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Ann Thorac Surg 2001;71:995-1002
© 2001 The Society of Thoracic Surgeons

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Original article: general thoracic

Economic analysis of lung volume reduction surgery as part of the national emphysema treatment trial

^a Department of Medicine, University of Washington, Seattle, Washington, USA
^b Department of Pharmacy, University of Washington, Seattle, Washington, USA
^c Department of Surgery, University of Washington, Seattle, Washington, USA
^d Center for Outcomes & Effectiveness Research, Agency for Healthcare Research and Quality, Rockville, Maryland, USA
^e Department of Family & Preventive Medicine, University of California, San Diego, California, USA
^f Health & Human Resources Division, Congressional Budget Office, Washington, DC, USA

Accepted for publication August 11, 2000.

Address reprint requests to Dr Ramsey, Fred Hutchinson Cancer Research Center, 1100 Fairview Ave N, Mailstop MP-900, Seattle, WA 98109
e-mail: sramsey{at}fhcrc.org

	Abstract

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
Background. In today’s cost-conscious health care environment, obtaining timely and accurate economic information regarding new medical technologies has become extremely important. The National Emphysema Treatment Trial, a multicenter, randomized controlled trial of lung volume reduction surgery (LVRS) plus medical therapy, versus medical therapy for patients with severe emphysema, includes a parallel cost-effectiveness analysis.

Methods. The analysis is designed to determine the cost-effectiveness of LVRS versus medical therapy for those who are eligible for the procedure. After describing theoretical foundations of cost-effectiveness analysis as they apply to this study, we describe the economic and quality of life data that are being collected alongside the clinical trial, methods of analysis, and approach to presenting the results.

Results. The cost-effectiveness of LVRS relative to medical therapy will be presented as costs per quality-adjusted life years gained.

Conclusions. This analysis will provide timely economic data that can be considered alongside the clinical results of the National Emphysema Treatment Trial. As one of the largest clinical trials to include a parallel, prospective cost-effectiveness analyses, this study will also provide valuable practical information about conducting an economic analysis alongside a multicenter clinical trial.

	Introduction

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
Lung Volume Reduction Surgery (LVRS), a promising new surgical therapy for patients with severe emphysema, has engendered considerable controversy since being reintroduced in 1994. After favorable results from a small study of patients with severe emphysema who underwent LVRS were reported at separate meetings in the spring and fall of 1994, several institutions throughout the country began offering LVRS programs and actively recruiting patients [1]. By December of 1995, Health Care Financing Administration (HCFA) records indicated that over 1,200 LVRS procedures had been performed on Medicare beneficiaries [2]. In December of 1995, the HCFA announced that Medicare would not pay for LVRS, on the grounds that insufficient safety and efficacy evidence were available to support reimbursement [3]. Subsequently, the HCFA and the National Heart, Lung, and Blood Institute (NHLBI) announced that they would cosponsor a multicenter, randomized controlled trial to evaluate the efficacy of LVRS. In October of 1997, patients began enrolling into what is now known as the National Emphysema Treatment Trial (NETT).

Should the NETT demonstrate that LVRS provides a significant and lasting improvement for those with emphysema, the financial impact on the health care sector may be substantial. Emphysema affects approximately 2.0 million Americans and is one of the fastest growing causes of morbidity and mortality in the United States [4]. The mean reimbursement for the more than 1,200 LVRS procedures performed on Medicare beneficiaries was $31,398 per procedure [2]. Given the prevalence of emphysema, even if a comparatively small proportion of individuals with this disease are eligible for LVRS, widespread adoption of this procedure could increase US health care expenditures by hundreds of millions of dollars [2, 5].

As efforts to control health care spending become increasingly intense, decision makers are forced to confront the reality that adopting new, cost-increasing technologies necessitates spending less in other areas of health care. In this context, some have argued that it is reasonable to consider the outcomes and costs for LVRS relative to outcomes and costs for other medical procedures [6–8]. The most common and accepted approach to compare the relative value of different interventions in creating better health or longer life is cost-effectiveness analysis (CEA).

As clinical services provided for NETT are reimbursed by HCFA, NETT provides a landmark opportunity to complete a rigorous cost-effectiveness analysis. Recognizing this, the Agency for Healthcare Research and Quality agreed to support a CEA alongside NETT, and HCFA, NHLBI, and NETT investigators to provide data for the CEA. The parallel analysis of cost-effectiveness alongside the clinical trial has two important advantages. First, it is an efficient and timely way to obtain data on clinical, economic, and humanistic outcomes simultaneously. Timely economic data will be particularly useful to those who are responsible for health care budgets, since LVRS may become a widely used procedure for patients with severe emphysema if the NETT demonstrates a beneficial effect of the procedure. Second, performing a CEA alongside a randomized, controlled trial has high internal validity and low potential for bias. If one accepts the notion that economic considerations are unavoidable in clinical decision-making, the highest quality economic evidence should be used.

In this article, we provide an overview of the CEA that will be conducted alongside the NETT. We begin by summarizing the approach for performing a CEA of a new medical technology, and describe how it will be applied to the alternative treatments being studied in the NETT. We then describe how the findings from this study should be interpreted in the context of other economic analyses of medical interventions.

	The National Emphysema Treatment Trial

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
The National Emphysema Treatment Trial (NETT) is a multicenter, randomized controlled trial of lung volume reduction surgery (LVRS) versus medical therapy (MT) for patients with severe emphysema [9]. Seventeen participating centers will randomly assign approximately 2,500 patients meeting inclusion criteria into two treatment arms: MT versus medical therapy with LVRS. At six centers, patients randomized to surgery will also be randomized as to surgical approach: LVRS via median sternotomy versus LVRS via video-assisted thoracoscopic surgery. Prior to randomization, all patients will undergo a 6 to 10 week period of pulmonary rehabilitation and optimization of their medical therapy. Since the trial has a fixed end date, follow-up postrandomization will range from 6 months to 5 years, depending on the date of entry into the protocol. The primary outcome measures for the trial are mortality and maximal exercise capacity as measured by a cycle ergometer. Other outcomes include measures of pulmonary physiology, emphysema-related quality of life measured by the St. Georges Respiratory questionnaire [10], and general health-related quality of life measured by the Quality of Well Being questionnaire [11].

The cost-effectiveness estimate for LVRS will be derived for costs and consequences that accrue over the time horizon of the clinical trial (5 years) utilizing data drawn directly from the trial. Costs will be estimated by tracking Medicare health care claims data for trial participants (provided by the HCFA) and applying national average prices to those claims, based on Medicare reimbursement levels. Health services not covered by Medicare (such as drugs) are being collected as part of the clinical trial, and will be incorporated into the analysis after applying average prices from national average wholesale price data. Health care costs for participants will be tracked during 6 months prior to entry into the study and through the duration of the trial. Survival and quality of life data for trial participants will be used to estimate the effectiveness of each arm of the trial, as described below. The cost, quality of life, and survival data will be used to derive lifetime cost-effectiveness estimates for LVRS compared to medical therapy.

	Economic analysis of medical technologies

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
The approach to performing cost-effectiveness analyses of medical technologies has become standardized in recent years, with principles and procedures for analysis and reporting results that should be adhered to as is done for clinical evaluations [12, 13]. Readers should now expect to find elements in reports of cost-effectiveness analyses indicating that a sound evaluation was performed (Table 1).

((1))

Where C_LVRS and C_MT refer to average total costs, and E_LVRS and E_MT refer to average total effectiveness for the LVRS and MT arms, respectively. Theoretically, four outcomes are possible in the analysis. They are represented graphically in Figure 1. The Y-axis displays the numerator of Equation (1), the absolute difference in costs. The X-axis displays the denominator of Equation (1), the absolute difference in effectiveness. Quadrant B illustrates the scenario where LVRS is less effective (denominator negative) and costs more than MT (numerator positive). In this case, we would unequivocally reject LVRS and continue with MT. Quadrant C depicts a situation where LVRS improves health outcome and achieves cost savings (numerator negative, denominator positive). In this case, LVRS is a dominant technology; that is, it is unambiguous that we would adopt LVRS over MT. Quadrant D represents a scenario where LVRS is less expensive than MT, but reduces health outcomes compared to standard therapy. Quadrant A shows the cost-outcome relationship for most new medical technologies. Here, health benefits improve, but at an additional expense to the health care system. Line OM graphically represents the cost-effectiveness derived from Equation (1) for a technology that increases both costs and outcomes. For outcomes in Quadrant A, clinicians, patients, and payers must decide whether the improvement in health outcome is worth the additional cost of providing care with the new technology, ie, what is the maximum acceptable cost-effectiveness ratio from equation (1). Note that in a health care system with a fixed budget, additional expenditure on a new treatment like LVRS, even if it is considered "cost-effective" (that is, improved health or life expectancy at low additional lifetime cost), reduces the amount of resources that are available to treat other diseases.

View larger version (14K): [in this window] [in a new window]   Fig 1. Possible outcomes of LVRS versus MT. Figure created with data adapted from Anderson and associates [23]. (A = LVRS more costly and more effective than MT; B = LVRS more costly and less effective than MT; C = LVRS less costly and more effective than MT; D = LVRS less costly and less effective than MT; MT = medical therapy.)

Medical alternatives to LVRS
In cost-effectiveness analysis, it is important to define and justify the therapy or therapies that will be compared to the medical intervention of interest. Usually, the competing therapy is what would be considered the best alternative care of the patient prior to introduction of the new technology. In the NETT, the alternative to surgery is MT. Since MT is considered the best alternative for patients with emphysema, it is also an appropriate choice for the economic analysis. In the clinical trial, two LVRS surgical approaches are being compared: median sternotomy and video-assisted thoracoscopy. Although power calculations indicate that the number of subjects planned for this trial are sufficient to evaluate the overall cost-effectiveness of LVRS, there may be insufficient numbers to evaluate the cost-effectiveness each surgical approach compared to MT. Because person-to-person variation in costs is usually much greater than variation in effects, the number of patients required to establish cost-effectiveness is usually greater than the number needed to establish clinical efficacy alone [14].

All subjects enrolled in the NETT will undergo a pulmonary rehabilitation program prior to randomization into the surgical or medical therapy arms. Although evidence exists that pulmonary rehabilitation may improve outcomes for patients with emphysema, it has not traditionally been part of standard therapy for this condition in the United States [15, 16]. Thus, it would be appropriate to test the efficacy and cost-effectiveness of either LVRS or pulmonary rehabilitation alone in comparison to MT for patients with emphysema. Because pulmonary rehabilitation is integrated into the trial as a required preliminary intervention for all trial participants, however, it will not be possible to estimate the incremental cost-effectiveness of rehabilitation (although its impact on quality of life will be assessed).

Identification and valuation of measures of effectiveness and costs
Measures of effectiveness
The measure of effectiveness for this cost-effectiveness analysis is quality-adjusted life years (QALYs), a measure of life expectancy, modified by patient-derived estimates of quality of life over this time period. Measures of health-related quality of life, when they reflect individual preferences for particular states of health, are known as utilities. Utilities are measured on a scale from 0 (death) to 1 (optimal health). The utility values (called weights) are obtained by interviewing patients using standardized survey techniques at regular intervals over time. Average utility weights for the treatment and control groups are multiplied by the percent surviving each period (those who have died have a utility of 0) to obtain a QALY estimate for each group. The difference in the QALY estimates for each group, which can be shown graphically (Fig 2) is the gain in quality-adjusted life expectancy afforded by the treatment. This is reflected by the difference under the quality-adjusted survival curves. For example, if subjects in the LVRS arm lived an average of 2 years after their operation and had an average utility score of 0.7 over this time period, then they would be assigned 1.4 QALYs. The NETT clinical protocol calls for measurement of health-related quality of life using several measures of general health status and emphysema-specific health status. The quality of life survey instrument that is most salient to the cost-utility analysis is the Quality of Well Being (QWB) questionnaire, a validated general health status measure that contains several domains, such as mobility, physical activity, and social activity [11] (Table 2). The QWB has been used in studies of chronic obstructive pulmonary disease (COPD) patients for about 20 years, and has been shown to be valid, reliable, and responsive to changes in health status for individuals with this condition [17, 18]. A methodology has been developed to translate the responses from the QWB into utility weights that may be used to derive QALYs [11]. The QWB questionnaire will be administered at enrollment and at months 6, 12, 24, 36, 48, and 60 from the point of randomization. Survival estimates for patients in each trial arm for each time period postrandomization will be multiplied by utility weights for those time periods and summed to determine total QALYs for LVRS and MT.

View larger version (13K): [in this window] [in a new window]   Fig 2. Theoretical diagram of quality of life and survival for LVRS patients versus MT patients. Dips in the curves represent exacerbations that reduce quality of life. In the diagram, LVRS patients initially have reduced quality of life while recovering from surgery, but ultimately have higher overall quality of life and longer survival, translating into a higher number of QALYs (difference in area under curves for LVRS patients and MT patients) (LVRS = lung volume reduction surgery; MT = medical therapy; QALY = quality adjusted life years).

Since the great majority of patients in this study will be enrolled in the Medicare program, the values assigned to each resource will be the reimbursement amounts that Medicare provides for the services. Since Medicare reimbursements for hospital, outpatient, and physician services are often lower than what private health insurers will pay for the same service, the total costs of care that will be estimated for each treatment arm in this study might be considered conservative in this respect.

Accounting for time preference when valuing future costs and effects
In general, people prefer to receive health benefits today and incur the costs sometime in the future, all other things being equal. From an economic point of view, this phenomenon involves trade-offs between current costs and future benefits. The costs may be purely psychic, such as the loss of pleasure from passing up a rich dessert. They may involve time, such as that used to undertake exercise programs, or they may involve financial and nonfinancial resources. Health benefits typically take the form of reductions in the probability of mortality or morbidity from disease sometime in the future. The acceptance of a current cost for a future benefit constitutes an investment, and individuals and health payers differ in their willingness or ability to undertake investments. That is, they have different time preferences.

For example, most people faced with the question, "Would you rather have $100 now, or $103 in 1 year?" will prefer to take the money today rather than wait 1 year for the extra $3. Time preference applies to both health care costs and benefits, including survival. To account for this characteristic of human nature, health economists use a mathematical procedure to decrease the future value of costs and benefits associated with a particular intervention, a practice known as discounting. Some have criticized the practice of discounting health benefits on the grounds that future health and life is not a "commodity" like other goods and services. In defense, economists note that discounting costs but not benefits can lead to a situation where a health intervention will become more and more cost-effective as the program is delayed farther and farther into the future. In addition, evidence exists that individuals internally "discount" future health benefits at the same rate as costs. Because of these issues, most health economists take the position that discounting is necessary. In the economic analysis of the NETT, the base "discount rate" for future costs and benefits will be 3% [12], but this value will ultimately be varied between 0% and 10% in separate analyses.

Allowance for uncertainty in the estimates
Two important sources of uncertainty must be addressed in the CEA of the NETT. The first source is primarily a statistical issue: With what degree of confidence can we say that the cost-effectiveness ratio we derive from the trial is the true incremental cost-effectiveness of LVRS? As is routinely done for the clinical portion of randomized trials, this can be accomplished by creating a confidence interval around the estimate of incremental cost effectiveness. Creating the interval is technically difficult, and economists have only recently devised methods for estimating these intervals [19]. These intervals can be used to present the data in ways that are helpful for decision-makers; for example, by stating that there is a 90% probability that the incremental cost-effectiveness of LVRS is at, or below, a certain threshold value.

The second source of uncertainty is how closely the cost-effectiveness estimates derived in the artificial situation of a clinical trial will represent cost-effectiveness in the "real world" setting. Here, there are several issues to consider. One issue of concern to trial investigators is that some patients who are randomized to the medical therapy arm may obtain surgery outside the clinical trial. Including these patients as originally randomized for analysis (an "intent-to-treat" analysis) would bias both the final cost and outcome estimates. If a substantial proportion of patients in the medical therapy arm obtain surgery outside the trial, the analysis will need to be rerun excluding such patients and then comparing the results to an intent-to-treat analysis. If the differences are great, both results may have to be presented. A second issue is that patient selection criteria for the trial have been made with limited knowledge. If it is possible to reliably identify patients who are going to have a particularly poor or good outcome prior to surgery, then guidelines might be established recommending against or for surgery in these subgroups. In this case, performing a separate cost-effectiveness analysis for study patients who meet guidelines would be appropriate. Finally, as with other carefully designed and monitored clinical trials, outcomes are likely to be better for both LVRS and MT patients than is typical for community practice. Thus, commonly stated concerns about the external validity of clinical trials also translate to the cost-effectiveness analysis. Health economists address this issue with a technique called sensitivity analysis. Here, one examines the sensitivity of the primary cost-effectiveness estimate to alternative scenarios that might more closely reflect "real world" uses and outcomes for LVRS.

Several analytic steps will be performed to attempt to identify outcomes and costs that are likely to reflect typical clinical use of LVRS. First, the cost-effectiveness of LVRS will be estimated after removing research protocol-induced costs. To identify these elements, principal investigators from the participating NETT centers will be polled to identify resources that are unlikely to be utilized outside the clinical trial setting. Second, cost-effectiveness ratios will be calculated using data for subgroups of trial enrollees (eg, upper and lower bounds of the eligible age range, pulmonary function parameters, and QWB score at entry). These analyses may help predict the cost-effectiveness when LVRS is applied to patients that fall somewhat outside the eligibility criteria established in the NETT protocol. Finally, the cost-effectiveness ratio for LVRS will be reanalyzed after varying the values of key input parameters (for example, the cost of the surgery itself), both individually (one-way sensitivity analysis) and simultaneously (two and n-way sensitivity analysis). Worst- and best-case cost-effectiveness ratios will then be calculated using the upper and lower bounds of 95% confidence intervals derived for the input parameters that were used to calculate the baseline cost-effectiveness ratio. This analysis will be used to account for trends that occur over the course of the NETT trial. For example, it is possible that average postoperative hospital length of stay will fall over the course of the trial as trial participants gain experience with managing these patients. Using a simple average of hospitalization costs obtained throughout the trial might produce an overestimate of the true costs of hospital care that can be expected following the trial. To address trending over time, time-series analysis regression techniques will be used. For parameters where a trend is found, the cost-effectiveness ratio will be estimated using: (1) average values for inputs obtained during the last year of observation; (2) predicted input parameters for the end of the period of observation from the time-series model.

Interpretation and application of the results
If patient outcomes were so improved after LVRS compared to MT that the initial cost of surgery was more than offset by savings from reduced emphysema-related care in the years following surgery, LVRS would dominate MT (quadrant C, Fig 1). Likewise, if outcomes were worse and lifetime costs were higher for LVRS patients, MT would dominate LVRS. Many experts associated with the NETT, however, expect an outcome where LVRS is both more expensive and more effective than standard medical therapy for emphysema (quadrant A in Fig 1). Even if we assume that this will be the case, the magnitude of the difference in costs and benefits remains a critically important issue. In today’s budget-driven health care system, it is not unreasonable to argue that the relative cost-effectiveness or cost-ineffectiveness of LVRS may ultimately determine the degree to which it is adopted by the health care system at large.

We are seeking to determine whether LVRS is "cost-effective" compared to MT. This of course begs the question of whether there is a widely agreed upon threshold value for cost-effectiveness. A commonly cited manuscript suggests that interventions with an incremental cost-effectiveness ratios of $27,000 per QALY (1997 US dollars) or less had "strong evidence" of cost-effectiveness, while those ratios between $27,000 and $125,000 per QALY had "moderate evidence of cost-effectiveness [20]. Still, decision-makers are more likely to evaluate the cost-effectiveness of LVRS relative to the cost-effectiveness of other common health care interventions than by whether it exceeds a reference value. Table 4 lists cost-effectiveness ratios for several common medical interventions. Cost-effectiveness studies have not been major factors in decisions to adopt or not adopt new technologies in the United States. Still, if LVRS is shown to have marginal effectiveness and a very high cost compared to other common therapies, it is likely that health insurers will erect barriers to limit their reimbursements for this technology. Bone marrow transplantation for breast cancer is a recent example of a high-cost procedure where health insurers have curtailed coverage on the grounds that the evidence shows uncertain or minimal benefit [21, 22]. It is important to emphasize that the goal of most procedures in health care is to produce QALYs. The purpose of this analysis is to estimate the best way to allocate resources in order to achieve the most health given limited funds.

	Conclusions

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
In today’s cost-conscious health care environment, obtaining accurate economic information regarding new medical technologies has become extremely important. If LVRS is shown to be beneficial for patients with severe emphysema, the economic impact of widespread adoption of LVRS will be substantial. The results of the analysis—which is one of the largest clinical trials to include a cost-effectiveness analysis—will provide high-quality economic evidence to guide medical decision-making. This study will employ standardized and accepted methods for conducting and presenting economic analyses, which will facilitate the usefulness of the results for policymaking and comparing the economic outcomes for LVRS to other advanced technologies for the treatment of chronic illness.

	Acknowledgments

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 
The following funding sources are acknowledged: Agency for Healthcare Research and Quality, Rockville, MD; Health Care Financing Administration, Baltimore, MD; and National Heart, Lung, and Blood Institute, Bethesda, MD.

	References

Top Abstract Introduction The National Emphysema Treatment... Economic analysis of medical... Conclusions Acknowledgments References

 

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