increased with injection frequency. However, because both treatment uptake and discontinuation rates could be improved, there is a high degree of unmet need. If all patients with wAMD received anti-VEGF therapy and discontinuation was equivalent to the clinical trial rates, the treatment could generate $95 million to $648 million in additional societal value across 3 years. Because we assumed no additional cost associated with innovation, these estimates represent an upper bound.

Although we considered the value of anti-VEGF therapies as a class, our results are most directly comparable to prior studies^31,32 that compared anti-VEGF treatment with the best supportive care or usual care. The estimated incremental cost-effectiveness ratios (ICER) from these studies were highly variable ($11 412-$308 400), reflecting differences in underlying model assumptions and data.^31,32 Nevertheless, our implied 3-year ICERs ($114 716 for less frequent injections, $83 557 for more frequent injections) fall within the range from prior studies. Although recent studies¹⁵ have questioned the cost of anti-VEGF therapies, a comparison of our implied ICERs with those from recent analyses of newly approved therapies in other disease areas indicates that anti-VEGF therapies provide larger returns on investment. For example, the lower-bound ICER estimate for targeted immune modulator treatments for rheumatoid arthritis is $168 660; similarly, estimates across new oncology therapies range from $146 210 to $291 454.^33,34,35,36

One-year estimates for less frequent injections and more frequent injections were similar, which is consistent with recent studies that show noninferiority of the TE approach compared with monthly injections.³⁷ Optimal treatment frequency has received considerable attention, and although TE is a predominant approach among ophthalmologists in the United States, there is limited head-to-head evidence comparing treatment frequencies, particularly for times beyond 1 to 2 years.^38,39 However, if more frequent injections on average result in better VA outcomes as modeled in our scenarios, the potential value of more frequent injections would be apparent over a longer time; the more frequent injections scenario provided an additional $3.0 billion in patient benefits across 3 years compared with that provided by less frequent injections. The more frequent injections scenario still provided more value than did the less frequent injections scenario even after adjusting for the added cost of more injections, generating $2.1 billion more in societal value. The discrepancy between the long-term estimates favoring more injections and short-term clinical studies highlights the need for additional long-term data comparing treatment frequencies.

Both best-case scenarios show that innovations resulting in higher treatment rates may generate additional patient benefits. Although such innovations would not influence patients whose VA does not respond to current anti-VEGF treatments or whose vision has stabilized, they would benefit patients who report modifiable reasons for discontinuation, such as cost or missing visits.^10,40,41 Although hypothetical cure would represent a meaningful advance in treatment, the relative value of maximizing treatment adherence under current treatment scenarios should not be understated. The best-case more frequent injections scenario generates 3-year patient benefit equal to 63% of that of the hypothetical cure scenario. This suggests that incremental innovations that increase patient adherence even without providing VA improvements beyond current anti-VEGF therapies are an important step toward maximizing value.

Although we have shown that anti-VEGF therapies as a class may provide substantial economic benefits, policy makers often focus on treatment cost. Medicare Part B made $3.0 billion in payments for aflibercept and ranibizumab combined in 2015, and individually these drugs accounted for the highest and fifth-highest Part B drug spending, respectively.⁴² Consequently, policy makers have indicated that Medicare could reduce its spending on wAMD if more patients switched to bevacizumab, which has been shown to be more cost-effective compared with ranibizumab and aflibercept.^15,43,44 The sensitivity analysis that varied drug share parameters found that increasing the share of bevacizumab from 55% to 72% may reduce total costs for the full population across 3 years by $1.8 billion to $2.2 billion.

The study demonstrates the importance of economic valuation of therapies for ocular diseases. Outside ophthalmology, a growing body of literature eschews cost-effectiveness and focuses on valuing the clinical benefits derived from innovative therapies in monetary terms. This literature spans various disease areas and has shown that new therapies for treating HIV infection, hepatitis C, and several cancer types have generated hundreds of billions of dollars in economic benefits.^45,46,47,48 As the pressure to contain health care costs increases, it will be important for ophthalmology as a specialty to generate the data necessary to demonstrate the value of the services provided. The present study suggests that for wAMD, anti-VEGF treatment has generated billions in benefits to patients. However, unmet need remains, suggesting that novel therapies with better efficacy, more durable benefits, or mechanisms that reduce discontinuation may lead to substantial benefits.

Limitations

This study has several limitations related to simplifying assumptions and data availability. Because the underlying data for each treatment scenario correspond to different publications with varied patient populations, there may be concern that the association between injection frequency and VA outcomes in our scenarios may not generalize to the broader US population. This limitation highlights the need for more comprehensive and nationally representative patient data. As a result of this limitation, we note that comparisons across more and less frequent injection scenarios only hold in the real world to the extent that more injections tend to be associated with better VA outcomes. If the reverse were true (more injections associated with lower VA), anti-VEGF therapy for wAMD would not generate positive societal value (see alternative and subgroup data scenarios in eTable 14 in the Supplement).

Second, because we modeled cohort outcomes, we did not capture individual-level VA variation. For example, patients with lower baseline VA tend to have a better response to treatment. However, because we are unaware of VA and injection frequency data stratified by baseline VA spanning at least 5 years, we were unable to incorporate this aspect of heterogeneity into the model. The implications of this limitation were explored in the sensitivity analyses in eTable 16 and eFigure 2 in the Supplement.

Third, the decision to receive anti-VEGF therapy was static; patients could initiate treatment only in year 1 and could not restart treatment after discontinuation. Consequently, the estimates understate benefits because dynamic uptake would increase the number of patients treated. A related issue is our assumption of fixed drug utilization rates. The implication of the assumption could go in either direction: if patients switch to more or less expensive therapies over time, treatment cost may be underestimated or overestimated. These limitations highlight the need for additional data related to treatment dynamics.

Fourth, our patient benefit estimates reflect only the economic value from improved VA and do not incorporate indirect costs. Examples include use of vision aids, higher incidence of depression, falls, functional limitations, and caregiver burden (approximately 82% of patients with wAMD receive caregiver support).^49,50,51,52 Excluding indirect costs from the present analysis underestimates patient benefits and societal value from anti-VEGF treatment.

Conclusions

This study suggests that improved VA associated with anti-VEGF treatment provides economic value to patients and society, and if the association between VA and injection frequency is positive, this value increases with the number of injections. However, a substantially higher value may be realized if adherence improved. This finding suggests that even incremental treatment innovations that lead to improved adherence, such as drug delivery or longer-lasting therapy (lower injection frequency), may provide additional patient benefits.

Supplement.

eMethods.

eTable 1. Baseline Model Parameters

eTable 2. Mapping Visual Acuity to Quality of Life (QoL)

eTable 3. Cost Parameter Components

eTable 4. VA and Injection Parameters, by Model Scenario

eTable 5. Treatment Uptake and Discontinuation Parameters, by Model Scenario

eTable 6. Cumulative Patient Benefits, Costs, and Social Value

eTable 7. Cumulative Number of Patients Treated, Single Incident Cohort

eTable 8. Treatment Innovation Results (Based on Less Frequent Injections VA), Single Incident Cohort

eTable 9. Treatment Innovation Results (Based on More Frequent Injections VA), Single Incident Cohort

eTable 10. Drug Utilization Shares

eTable 11. Sensitivity Analysis: Drug Utilization Shares

eTable 12. Sensitivity Analysis: Value of a QALY

eTable 13. VA Delta Sensitivity Parameters

eTable 14. Sensitivity Analysis: Alternative Scenarios With Varied VA and Injection Frequency

eTable 15. VA Outcomes and Injection Frequency by Subgroup

eTable 16. Sensitivity Analysis: Subgroup Results

eFigure 1. Sensitivity Analysis: VA Parameters, Single Incident Cohort

eFigure 2. Sensitivity Analysis: Subgroup Results (Difference Between Peden and Mrejen), Single Incident Cohort

eReferences.

Click here for additional data file.^{(271.3KB, pdf)}

References

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplement.

eMethods.

eTable 1. Baseline Model Parameters

eTable 2. Mapping Visual Acuity to Quality of Life (QoL)

eTable 3. Cost Parameter Components

eTable 4. VA and Injection Parameters, by Model Scenario

eTable 5. Treatment Uptake and Discontinuation Parameters, by Model Scenario

eTable 6. Cumulative Patient Benefits, Costs, and Social Value

eTable 7. Cumulative Number of Patients Treated, Single Incident Cohort

eTable 8. Treatment Innovation Results (Based on Less Frequent Injections VA), Single Incident Cohort

eTable 9. Treatment Innovation Results (Based on More Frequent Injections VA), Single Incident Cohort

eTable 10. Drug Utilization Shares

eTable 11. Sensitivity Analysis: Drug Utilization Shares

eTable 12. Sensitivity Analysis: Value of a QALY

eTable 13. VA Delta Sensitivity Parameters

eTable 14. Sensitivity Analysis: Alternative Scenarios With Varied VA and Injection Frequency

eTable 15. VA Outcomes and Injection Frequency by Subgroup

eTable 16. Sensitivity Analysis: Subgroup Results

eFigure 1. Sensitivity Analysis: VA Parameters, Single Incident Cohort

eFigure 2. Sensitivity Analysis: Subgroup Results (Difference Between Peden and Mrejen), Single Incident Cohort

eReferences.

Click here for additional data file.^{(271.3KB, pdf)}

[eoi190079r1] 1.Prevent blindness Living with AMD. https://www.preventblindness.org/living-amd. Accessed December 17, 2018.

[eoi190079r2] 2.Wittenborn J, Rein D Cost of Vision Problems: The Economic Burden of Vision Loss and Eye Disorders in the United States. https://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=3&cad=rja&uact=8&ved=2ahUKEwi05fXz5I_lAhXwFjQIHRdPBIQQFjACegQIARAC&url=https%3A%2F%2Fwww.preventblindness.org%2Fsites%2Fdefault%2Ffiles%2Fnational%2Fdocuments%2FEconomic%2520Burden%2520of%2520Vision%2520Final%2520Report_130611.pdf&usg=AOvVaw3vKugHeQ1lHLWwf7sC322S. Published 2013. Accessed October 10, 2019.

[eoi190079r3] 3.Duffy M. New research: two potential treatments for dry macular degeneration and geographic atrophy. VisionAware website. https://www.visionaware.org/blog/visionaware-blog/new-research-two-potential-treatments-for-dry-macular-degeneration-and-geographic-atrophy/12. Published October 2017. Accessed February 1, 2019.

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[eoi190079r5] 5.Peden MC, Suñer IJ, Hammer ME, Grizzard WS. Long-term outcomes in eyes receiving fixed-interval dosing of anti-vascular endothelial growth factor agents for wet age-related macular degeneration. Ophthalmology. 2015;122(4):803-808. doi: 10.1016/j.ophtha.2014.11.018 [DOI] [PubMed] [Google Scholar]

[eoi190079r6] 6.Qin VL, Young J, Silva FQ, Conti FF, Singh RP. Outcomes of patients with exudative age-related macular degeneration treated with antivascular endothelial growth factor therapy for three or more years: a review of current outcomes. Retina. 2018;38(8):1500-1508. doi: 10.1097/IAE.0000000000001753 [DOI] [PubMed] [Google Scholar]

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[eoi190079r9] 9.Maguire MG, Martin DF, Ying GS, et al. ; Comparison of Age-related Macular Degeneration Treatments Trials (CATT) Research Group . Five-year outcomes with anti-vascular endothelial growth factor treatment of neovascular age-related macular degeneration: the comparison of age-related macular degeneration treatments trials. Ophthalmology. 2016;123(8):1751-1761. doi: 10.1016/j.ophtha.2016.03.045 [DOI] [PMC free article] [PubMed] [Google Scholar]

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[eoi190079r13] 13.Freund KB, Korobelnik J-F, Devenyi R, et al. Treat-and-extend regimens with anti-VEGF agents in retinal diseases: a literature review and consensus recommendations. Retina. 2015;35(8):1489-1506. doi: 10.1097/IAE.0000000000000627 [DOI] [PubMed] [Google Scholar]

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[eoi190079r15] 15.Hutton D, Newman-Casey PA, Tavag M, Zacks D, Stein J. Switching to less expensive blindness drug could save Medicare Part B $18 billion over a ten-year period. Health Aff (Millwood). 2014;33(6):931-939. doi: 10.1377/hlthaff.2013.0832 [DOI] [PMC free article] [PubMed] [Google Scholar]

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[eoi190079r19] 19.Rudnicka AR, Kapetanakis VV, Jarrar Z, et al. Incidence of late-stage age-related macular degeneration in American Whites: systematic review and meta-analysis. Am J Ophthalmol. 2015;160(1):85-93.e3. doi: 10.1016/j.ajo.2015.04.003 [DOI] [PubMed] [Google Scholar]

[eoi190079r20] 20.Murphy SL, Xu J, Kochanek KD, Curtin SC, Arias E. Deaths: Final Data for 2015. Natl Vital Stat Rep. 2017;66(6):1-75. [PubMed] [Google Scholar]

[eoi190079r21] 21.Thiagarajan M, Evans JR, Smeeth L, Wormald RP, Fletcher AE. Cause-specific visual impairment and mortality: results from a population-based study of older people in the United Kingdom. Arch Ophthalmol. 2005;123(10):1397-1403. doi: 10.1001/archopht.123.10.1397 [DOI] [PubMed] [Google Scholar]

[eoi190079r22] 22.Ho AC, Albini TA, Brown DM, Boyer DS, Regillo CD, Heier JS. The potential importance of detection of neovascular age-related macular degeneration when visual acuity is relatively good. JAMA Ophthalmol. 2017;135(3):268-273. doi: 10.1001/jamaophthalmol.2016.5314 [DOI] [PubMed] [Google Scholar]

[eoi190079r23] 23.Mrejen S, Jung JJ, Chen C, et al. Long-term visual outcomes for a treat and extend anti-vascular endothelial growth factor regimen in eyes with neovascular age-related macular degeneration. J Clin Med. 2015;4(7):1380-1402. doi: 10.3390/jcm4071380 [DOI] [PMC free article] [PubMed] [Google Scholar]

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[eoi190079r25] 25.Singer MA, Awh CC, Sadda S, et al. HORIZON: an open-label extension trial of ranibizumab for choroidal neovascularization secondary to age-related macular degeneration. Ophthalmology. 2012;119(6):1175-1183. doi: 10.1016/j.ophtha.2011.12.016 [DOI] [PubMed] [Google Scholar]

[eoi190079r26] 26.Hirth RA, Chernew ME, Miller E, Fendrick AM, Weissert WG. Willingness to pay for a quality-adjusted life year: in search of a standard. Med Decis Making. 2000;20(3):332-342. doi: 10.1177/0272989X0002000310 [DOI] [PubMed] [Google Scholar]

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[eoi190079r31] 31.Mitchell P, Annemans L, White R, Gallagher M, Thomas S. Cost effectiveness of treatments for wet age-related macular degeneration. Pharmacoeconomics. 2011;29(2):107-131. doi: 10.2165/11585520-000000000-00000 [DOI] [PubMed] [Google Scholar]

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[eoi190079r34] 34.Institute for Clinical and Economic Review Treatment options for advanced non-small cell lung cancer: effectiveness, value and value-based price benchmarks. Updated October 2016. https://icer-review.org/wp-content/uploads/2016/08/MWCEPAC_NSCLC_Evidence_Report_Plus_Supplement_101716.pdf. Accessed October 4, 2019.

[eoi190079r35] 35.Institute for Clinical and Economic Review Treatment options for relapsed or refractory multiple myeloma: effectiveness, value, and value-based price benchmarks. Published May 2016. https://icer-review.org/wp-content/uploads/2016/05/MWCEPAC_MM_Evidence_Report_050516-002.pdf. Accessed October 4, 2019.

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PERMALINK

Economic Value of Anti–Vascular Endothelial Growth Factor Treatment for Patients With Wet Age-Related Macular Degeneration in the United States

Karen Mulligan, PhD

Seth A Seabury, PhD

Pravin U Dugel, MD

Jill F Blim, MS

Dana P Goldman, PhD

Mark S Humayun, MD, PhD

Key Points

Question

Findings

Meaning

Abstract

Importance

Objective

Design, Setting, and Participants

Main Outcomes and Measures

Results

Conclusions and Relevance

Introduction

Methods

Model Scenarios

Current Treatment Scenarios

Table 1. Model Scenarios.

Treatment Innovation Scenarios

Statistical Analysis

Model Outcomes

Sensitivity Analysis

Results

Benefits for a Single Patient

Current Treatment Scenarios

Figure 1. Patient Benefits, Costs, and Societal Value Associated With Anti–Vascular Endothelial Growth Factor (VEGF) Treatment Compared With No Treatment.

Treatment Innovation Scenarios

Figure 2. Value of Treatment Innovation Compared With No Treatment.

Table 2. Patient Benefits From Treatment Innovation Relative to No Treatmenta.

Sensitivity Analyses

Discussion

Limitations

Conclusions

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

Similar articles

Cited by other articles

Links to NCBI Databases

Table 2. Patient Benefits From Treatment Innovation Relative to No Treatment^a.