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Design of a multiple criteria decision analysis framework for prioritizing high-impact health technologies in a regional health service

Published online by Cambridge University Press:  05 April 2024

Fernando-Ignacio Sánchez-Martínez*
Affiliation:
Applied Economics Department, University of Murcia, Murcia, Spain
José-María Abellán-Perpiñán
Affiliation:
Applied Economics Department, University of Murcia, Murcia, Spain
Jorge-Eduardo Martínez-Pérez
Affiliation:
Applied Economics Department, University of Murcia, Murcia, Spain
Jorge-Luis Gómez-Torres
Affiliation:
International Doctorate School, PhD programme in Economics, DEcIDE, University of Murcia, Murcia, Spain
*
Corresponding author: Fernando Ignacio Sánchez Martínez; Email: [email protected]
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Abstract

Objectives

This study aims to develop a framework for establishing priorities in the regional health service of Murcia, Spain, to facilitate the creation of a comprehensive multiple criteria decision analysis (MCDA) framework. This framework will aid in decision-making processes related to the assessment, reimbursement, and utilization of high-impact health technologies.

Method

Based on the results of a review of existing frameworks for MCDA of health technologies, a set of criteria was proposed to be used in the context of evaluating high-impact health technologies. Key stakeholders within regional healthcare services, including clinical leaders and management personnel, participated in a focus group (n = 11) to discuss the proposed criteria and select the final fifteen. To elicit the weights of the criteria, two surveys were administered, one to a small sample of healthcare professionals (n = 35) and another to a larger representative sample of the general population (n = 494).

Results

The responses obtained from health professionals in the weighting procedure exhibited greater consistency compared to those provided by the general public. The criteria more highly weighted were “Need for intervention” and “Intervention outcomes.” The weights finally assigned to each item in the multicriteria framework were derived as the equal-weighted sum of the mean weights from the two samples.

Conclusions

A multi-attribute function capable of generating a composite measure (multicriteria) to assess the value of high-impact health interventions has been developed. Furthermore, it is recommended to pilot this procedure in a specific decision context to evaluate the efficacy, feasibility, usefulness, and reliability of the proposed tool.

Type
Policy
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The growth of healthcare expenditure poses significant challenges to resource allocation in public health systems. Demographic (e.g., aging) and nondemographic determinants of healthcare spending (e.g., biomedical technology innovation) exert considerable pressure on public budgets (Reference Baltagi, Lagravinese, Moscone and Tosetti1Reference Zweifel, Steinmann and Eugster6). Consequently, healthcare managers face the daunting task of making decisions with substantial opportunity costs within increasingly complex and multifaceted contexts (7;Reference Schmets, Rajan and Kadandale8).

In the European context, a value-based approach is employed to assist in public financing and pricing decisions concerning new health technologies (Reference Oortwijn, Sampietro-Colom and Habens9). For instance, the United Kingdom assesses value by comparing the cost utility of an intervention (measured as the Incremental Cost per Quality-Adjusted Life Year gained) with an efficiency threshold (10). In France and Germany, however, value is determined based on the incremental therapeutic benefits and domestic reference pricing, with cost-effectiveness playing a small role in the overall approach (Reference Toumi, Remuzat, El Hammi, Millier, Aballéa and Chouaid11;Reference Lauenroth and Stargardt12).

Furthermore, significant advancements in biomedical innovation have added complexity to the evaluation and decision-making processes (Reference Okunade and Murthy13Reference Willemé and Dumont15). Due to potential conflicts of interest among stakeholders, there is an increasing use of methodologies that systematize the criteria for assessing health technologies. The multiple criteria decision analysis (MCDA) is particularly notable in this regard, encompassing a set of methods that aid in prioritizing actions by assigning relative importance to each criterion reflecting different dimensions of health technology’s performance. These dimensions include clinical effectiveness, safety, cost, ethical considerations, and patient preferences (Reference Baltussen and Niessen16Reference Devlin and Sussex19).

The aim of this study is to design an MCDA framework to inform decisions on the incorporation of high-impact technologies in the regional health service of Murcia, Spain. By “high-impact” technologies, we mean both impact on patients’ health – reducing the burden of disease they bear, and/or impact on the available budget – consequently displacing other healthcare services.

The Spanish healthcare system is a markedly decentralized one, with a notable degree of autonomy in how each regional health service prioritizes funding for new healthcare technologies, especially those that do not involve pharmaceuticals. Although MCDA is currently used by some Spanish regions (e.g., Catalonia uses this methodology to assess some drugs), in the Region of Murcia – a relatively small Spanish region, accounting for 3 percent of the national population – there is currently no formalized procedure with explicit criteria for making these decisions. This lack of a standardized process results in significant differences between health areas.

The specific objectives are to select the criteria that will be part of the scheme, as well as to obtain the weights of each of them based on the preferences of health professionals and general population. The task of assigning scores to each of the criteria is outside the scope of our study, so in this respect it is similar to the approach followed by Cleemput et al. (Reference Cleemput, Devriese, Kohn, Devos, van Til and Groothuis-Oudshoorn20) in their report for the Belgian Health Care Knowledge Centre (KCE).

The next section provides a summary of the fundamental aspects of MCDA and its applications. In Methodology section, we elaborate on the methodologies employed to develop an MCDA framework tailored to assess high-impact health technologies within the context of a Spanish regional health service. The findings derived from the analysis are presented in Results section, followed by a Discussion section, which precedes the final conclusions.

The multiple criteria decision analysis framework

A classical definition of MCDA is that by Keeny and Raiffa (Reference Keeny and Raiffa21), “a methodology for appraising alternatives on individual, often conflicting criteria, and combining them into one overall appraisal.” The potential of MCDA in healthcare decision making was recognized in the 1980s and, since then, the use of MCDA in health technology assessment (HTA) has been actively promoted, based on its potential, but also criticized, because of doubts about its suitability (Reference Campillo-Artero, Puig-Junoy and Culyer22). Nevertheless, MCDA has been widely utilized in the healthcare sector for various decision-making purposes (Reference Thokala, Devlin, Marsh, Baltussen, Boysen, Kalo, Longrenn, Mussen, Peacock, Watkins and Ijzerman23;Reference Glaize, Duenas, Di Martinelly and Fagnot24), such as new technology evaluations (Reference Husereau, Boucher and Noorani25;Reference Danner, Hummel, Volz, van Manen, Wiegard and Dintsios26), assessment of orphan drugs (Reference Sussex, Rollet, Garau, Schmitt, Kent and Hutchings27;Reference Gilabert-Perramon, Torrent-Farnell, Catalan, Prat, Fontanet and Puig-Peiró28), risk–benefit assessments (Reference Phillips, Fasolo, Zafiropoulos and Beyer29), hospital purchasing (Reference Dolan30Reference Pecchia, Martin, Ragozzino, Vanzanella, Scognamiglio and Mirarchi33), and establishing priority frameworks for different types of interventions (Reference Goetghebeur, Wagner and Khoury34;Reference Marsh, Dolan, Kempster and Lugon35).

Interest in using MCDA to inform decisions on public financing of new technologies has also grown in recent decades. Consequently, various guidelines have been developed based on this methodology by HTA institutions (Reference Devlin and Sussex19;Reference Cleemput, Devriese, Kohn, Devos, van Til and Groothuis-Oudshoorn20;Reference Husereau, Boucher and Noorani25;Reference Márquez-Peláez, Espín Balbino, Olry de Labry Lima and Benítez Hidalgo36).

MCDA is typically categorized into two main approaches: qualitative and quantitative. In qualitative MCDA, technologies are evaluated through deliberation about their performance on explicitly defined criteria (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37). The goal of quantitative MCDA is to obtain a global measure of the value of each technology. An overwhelming majority of studies that have utilized MCDA in HTA are of a quantitative nature (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37).

Quantitative MCDA frameworks comprise three primary phases (Reference Devlin and Sussex19): selection of criteria, weighting of criteria, and application of the framework established in the two previous phases. The selection of criteria must adhere to the requirements set forth in the recommendation guide of the International Society for Pharmacoeconomics and Outcomes Research (ISPOR): completeness, nonredundancy, no-overlap, and preference independence (Reference Marsh, Ijzerman, Thokala, Baltussen, Boysen and Kaló18).

Performance for each criterion can be measured using various scales (binary, categorical, ordinal, ratio, interval, etc.). On the other hand, weighting involves eliciting stakeholders’ preferences between criteria (Reference Campillo-Artero, Puig-Junoy and Culyer22). Weights reflect the “trade-offs” between criteria and are needed to combine the scores on individual criterion into a unique measure of “total value.”

There are different types of methods for scoring and weighting criteria: direct methods, hierarchical methods, discrete choice methods, and matching methods (Reference Marsh, Goetghebeur, Thokala and Baltussen38). The source of preferences depends on the type of decision problem. The “stakeholders” can be members of the Regulatory Committees or the Health Technology Assessment Committees, patients, clinical leaders and other health professionals, or the general public (Reference Campillo-Artero, Puig-Junoy and Culyer22).

Once the alternatives’ performance is scored and the criteria are weighted, their values must be aggregated to determine which intervention generates the highest value. Aggregation can be performed using a variety of procedures (e.g., additive, multiplicative, regression), depending on the methods used to score the criteria and assign weights (Reference Marsh, Lanitis, Neasham, Orfanos and Caro39).

Subsequently, uncertainty analysis in the ADM framework is conducted similar to economic evaluation studies. Sensitivity analysis should consider all sources of uncertainty (structural, stochastic, parameter, etc.), and can be deterministic or probabilistic (Reference Broekhuuizen, Groothuis-Oudshoom, van Til, Hummel and Ijzerman40).

Methodology

Selection and structuring of the criteria

To select the criteria that will constitute the MCDA framework, a discussion meeting was conducted with a carefully selected group of organizational members. The group included various high-ranking officials from the regional health service, as well as health area managers and other mid-level executives (more detailed information is available in Table S1 of the Supplementary Material 1). All of them possess decision-making authority regarding the purchase and use of these technologies. The meeting took place on November 26, 2021, at the facilities of the regional health service.

Prior to the meeting, the participants were provided with a list of criteria. These criteria resulted from a two-step preselection process conducted by the research team. Firstly, a set of criteria were selected from the latest version of the EVIDEM framework (41). The EVIDEM (Evidence and Value: Impact in Decision Making) framework consists of a “core model” with thirteen quantifiable criteria, grouped into five domains, supplemented by a contextual tool of six qualitative criteria and one criterion related to the opportunity costs of the intervention. Each generic criterion may encompass specific subcriteria pertinent to distinct therapeutic areas or intervention types.

Fourteen criteria were chosen, comprising the thirteen criteria from the “core model” and the Opportunity Cost Considerations criterion. The reason for selecting most of the criteria from the EVIDEM framework was that these criteria are generic and universally applicable (Reference Goetghebeur, Wagner, Khoury, Rindress, Grégoire and Deal42).

Additionally, the criteria from the KCE framework were integrated, with appropriate modifications when necessary. The KCE report (Reference Marsh, Dolan, Kempster and Lugon35) includes results from a survey of the general population and health decision makers, aimed to assign weights to ten criteria grouped into three categories: therapeutic needs, social needs, and the added value of the new treatment. These criteria were based on a transparent decision framework previously developed by the KCE (Reference Polain, Franken, Koopmanschap and Cleemput43), designed to enhance accountability in the realm of public healthcare benefits reimbursement, a goal closely aligned with the objectives of our proposal. Hence, we chose to integrate some of its criteria in our framework.

The criteria thus selected were then grouped into five domains, and are those shown in Table 1, with the exceptions and qualifications indicated at the foot of the table. The precise definition of domains, criteria, and subcriteria can be found in the glossary (Supplementary Material 2).

Table 1. Criteria of the MCDA resulting from the focus group

Source: Own elaboration, based on EVIDEM 10th edition (Reference Campolina, Estevez-Diz, Abe and de Soárez55), the KCE framework. (Reference Marsh, Dolan, Kempster and Lugon35), and the results of the decision makers’ discussion group.

a The criterion “Type of benefit” was initially included as a domain in the proposal submitted for debate and vote. The participants in the focus group agreed to relocate it as a criterion, within the domain “Outcomes of the intervention.”

b The domain “Feasibility” and its two criteria were absent in the initial proposal, but were added as a result of the focus group discussion.

The dynamics of the discussion meeting was as follows: First, the objective and mechanics of the meeting were explained to the participants. The domains were then voted on, followed by a debate and discussion of the results, which, if applicable, could lead to an extension or reduction of the domains. The criteria were then voted on, following the same methodology as for the domains: voting, debate and discussion, and, if necessary, extension, reduction, and/or relocation of the criteria. Finally, this same process was carried out with the subcriteria included within each criterion previously selected.

It is important to emphasize that, before each vote, participants could suggest additions or modifications to the list of domains or criteria under consideration. The objective was to reach final decisions by consensus after discussing the results following each vote. If consensus was not achieved, the majority rule was applied.

Weighting of the criteria

To obtain the weights associated with the criteria, we conducted surveys with two distinct samples: decision makers and healthcare professionals from the Regional Health Service, and a sample drawn from the general population of the Region of Murcia. This approach allows us to compare the judgments of professionals, who possess specialized expertise, against the presumably less informed viewpoint of the general population.

Sixty-seven professionals were extended invitations by the Regional Health Service to participate in the survey. Among the recipients were area managers, hospital medical directors, coordinators, and heads of specialized services with high technological requirements (surgery, oncology, etc.). The response rate was 52 percent (thirty-five respondents).

A representative sample of the population (n = 500) was obtained through a two-stage stratified sampling methodology. To optimize the response rate, recruitment strategies included advance contact, reminders, and appointment scheduling. As the survey was endorsed by the Health Department, high collaboration was achieved, obtaining a response rate of 99 percent (494 valid questionnaires). Statistics of this sample are available in Supplementary Material 1 (Table S2).

Two questionnaires were designed, and interfaces were programmed for this purpose, with one questionnaire tailored for each sample. The structure of each questionnaire was similar in both surveys, except for the need to include additional information in the case of the general population. In the latter, wording was slightly simplified to ensure comprehension. Both questionnaires started with an introduction to the survey’s primary objective, namely, to determine the relative importance assigned by the respondents to the different criteria within the analysis framework.

The questionnaire for professionals was administered online, while computer-assisted personal interviews (CAPI) were conducted in the homes of participants for the general population sample,.

To assign weights to the domains, criteria, and subcriteria, we utilize the allocation of 100 points. This method involves distributing 100 points among the domains, 100 points among the criteria within each domain, and 100 points among the subcriteria within each criterion. Some screenshots can be seen in Supplementary Material 3.

The weights obtained from the two subsamples were compared by means of parametric (t-test for independent samples) and nonparametric (Mann–Whitney–Wilcoxon) tests.

Results

Selection of the criteria

The initial proposal described in the previous section was presented to the eleven members of the discussion group responsible for selecting the criteria. Before voting on the domains, one of the participants suggested adding a domain that captured the availability of resources within the healthcare system to incorporate the technology under evaluation, as well as its impact on the system’s organization. This proposal was accepted by consensus, and the “Feasibility” domain was added, including two criteria (see Table 1). All domains received unanimous support from the participants, except for the “Knowledge of the intervention” domain, which recorded two opposing votes.

The criteria received unanimous endorsement from the participants, with few exceptions: “Comparative safety,” “Patient-perceived outcomes,” “Preventive benefit,” “Therapeutic benefit,” and “Non-healthcare costs” received one opposing vote; the “Expert consensus” criterion was supported by eight out of eleven participants. After a brief debate, participants agreed to relocate the domain “Type of benefit” and its corresponding criteria (“Preventive benefit” and “Therapeutic outcome”) as a criterion within the “Outcome of the intervention” domain.

The subcriteria that did not receive 100 percent of the votes from the attendees were “Unmet needs in HRQoL,” “Change in intermediate outcomes,” and “Change in HRQoL” (one opposing vote each), “Change in convenience” (three opposing votes), and “Unmet needs in convenience” (four opposing votes).

It was understood that all criteria and subcriteria were validated by the participants in the meeting, with the clarifications provided. The final criteria are as shown in Table 1.

Weighting of the criteria

Table 2 presents the mean weights, accompanied by their standard deviation, for all the domains, criteria, and subcriteria, obtained from each sample. In both cases, the same three domains receive the highest weightings. “Need for intervention” occupies the top position, with a weight of 28.1 percent in the general population subsample and 23.7 percent in the healthcare professionals’ sample. The domain “Intervention outcomes” is ranked second (24.6 and 23.1 percent, respectively), and the third domain is “Knowledge about the intervention” (19.0 and 19.5 percent). In the general population subsample, the fourth-ranking domain is “Feasibility” (14.5 percent). Conversely, healthcare professionals place the domain “Impact on the economy” in fourth position (18.5 percent).

Table 2. Weights of the domains, criteria and subcriteria from the two subsamples

Source: Own elaboration. p-values corresponding to the t-test.

The average weight assigned by the general population is higher than that given by healthcare professionals for the first two domains, and lower for the remaining three domains. However, statistically significant differences in mean weights between the two subsamples are observed only in the domain “Economic impact” (p = 0.007).

Regarding the criteria, nine of them receive higher weights from the general population than from healthcare professionals, while six receive lower weights. Nevertheless, statistically significant differences (at the 95 percent confidence level) between the means of the two groups are found only in one criterion of the first domain (“Affected population”) and in two criteria of domain IV (“Non-medical costs” and “Opportunity costs and budget impact”). Lastly, none of the fifteen subcriteria exhibit significantly different weights between the means of the two subsamples.Footnote 1

The analysis of the distribution of absolute frequencies from the combined sample set (N = 529) suggests a greater dispersion of scores in the first two domains compared to the rest, particularly the last two domains. The medians of the scores decrease as one progresses through the domains. The median for the “Need for intervention” domain is 25, followed by 20 for the “Outcomes of the intervention” and “Knowledge of the intervention” domains, and finally 10 for the “Economic impact” and “Feasibility” domains.

Differentiating between the two samples, histograms in Figure 1 confirm the higher concentration of weights assigned by the sample of health professionals within a narrower range, typically not exceeding 30, compared to the general population sample, which exhibits a more skewed distribution spreading to the right.

Figure 1. Histograms of the domains’ weights from each subsample.

In Figure 2, it is evident that the dispersion is significantly higher in the general population sample, although the medians, with the exception of the “Economic Impact” domain and, to a lesser extent, “Feasibility” are very similar. This greater homogeneity of the responses from the health professionals sample extends broadly when comparing the scores assigned to the criteria and subcriteria, as shown in Table 2.

Figure 2. Weights assigned to the domains by each subsample.

The different nature of the preferences and the significant difference in sample sizes between the two surveys make it impractical to integrate them into a single population to derive a measure of central tendency for establishing the weights. Combining the two samples would inevitably introduce bias toward social preferences, as they represent more than ninety-three percent of the total respondents. Therefore, we propose taking the average of the means obtained in the two samples for each item, that is, an equal-weighted sum of the mean weights from each subsample. By doing so, the resulting weights offer a more appropriate synthesis of both perspectives. These weights, rounded to the nearest integer, are presented in Table 3.

Table 3. Weights (%) of domains, criteria, and subcriteria for the MCDA

Source: Own elaboration. The weights have been calculated as the average of the means of the two subsamples.

Once the high-impact technology has been valued, by assigning a score to each of the criteria and subcriteria, which falls outside the scope of this article, these scores should be combined with the weights in Table 3 as follows:

$$ V=\sum \limits_{i=1}^5\sum \limits_{j=1}^{15}\sum \limits_{k=1}^{15}\left\{\left({w}_i{S}_i\right)\bullet \left({w}_j{S}_j\right)\bullet \left({w}_k{S}_k\right)\right\} $$

In the formula, i, j, and k represent the domains, criteria, and subcriteria of the analysis framework, respectively. The weightings from Table 3 are denoted as $ {w}_i $ , $ {w}_j $ , and $ {w}_k $ , representing the weights normalized to a total of one. $ {S}_i $ , $ {S}_j $ , and $ {S}_k $ represent the scores assigned by the decision makers to each domain, criterion, and subcriterion of the respective technology being evaluated.

Discussion

This article develops an MCDA framework for the evaluation of high-impact health technologies in a Spanish Regional Health Service. A multi-attribute function has been developed capable of generating a composite measure to assess the benefits and costs of high-impact health interventions, based on the preferences of healthcare professionals and the general population.

Out of the five domains, “Need for intervention” and “Outcomes of the intervention” are the most highly weighted by both samples. “Affected population,” “Disease severity,” and “Quality of the evidence” ranked at the top among the 15 criteria, a result which is in line with other studies (Reference Castro, Goetghebeur and Moreno-Mattar44Reference Mirelman, Mentzakis, Kinter, Paolucci, Fordham and Ozawa46). While it is true that the first two mentioned domains absorb a 50 percent of the total value of the weighting function, the results also suggest that participants exhibit a certain tendency to distribute points equally between criteria and between subcriteria. This pattern resembles, in some respect, the so-called equalizing bias (i.e., the tendency of decision makers to assign the same weight to different attributes), which seems to affect particularly in point allocation rules, though the bias is less acute under a hierarchical structuring of the decision problem, such as the format used in our study (Reference Rezaei, Arab and Mehregan47). There seems to be also a tendency to use round numbers, which is common in this type of point allocation exercise (Reference Honda, Kagawa and Shirasuna48).

Although a remarkable coincidence exists between the weights from the general population and those from the decision makers, some differences arise. First, healthcare professionals give more importance to the economic aspects of the intervention, which coincides with the results of previous studies (Reference Caro, Valcárcel and Olry49;Reference Sommers, Dorr-Goold, McGlynn, Pearson and Danis50). Professionals assigned a weight to the domain “Economic impact” that is 4.5 points higher than the weight assigned by the general population. One possible explanation is that professionals are more aware of the budget constraint and, consequently, more sensitive to the costs of interventions and their economic impact in general.

Another interesting finding is that the dispersion of the weights of the domains is significantly higher in the general population sample than among the decision makers, although the medians turned to be very similar, with the exception of the “Economic Impact.” This greater homogeneity of the responses provided by healthcare professionals seems a logical result, given that, firstly, the shared characteristics among members of this sample (employment status, level of education), as well as the presumably narrower age range it contains, make it more homogeneous. Secondly, it can be assumed that professionals may have more solidly formed opinions, and are therefore less prone to variability. Added to this is the disparate sample size of both groups of respondents, which may also help explain the differences in the degree of dispersion of the responses.

A controversial methodological issue has to do with the inclusion of cost-related attributes among the criteria. There are theoretical arguments for and against (Reference Marsh, Ijzerman, Thokala, Baltussen, Boysen and Kaló18). It has been argued that the aim of MCDA is to create a composite score of benefit, being the main question to be answered how much money should be spent for one unit of that composite score (Reference Claxton51). Some researchers considered as unrealistic to assume that individuals can derive value functions for all criteria including costs and provide weights for the value function of costs in relation to that of the other criteria (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37). Regarding cost-effectiveness, specifically, it has been recommended not to include it, from a technical perspective, since it is already a composite of costs and benefits (Reference Wahlster, Goetghebeur, Kriza and Niederländer17). One could assume, even, that the cost-effectiveness criterion, in some way, is implicitly included within the “intervention outcomes” domain (Reference Porter52).

On the other hand, advocates of including costs argue that, by doing so, respondents explicitly make trade-offs between costs and the rest of the criteria, making explicit their contribution throughout the entire decision-making process (Reference Rutten-Van Mölken, Leijten, Hoedemakers, Tsiachristas, Verbeek and Karimi53). In a review of MCDA studies to support health technology assessment (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37), eighty percent of the studies included costs, and fifty-seven percent included cost-effectiveness, as criteria in the value measurement model. Another systematic review of criteria and scoring functions (Reference Zelei, Mendola, Elezbawy, Némeh and Campbell54) found that cost-related criteria were considered in more than fifty percent of the selected studies. In our study, we opted for including cost-related criteria in the MCDA framework, as it is the case in some recent studies (Reference Caro, Valcárcel and Olry49;Reference Campolina, Estevez-Diz, Abe and de Soárez55).

Incorporating the perspectives of various stakeholders is a fundamental aspect of MCDA. Stakeholder engagement ensures that the evaluation process reflects the values, concerns, and preferences of patients, healthcare professionals, payers, and policy makers, thereby fostering transparency, legitimacy, and acceptance of the final decision. Our study, as the Belgian framework (Reference Cleemput, Devriese, Kohn, Devos, van Til and Groothuis-Oudshoorn20), and in contrast to most examples in literature, incorporates the general population in the weighting stage, which is in line with the purpose of the MCDA scheme that has been designed, that is, the incorporation of high-impact technologies into the public system. We think this is one of the strengths of the study, although we acknowledge as a potential limitation of the design the omission of incorporating the perspective of the general population (or the patients’ perspective) in the initial phase of criterion identification.

Despite its advantages, MCDA faces certain challenges and limitations, and our study is no stranger to these. The selection and weighting of criteria can be subjective, leading to potential biases in decision outcomes, and this could be somehow present in our results. Particularly, the method chosen for weighting the criteria, namely, the 100-points allocation procedure, has been regarded as a more prone to framing bias, as criteria and their performance ranges are not explicitly traded off (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37). Nevertheless, when choosing a method for weighting, time and resources required, as well as cognitive burden imposed to participants should also be considered (Reference De Montis, De Toro, Droste-Franke, Omann, Sagl, Getzner, Spash and Stagl56). The method we chose has the advantage of its simplicity and understandability, and it has been successfully used in previous studies (Reference Zozaya, Arrizubieta, Bollo, Castellví, Espín and Ortego57).

On the other hand, the advisability of incorporating a deliberative component into any quantitative MCDA has been suggested (Reference Baltussen, Marsh, Thokala, Diaby, Castro and Cleenput37), allowing the decision-making body to carry out a flexible interpretation of the results. This is the spirit that guides the proposal, not that of providing a rigid framework where the score obtained with the multi-attribute function becomes the sole input to consider in the decision-making process.

Finally, validation of the proposed framework would require its application in order to detect possible shortcomings or dysfunctions that could become apparent at the time of its use for the evaluation of a specific intervention or technology. The availability and reliability of data for all criteria could pose practical difficulties. And furthermore, interpreting and communicating the results of MCDA to diverse stakeholders can be complex, demanding effective communication strategies.

Future research, afterwards the framework has been used for a time, could check whether it has indeed been useful for decision makers of the regional health service. A reassessment of its suitability should be done periodically and, depending on its success for making better decisions, to transfer to other instances.

Conclusions

Multi-Criteria Decision Analysis constitutes a valuable approach to systematically and transparently support decision making, enabling a comprehensive evaluation of healthcare technologies based on various criteria. This article presents a multicriteria decision scheme to guide the purchasing decisions of new high-impact technologies in a Spanish regional health service where, currently, no formal procedure with objective criteria exists for adopting such decisions. The development of the scheme has considered, in its different phases, the preferences of managers, healthcare professionals, and the general population. Although the contributions of the former have shown a higher degree of consistency and lower dispersion than the preferences of the general population, no significant discrepancies have been detected in how criteria are prioritized between the two groups. The result is a multi-attribute function capable of generating a composite measure to assess the costs and benefits of high-impact interventions, with “need for intervention” and “outcomes of the intervention” emerging as the most relevant domains or attributes. Implementing this framework in a specific decision context would provide valuable information about the effectiveness of this tool in informing priority setting in resource allocation within the regional health system.

Supplementary material

The supplementary material for this article can be found at http://doi.org/10.1017/S0266462324000205.

Acknowledgments

This research received funding from the Spanish State Research Agency (FIS, JMA, JEM, Grant PID2019-104907 GBI00 funded by MCIN/AEI/10.13039/501100011033), and from the Regional Health Ministry of the Autonomous Community of Murcia, Spain.

Competing interest

The authors declare no competing interests exist.

Footnotes

1 When the Mann–Whitney–Wilcoxon test is employed, the statistically significant differences extend to the subcriteria Impact on HRQoL (p = 0.034), Impact on life expectancy (p = 0.034), Change in prevalence (p = 0.043), and Unmet needs in effectiveness (p = 0.043).

References

Baltagi, BH, Lagravinese, R, Moscone, F, Tosetti, E. Health care expenditure and income: A global perspective. Health Econ. 2017;26:863874.CrossRefGoogle ScholarPubMed
Dormont, B, Grignon, M, Huber, H. Health expenditure growth: Reassessing the threat of ageing. Health Econ. 2006;15:947963.CrossRefGoogle ScholarPubMed
Howdon, D, Rice, N. Health care expenditures, age, proximity to death and morbidity: Implications for an ageing population. J Health Econ. 2018;57:6074.CrossRefGoogle ScholarPubMed
Payne, G, Laporte, A, Deber, R, Coyte, PC. Counting backward to health care’s future: Using time-to-death modelling to identify changes in end-of-life morbidity and the impact of aging on health care expenditures. Milbank Q. 2007;85:213257.CrossRefGoogle ScholarPubMed
Smith, S, Newhouse, J, Freeland, M. Income, insurance, and technology: Why does health spending outpace economic growth? Health Aff. 2009;28:12761284.CrossRefGoogle ScholarPubMed
Zweifel, P, Steinmann, L, Eugster, P. The Sisyphus syndrome in health revisited. Int J Health Care Finance Econ. 2005;5:127145.CrossRefGoogle Scholar
OECD. New health technologies: Managing access, value and sustainability. Paris: OECD Publishing; 2011.Google Scholar
Schmets, G, Rajan, D, Kadandale, S, editors. Strategizing national health in the 21st century: a handbook. Geneva: World Health Organization; 2016.Google Scholar
Oortwijn, W, Sampietro-Colom, L, Habens, F. Developments in value frameworks to inform the allocation of healthcare resources. Int J Technol Assess Health Care. 2017;33:323329.CrossRefGoogle ScholarPubMed
NICE (National Institute for Health and Care Excellence). Guide to the methods of technology appraisal; 2013. Available from: https://www.nice.org.uk/process/pmg9.Google Scholar
Toumi, M, Remuzat, C, El Hammi, E, Millier, A, Aballéa, S, Chouaid, C, et al. Current process and future path for health economic assessment of pharmaceuticals in France. J Mark Access Health Pol. 2015;3:27902.CrossRefGoogle ScholarPubMed
Lauenroth, VD, Stargardt, T. Pharmaceutical pricing in Germany: how is value determined within the scope of AMNOG? Value Health. 2017;20:927935.CrossRefGoogle Scholar
Okunade, AA, Murthy, VNR. Technology as a ‘major driver’ of health care costs: A cointegration analysis of the Newhouse conjecture. J Health Econ. 2002;21:147159.CrossRefGoogle Scholar
Oliveira Martins, J, de la Maisonneuve, C. The Drivers of Public Expenditure on Health and Long-Term Care: An Integrated Approach. OECD Economic Studies No 43, 2006/2.CrossRefGoogle Scholar
Willemé, P, Dumont, M. Machines that go ‘ping’: Medical technology and health expenditures in the OECD countries. Health Econ. 2014;24:10271041; Corrected and republished from: Health Econ. 2015;24:387-388.CrossRefGoogle ScholarPubMed
Baltussen, R, Niessen, L. Priority setting of health interventions: the need for multi-criteria decision analysis. Cost Eff Resour Alloc. 2006;4:14.CrossRefGoogle ScholarPubMed
Wahlster, P, Goetghebeur, M, Kriza, C, Niederländer, C, Kolominsky-Rabas P and on behalf of the National Leading-Edge Cluster Medical Technologies ‘Medical Valley EMN’ Balancing costs and benefits at different stages of medical innovation: A systematic review of Multi-criteria decision analysis (MCDA). BMC Health Serv Res. 2015;15:262.CrossRefGoogle Scholar
Marsh, K, Ijzerman, M, Thokala, P, Baltussen, R, Boysen, M, Kaló, Z, et al. Multiple criteria decision analysis for health care decision making—Emerging good practices: Report 2 of the ISPOR MCDA emerging good practices task force. Value Health. 2016;19:125137.CrossRefGoogle ScholarPubMed
Devlin, N, Sussex, J. Incorporating multiple criteria in HTA. Methods and processes. London: Office of Health Economics; 2011.Google Scholar
Cleemput, I, Devriese, S, Kohn, L, Devos, C, van Til, J, Groothuis-Oudshoorn, K, et al. Incorporating societal preferences in reimbursement decisions - relative importance of decision criteria according to Belgian citizens. KCE reports. Brussels: Belgian Health Care Knowledge Centre (KCE); 2014.Google Scholar
Keeny, RL, Raiffa, H. Decisions with multiple objectives. Preferences and value trade-offs. Cambridge, UK: Cambridge University Press; 1993.CrossRefGoogle Scholar
Campillo-Artero, C, Puig-Junoy, J, Culyer, A. Does MCDA trump CEA? Appl Health Econ Health Policy. 2018;16(2):147151.CrossRefGoogle ScholarPubMed
Thokala, P, Devlin, N, Marsh, K, Baltussen, R, Boysen, M, Kalo, Z, Longrenn, T, Mussen, F, Peacock, S, Watkins, J, Ijzerman, M. Multiple criteria decision analysis for health care decision making—An introduction: Report 1 of the ISPOR MCDA emerging good practices task force. Value Health. 2016;19:113.CrossRefGoogle ScholarPubMed
Glaize, A, Duenas, A, Di Martinelly, C, Fagnot, I. Healthcare decision-making applications using multicriteria decision analysis. A scoping review. J Multi-Crit Decis Anal. 2019;26:6283.CrossRefGoogle Scholar
Husereau, D, Boucher, M, Noorani, H. Priority setting for health technology assessment at CADTH. Int J Technol Assess Health Care. 2010;26:341347.CrossRefGoogle ScholarPubMed
Danner, M, Hummel, JM, Volz, F, van Manen, JG, Wiegard, B, Dintsios, CM, et al. Integrating patients’ views into health technology assessment: Analytic hierarchy process (AHP) as a method to elicit patient preferences. Int J Technol Assess Health Care. 2011;27:369375.CrossRefGoogle ScholarPubMed
Sussex, J, Rollet, P, Garau, M, Schmitt, C, Kent, A, Hutchings, A. Multi-criteria decision analysis to value orphan medicines. Office of Health Economics. 2013; Research paper 13/03.CrossRefGoogle Scholar
Gilabert-Perramon, A, Torrent-Farnell, J, Catalan, A, Prat, A, Fontanet, M, Puig-Peiró, R, et al. Drug evaluation and decision making in Catalonia: development and validation of a methodological framework based on multi-criteria decision analysis (MCDA) for orphan drugs. Int J Technol Assess Health Care. 2017;33:111120.CrossRefGoogle ScholarPubMed
Phillips, LD, Fasolo, B, Zafiropoulos, N, Beyer, A. Is quantitative benefit risk modeling of drugs desirable or possible? Drug Discovery Today Technol. 2011;8:e310.CrossRefGoogle Scholar
Dolan, JG. Medical decision making using the analytic hierarchy process: choice of initial antimicrobial therapy for acute pyelonephritis. Med Decis Making. 1989;9:5156.CrossRefGoogle ScholarPubMed
Dolan, JG. Shared decision-making–transferring research into practice: The analytic hierarchy process (AHP). Patient Educ Couns. 2008;73:418425.CrossRefGoogle ScholarPubMed
van Til, JA, Renzenbrink, GJ, Dolan, JG, Ijzerman, MJ. The use of the analytic hierarchy process to aid decisión making in acquired equinovarus deformity. Arch Phys Med Rehabil. 2008;89:457462.CrossRefGoogle ScholarPubMed
Pecchia, L, Martin, JL, Ragozzino, A, Vanzanella, C, Scognamiglio, A, Mirarchi, L, et al. User needs elicitation via analytic hierarchy process (AHP). A case study on a Computed Tomography (CT) scanner. BMC Med Inform Decis Mak. 2013;13:2.CrossRefGoogle ScholarPubMed
Goetghebeur, MM, Wagner, M, Khoury, H, et al. Evidence and value: Impact on decision making–The EVIDEM framework and potential applications. BMC Health Serv Res. 2008;8:270.CrossRefGoogle Scholar
Marsh, K, Dolan, P, Kempster, J, Lugon, M. Prioritizing investments in public health: A multi-criteria decisión analysis. J Public Health. 2013;35:460466.CrossRefGoogle ScholarPubMed
Márquez-Peláez, S, Espín Balbino, J, Olry de Labry Lima, A, Benítez Hidalgo, V, y grupo de trabajo RedETS paran MCDA. Guía para la elaboración de recomendaciones basada en análisis de decisión multicriterio. Sevilla: AETSA, Evaluación de Tecnologías Sanitarias de Andalucía. Madrid: Red Española de Agencias de Evaluación de Tecnologías Sanitarias; 2020.Google Scholar
Baltussen, R, Marsh, K, Thokala, P, Diaby, V, Castro, H, Cleenput, I, et al. Multicriteria decision analysis to support health technology assessment agencies: Benefits, limitations and the way forward. Value Health. 2019; 22:12831288.CrossRefGoogle ScholarPubMed
Marsh, K, Goetghebeur, M, Thokala, P, Baltussen, R. Multi-criteria decision analysis to support healthcare decisions. New York: Springer; 2017.CrossRefGoogle Scholar
Marsh, K, Lanitis, T, Neasham, D, Orfanos, P, Caro, J. Assessing the value of healthcare interventions using multi-criteria decision analysis: A review of the literature. PharmacoEconomics. 2014;32:345365.CrossRefGoogle ScholarPubMed
Broekhuuizen, H, Groothuis-Oudshoom, CGM, van Til, JA, Hummel, JM, Ijzerman, MJ. A review and classification of approaches for dealing with uncertainty in multi-criteria decision analysis for healthcare decisions. Pharmacoeconomics. 2015;33:44555.CrossRefGoogle Scholar
EVIDEM Collaboration. Concept & definitions (v4.0). 10th Edition; 2017.Google Scholar
Goetghebeur, M, Wagner, M, Khoury, H, Rindress, D, Grégoire, JP, Deal, C. Combining multi-criteria decisión analysis, ethics and health technology assessment: applying the EVIDEM framework decision making framework to growth hormone for Turner syndrome patients. Cost Effec Resourc Alloc. 2010;8:4.CrossRefGoogle Scholar
Polain, M, Franken, M, Koopmanschap, M, Cleemput, I. Drug reimbursement systems: International comparison and policy recommendations. Brussels: Belgian Health Care Knowledge Centre (KCE); 2010.Google Scholar
Castro, HE, Goetghebeur, M, Moreno-Mattar, O. testing multi-criteria decision analysis for more transparent resource-allocation decision making in Colombia. Int J Technol Assess Health Care. 2016;32:307314.CrossRefGoogle Scholar
Iskrov, G, Stefanov, R. Criteria for drug reimbursement decision-making: An emerging public health challenge in Bulgaria. Balkan Med J. 2016;33(1):2735.CrossRefGoogle ScholarPubMed
Mirelman, A, Mentzakis, E, Kinter, E, Paolucci, F, Fordham, R, Ozawa, S, et al. Decision-making criteria among national policy makers in five countries: A discrete choice experiment eliciting relative preferences for equity and efficiency. Value Health. 2012;15:534539.CrossRefGoogle ScholarPubMed
Rezaei, J, Arab, A, Mehregan, M. Equalizing bias in eliciting attribute weights in multiattribute decision-making: experimental research. J Behav Decis Mak. 2022;35:e2262.CrossRefGoogle Scholar
Honda, H, Kagawa, R, Shirasuna, M. On the round number bias and wisdom of crowds in different response formats for numerical estimation. Sci Rep. 2022;12:8167.CrossRefGoogle ScholarPubMed
Caro, A, Valcárcel, MC, Olry, A. Valor de la hemodiálisis concertada y la hospitalaria mediante un análisis de decisión multicriterio. Nefrología. 2022;43:742749. https://doi.org/10.1016/j.nefro.2022.08.004.CrossRefGoogle Scholar
Sommers, R, Dorr-Goold, S, McGlynn, EA, Pearson, SD, Danis, M. Focus groups highlight that many patients object to clinician’s focusing on costs. Health Aff. 2013;32(2):338346.CrossRefGoogle ScholarPubMed
Claxton, K. Three questions to ask when examining MCDA. Value Outcomes Spotlight. 2015;January/February:18-20.Google Scholar
Porter, ME. What is value in health care. N Engl J Med. 2010;363:24772481.CrossRefGoogle ScholarPubMed
Rutten-Van Mölken, M, Leijten, F, Hoedemakers, M, Tsiachristas, A, Verbeek, N, Karimi, M, et al. Strengthening the evidence-vase of integrated care for people with multi-morbidity in Europe using Multi-Criteria Decision Analysis (MCDA). BMC Health Serv Res. 2018;18:576.CrossRefGoogle ScholarPubMed
Zelei, T, Mendola, ND, Elezbawy, B, Némeh, B, Campbell, JD. Criteria and scoring functions used in multi-criteria decision analysis and value frameworks for the assessment of rare disease therapies: A systematic literature review. Pharmacoeconomics Open. 2021;5:605612.CrossRefGoogle ScholarPubMed
Campolina, AG, Estevez-Diz, MDP, Abe, JM, de Soárez, PC. Multiple criteria decision analysis (MCDA) for evaluating cancer treatments in hospital-based health technology assessment: The paraconsistent value framework. PLoS One. 2022;17:e0268584.CrossRefGoogle ScholarPubMed
De Montis, A, De Toro, P, Droste-Franke, B, Omann, I, Sagl, S. Assessing the quality of different MCDA methods. In: Getzner, M, Spash, C, Stagl, S, editors. Alternatives for environmental valuation. London, UK: Routledge; 2004.Google Scholar
Zozaya, N, Arrizubieta, MI, Bollo, E, Castellví, I, Espín, J, Ortego, N, et al. A multi-criteria decision analysis on the value of nintedanib for interstitial lung diseases. Int J Technol Assess Health Care. 2022;38:e64.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Criteria of the MCDA resulting from the focus group

Figure 1

Table 2. Weights of the domains, criteria and subcriteria from the two subsamples

Figure 2

Figure 1. Histograms of the domains’ weights from each subsample.

Figure 3

Figure 2. Weights assigned to the domains by each subsample.

Figure 4

Table 3. Weights (%) of domains, criteria, and subcriteria for the MCDA

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