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HEALTH TECHNOLOGY ASSESSMENT METHODS GUIDELINES FOR MEDICAL DEVICES: HOW CAN WE ADDRESS THE GAPS? THE INTERNATIONAL FEDERATION OF MEDICAL AND BIOLOGICAL ENGINEERING PERSPECTIVE

Part of: Special Collection - Methods

Published online by Cambridge University Press:  18 June 2018

Julie Polisena ,
Rossana Castaldo ,
Oriana Ciani ,
Carlo Federici ,
Simone Borsci ,
Matteo Ritrovato ,
Daniel Clark  and
Leandro Pecchia
Julie Polisena
Affiliation:
CADTH, Ottawajuliep@cadth.ca
Rossana Castaldo
Affiliation:
School of Engineering, University of Warwick
Oriana Ciani
Affiliation:
Centre for Research on Health and Social Care Management (CeRGAS), SDA Bocconi University; Evidence Synthesis and Modeling for Health Improvement, University of Exeter Medical School
Carlo Federici
Affiliation:
School of Engineering, University of Warwick; Centre for Research on Health and Social Care Management (CeRGAS), SDA Bocconi University
Simone Borsci
Affiliation:
Department of Cognitive Psychology and Ergonomics, University of Twente
Matteo Ritrovato
Affiliation:
HTA Unit, Bambino Gesù Children's Hospital
Daniel Clark
Affiliation:
Clinical Engineering, Nottingham University Hospitals NHS Trust
Leandro Pecchia
Affiliation:
School of Engineering, University of Warwick; Health Technology Assessment Division, International Federation of Medical and Biological Engineering
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Abstract

Objectives:

Current health technology assessment (HTA) methods guidelines for medical devices may benefit from contributions by biomedical and clinical engineers. Our study aims to: (i) review and identify gaps in the current HTA guidelines on medical devices, (ii) propose recommendations to optimize the impact of HTA for medical devices, and (iii) reach a consensus among biomedical engineers on these recommendations.

Methods:

A gray literature search of HTA agency Web sites for assessment methods guidelines on devices was conducted. The International Federation of Medical and Biological Engineers (IFMBE) then convened a structured focus group, with experts from different fields, to identify potential gaps in the current HTA guidelines, and to develop recommendations to fill these perceived gaps. The thirty recommendations generated from the focus group were circulated in a Delphi survey to eighty-five biomedical and clinical engineers.

Results:

Thirty-two panelists, from seventeen countries, participated in the Delphi survey. The responses showed a strong agreement on twenty-seven of thirty recommendations. Some uncertainties remain about the methods to accurately assess the effectiveness and safety, and interoperability of a medical device with other devices or within the clinical setting.

Conclusions:

As medical devices differ from drug therapies, current HTA methods may not accurately reflect the conclusions of their assessment. Recommendations informed by the focus group discussions and Delphi survey responses aimed to address the perceived gaps, and to provide a more integrated approach in medical device assessments in combining engineering with other perspectives, such as clinical, economic, patient, human factors, ethical, and environmental.

Keywords

Medical deviceHealth technology assessmentGuidelinesClinical and biomedical engineering
Type
Method
Information
International Journal of Technology Assessment in Health Care , Volume 34 , Issue 3 , 2018 , pp. 276 - 289
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 in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2018

The World Health Organization describes medical devices (MDs) as essential tools for prevention, diagnosis and treatment of illnesses and diseases, and patient rehabilitations (1). The European Parliament and Council of the European Union defines a MD as “any instrument, apparatus, appliance, software, implant, reagent, material or other article intended by the manufacturer to be used, alone or in combination, for human beings” (2). Furthermore, they are used for different purposes such as diagnosis, prevention, monitoring, prediction, prognosis, treatment, alleviation, or compensation of disease, injury, or disability (2). Moreover, the U.S. Food and Drug Administration specifies that MDs are “intended to affect the structure or any function of the body of man or other animals, and which does not achieve any of its primary intended purposes through chemical action within or on the body of man or other animals and which is not dependent upon being metabolized for the achievement of any of its primary intended purposes” (Reference Maisel3).

There are important differences between drug therapies and medical devices. These differences can impact health technology assessment (HTA) methods and can be grouped into five categories: product lifecycle, clinical evaluation, user issues, costs and economic evaluation, and intellectual property (Reference Pecchia, Craven and Long4). This diversity among drugs and MDs results in different assessment needs, evaluation criteria, and approaches.

The perspective of clinical and biomedical engineers is particularly relevant in the assessment of MDs and, given the drug-oriented development of HTA methods and processes in the past decades, it is unlikely to be addressed in many HTA guidelines (Reference Ciani, Wilcher and Blankart5). Some HTA agencies or networks have developed guidelines specific to MDs and diagnostics (6Reference Tarricone, Torbica and Drummond11) (Supplementary Table 1). However, it remains uncertain whether these guidelines considered all the unique features of MDs as relevant for the clinical and biomedical engineers’ community.

In 2017, Schnell-Inderst et al. (Reference Schnell-Inderst, Hunger, Conrads-Frank, Arvandi and Siebert12) developed recommendations for the planning and conduct of systematic reviews of therapeutic MDs. A targeted literature review of methodological publications and guidelines on the design, conduct, analysis, and reporting of primary studies on the clinical evaluation of therapeutic MDs and surgical procedures was performed (Reference Schnell-Inderst, Hunger, Conrads-Frank, Arvandi and Siebert12). The recommendations were based primarily on the information from the literature review, judgement and experience of the authors, and discussions with their project partners at MedTech and the European Network for Health Technology Assessment (EUnetHTA) (Reference Schnell-Inderst, Hunger, Conrads-Frank, Arvandi and Siebert12). The authors highlighted the necessity to define the intervention and describe the technical characteristics and to identify and measure the potential effect modifiers, such as the incremental development of the device, the experience and learning curve of the user, and contextual factors (Reference Schnell-Inderst, Hunger, Conrads-Frank, Arvandi and Siebert12).

The involvement of biomedical and clinical engineers in HTA can provide insights on the technical characteristics, usability, safety, user setting dependences, organizational impact, and maintenance of devices throughout their lifecycle (1315). In a 2013 study, Margotti et al. interviewed clinical engineers, healthcare providers, and managers in four public hospitals in Brazil to inquire about their perspectives on the decision making process in acquiring new medical equipment, HTA, and the identification of aspects to guide HTA in their institutions. Based on the participants’ responses, the authors concluded that the decision making process to introduce a new medical equipment was not based on evidence, and therefore, recommended that the hospitals should establish a formal HTA process that would involve clinical engineers to integrate medical equipment in the hospitals. The HTA process would be separate from a technical evaluation for procurement decisions (Reference Margotti, Santos and Garcia16).

In November 2016, as part of the 2015–18 HTA program, the International Federation of Medical and Biological Engineers (IFMBE)-HTA Division held a focus group to contextualize the differences between MDs and drugs and their impact on HTA. The study objectives were to: (i) review and identify the gaps in the current HTA guidelines on MDs; (ii) propose recommendations (Reference Pecchia, Craven and Long4) to improve the accuracy of MD assessments and compare current HTA MD guidelines with the proposed recommendations; and (iii) to reach a consensus among clinical and biomedical engineers on the proposed recommendations with a modified Delphi survey.

METHODS

We conducted a structured focus group to review and identify the gaps in HTA guidelines for MDs, and we developed a modified Delphi survey to establish consensus within the community of biomedical and clinical engineers on the recommendations proposed to address the perceived gaps. The study received full ethics approval by University of Warwick Ethical BSREC Committee (REGO-2017-2072).

Focus Group

Health Technology Guidelines

Guidelines were obtained from a limited gray literature search of HTA agency Web sites and from contributions among the study investigators (7Reference Tarricone, Torbica and Drummond11). They were identified through a focused Internet search on HTA organizations and research initiatives up until May 2018. These searches were supplemented by reviewing the bibliographies of the guidelines and through contacts with appropriate experts and manufacturers. HTA guidelines were selected for inclusion if they were specific to any type of MD and described methods to evaluate medical technology. Guidelines that presented solely the clinical review methods, were focused on HTA processes only, or were not explicit about the appropriate methods for medical device assessments were excluded.

Six HTA guidelines (6Reference Tarricone, Torbica and Drummond11), published from 2011 (7) to 2018 (10), were selected for inclusion in the review. A standardized data extraction form was designed a priori to document and tabulate all relevant information from the included guidelines. One investigator (J.P.) extracted information for each HTA component in the guidelines, and a second investigator (R.C.) reviewed the extracted information. Another investigator (L.P.) prepared a table to extract the relevant information from the guidelines (Reference Pecchia17). Accordingly, the description of how HTA guidelines addressed the product lifecycle, clinical evaluation, user issues, and costs and economic evaluation for medical devices were extracted.

A narrative summary of the HTA methods described in the guidelines was performed. The methods described in the HTA guidelines were contrasted with the proposed recommendations developed by the focus group to determine which recommendations were addressed in full or partially in the existing guidelines and which ones were not addressed at all.

Focus Group Discussions

Fifteen members and collaborators of the IFMBE were invited for a 2-day structured focus group which was convened between November 26 and 27, 2016 at the School of Engineering at the University of Warwick. A second focus group was convened at the European Medical and Biological Engineering and North-Baltic Conference on Biomedical Engineering and Medical Conference on June 16, 2017, in Tampere, Finland, to finalize the recommendations. Focus group participants comprised of: biomedical and clinical engineers, human factors experts, health economists, and epidemiologists, all with experience in HTAs. The focus group was coordinated by the Chair of the IFMBE-HTA Division.

The aims of the focus group were to: (i) contextualize the differences between MD and drugs in terms of their characteristics and functionality (18;19); (ii) review and expand the list of the main differences between MD and drugs that can impact the HTA methods identified in previous studies (Reference Pecchia, Craven and Long4); and (iii) develop a set of recommendations to fill any identified gap on HTA guidelines to assess MDs.

Using the narrative summary of the guidelines, the focus group discussed and developed an initial set of recommendations. These initial recommendations were then mapped onto the European Network for Health Technology Assessment (EUnetHTA) (Reference Pecchia, Craven and Long4) domains (i.e., health problem and current use of the technology, description and technical characteristics of technology, safety, clinical effectiveness, costs and economic evaluation, ethical analysis, organizational aspects, patients, social, and legal aspects).

Delphi Survey

Survey Design

The Delphi method is a process that uses a series of rounds of questionnaires to gather information in a structured manner until consensus is obtained (Reference Hsu and Sandford20). For our study, we conducted an online Delphi survey. This approach enabled: (i) the anonymity of each panelist; (ii) to reach panelists from various geographic locations; and iii) to reduce the risk of one or more panelists dominating the consensus process (Reference Hsu and Sandford20Reference Thangaratinam and Redman22). The aim of the Delphi process for the present study was to obtain consensus from panelists with different perspectives and expertise, and not to achieve statistical power (Reference Okoli and Pawlowski21). In particular, the objective of the Delphi survey was to achieve consensus on the 30 recommendations proposed by the focus group to fill the perceived gaps in HTA process to evaluate MDs.

The online Delphi survey (Supplementary File 1) consisted of a demographic section and a section to inquire about the panelist's agreement level with the thirty recommendations proposed by the focus group to enhance the HTA guidelines for MDs.

Before a wider distribution, the survey was piloted among a handful of clinical and biomedical engineers to estimate the time to complete the survey, and to review the flow of interaction, coherence, and appropriateness of format and contents.

Delphi Process

We invited a purposive sample of approximately 85 international professionals through an email invitation. The panelists were identified through the IFMBE associates, study investigators’ networks, and scientific and professional societies. They were selected based on their experience with health technology assessments, including design, development, testing, implementation, selection, procurement, reimbursement, maintenance, and from various areas in the healthcare sector.

Our email invitation included a letter inviting the individual to participate, and described the study objectives, an overview of the Delphi methods, expected time to complete survey, and a link to the survey. The invitation also indicated that any information provided would have been used in a publication. If the participants were unable to participate in the Delphi process, we invited them to suggest alternates, whom they believed would have been appropriate for the study.

A 5-point Likert scale was applied, where “1” was strongly disagree and “5” was strongly agree. Median scores were calculated per recommendation to characterize the answer category above and below which 50 percent of the answers fall. Interquartile ranges (IQRs) were used to represent the spread of the data and to assess the level of consensus per recommendation. Ratings with a median of ≤ 2 (i.e., high level of disagreement with the proposed recommendation) and a narrow IQR (i.e., IQR range between 1 and 2) were considered to have reached consensus on a strong disagreement. Those with a median ≥ 4 with an IQR between 4 and 5 were considered to have reached consensus on a strong agreement with the proposed recommendation. In addition, the free text comments were assessed, especially for ratings that seem to be equivocal as they can provide some insights on the respondents’ thought process (Reference Kelly, Moher and Clifford23).

As consensus (i.e., median ≥ 4) was reached for all proposed recommendations in Round 1, another round of Delphi iterations was not conducted.

RESULTS

Focus Group

Table 1 summarizes the output of the focus group in terms of potential recommendations to improve HTA process to evaluate MDs. The table presents the proposed recommendations and their association with the EUnetHTA domains, the MD characteristics and the impact of those characteristics for the application of HTA methods. The results of the focus group discussions were organized in four main MD characteristics: product lifecycle, clinical evaluation, issues in use, costs and economic evaluation.

Table 1. MD Characteristics and Functionality, Impact on HTA Methods, Proposed Recommendations for HTA Guidelines, and Associated EUnetHTA Domains

EUnetHTA, European Network for Health Technology Assessment; HTA, health technology assessment; IEC, International Electrotechnical Commission; IEC/TR, International Electrotechnical Commission/Technical Report; ISO, International Standards Organization; MD, medical device.

Product Lifecycle

Compared with drug therapies, MDs usually have a shorter lifecycle due to iterative innovations, and the facility to overcome patient protections often results in previous generations of devices to become obsolete. One direct consequence of a shorter product lifecycle is that the evaluation of MDs at market launch usually relies on limited evidence to measure their safety, efficacy, effectiveness, and value for money. Additional items related to the medical device lifecycle include the maintenance required, potential instability of individual parts that can impact the overall performance of the device, and possible interferences with or dependency on other devices. A lack of consideration for any of these items can result in a risk of inaccurate estimates related to the efficacy, effectiveness, safety, and cost-effectiveness of the device. Some recommendations proposed to help address these perceived gaps include obtaining as much data as feasible to more accurately predict the medical device lifespan, using appropriate statistical methods to analyze the different types of evidence, understanding the maintenance requirements with validated tools (e.g., ISO and IEC standards), and conducting risk assessments and technical analyses of the minimum requirements for possible interferences with other medical devices (Table 1).

Clinical Evaluation

The use of MDs involves a longer learning curve if the design is more complex; thus, impacting the estimation of the clinical efficacy and effectiveness, safety, cost-effectiveness, and service provision of the device. To help ensure the accuracy of the estimates, it is suggested to use both pre- and postmarket and registry data that capture the impact of the learning curve on outcomes, ensure that device users receive appropriate training to reduce the risk of bias in measuring clinical efficacy and effectiveness, and apply appropriate statistical methods to incorporate the impact of the learning curve into the estimates of outcomes and costs (Table 1).

Issues in Use

Most of the guidelines reviewed did not provide any recommendations on how to identify and assess the technical requirements and logistics, setting, and training, and accreditation considerations for the user. The NICE-DAP(6) mentioned that in some instances special implementation issues and recommendations for use of a diagnostic test were identified in their reports and Health Quality Ontario (HQO) considers policies or legislation that can impact the implementation of the health technology in their jurisdiction (10). The recommendations in Table 1 indicate the need for learning curve estimations and the collection of data that reflect the setting in which the MD will be used.

Costs and Economic Evaluation

Most guidelines discussed costs and economic evaluations. The EUnetHTA guidelines focused on the methods to assess the relative clinical effectiveness of therapeutic medical devices, but did not discuss cost-effectiveness and other non-clinical benefits or harms (8). In addition to primary economic evaluations, HQO also indicated that a budget impact analyses may be included in their HTA reports, and they conduct systematic reviews of the economic evidence for the health technology (10).

Costs associated with the supply, installation, training of users, supply of consumables, maintenance, and ongoing facilities are important considerations to appropriately evaluate the budget impact and cost-effectiveness of an MD. Compared with drugs, different purchasing methods and financial schemes may be available to the payers willing to adopt a new medical device. For example, manufacturers may offer to supply infusion devices free of charge to a hospital provided that they also contract to purchase a given volume of giving sets. Such arrangements are often referred to as “consumables deals.” As well, hospitals use different ways to consolidate their purchasing demand, sometimes at the interdepartmental, inter-organizational, or system level. In European and other countries, most highly innovative MDs are reimbursed through diagnosis-related group–based payment systems, which cover expenditures of hospital providers and encourage lowering costs. Long-term tenders that procure large quantities of specific products are common and facilitate interaction with the suppliers while allowing clinicians to gain experience with the devices; however, short-term targeted contracts are also used in practice (Reference Lingg, Wyss and Duran-Arenas24,Reference Callea, Armeni, Marsilio, Jommi and Tarricone25).

Considerations of such schemes are relevant when conducting an economic evaluation (Reference Akpinar, Jacobs and Husereau26). The proposed recommendations suggest incorporating all operation costs and the appropriate financial model to acquire the device in economic evaluations and budget impact analyses. The operating costs will be different for single-use devices.

The focus group prepared a list for each of the identified ten gaps in the HTA guidelines on medical devices. These recommendations and associated gaps were used then to develop the Delphi survey (Supplementary File 1).

Delphi Survey

Characteristics of Panelists

We invited eighty-five professionals to participate in the study, and thirty-two completed the survey (37.6 percent) (Table 2). Between one to three panelists did not provide scores for several recommendations.

Table 2. Characteristics of Panelists (N = 32)

a Some panelists responded as having more than one profession.

b Other included: medical equipment assessor (n = 1), HTA senior scientist (n = 1), chemical engineer (n = 1), health technology assessment and physician n = 1).

c Other included: CE specialist (n = 1), engineer (n = 1); engineer with post-graduate in health administration (n = 1), business management (n = 1); electro-mechanical engineer from 5-year university program (n = 1).

d Other included: capital planning (n = 1), clinical engineering instructor or professor (n = 2), health technology regulator (n = 1), healthcare technology policy and methodology (n = 1).

e Other included: retired (n = 1); government (n = 3); industry trade association (n = 1), HTA public institution (n = 1), academic/government (n = 1), regulatory authority for medical devices (n = 1), healthcare provider in public sector (n = 2).

Panelist characteristics are presented in Table 2, they represented seventeen countries. They ranged from five panelists from Mexico (15.6 percent) to one each from Belgium, Chile, China, Cuba, Ecuador, Egypt, Italy, the Netherlands, Spain, and the United Kingdom. Over 25 percent of panelists were clinical engineers (n = 12; 37.5 percent) or managers (n = 9; 28.1 percent). Almost 70 percent completed graduate studies (masters: n = 10; 31.1 percent and doctorate: n = 12; 37.5 percent), and approximately 85 percent had 11 years or more of service. The majority of respondents were involved in HTA (n = 22; 68.8 percent) or health technology management (n = 18; 56.3 percent), and over 20 percent indicated an acute hospital (n = 8; 25 percent) or university (n = 7; 21.9 percent) as their principal employer.

Consensus on Recommendations

The median, the IQR, and the number of panelists for each recommendation are presented in Table 3.

Table 3. Recommendations to Address the Gaps in HTA Methods Guidelines for MDs and Delphi Survey Results

HTA, health technology assessment; IQR, interquartile range; MD, medical device.

In Round 1, most of the recommendations reached a consensus with a strong agreement (i.e., median ≥ 4 and IQR between 4 and 5). Two recommendations on the application of sensitivity analyses in economic models to assess the impact on the results of varying lifespans or incremental innovations and the processes of data exchange and on the interoperability of the device within the hospital system or with other devices had a median ≥ 4, but the IQR was between 3 and 5. As well, one recommendation centered on the appropriate methods to assess the evidence on medical device effectiveness and safety presented a median equal to 4, but with an IQR between 3 and 4.

Although the panelists agreed with the proposed recommendations, several commented on their feasibility based on the availability of high-quality evidence and questioned whether existing statistical methods and economic models used in HTAs can accurately assess the effectiveness and safety of more complex health technologies. In addition, there was some uncertainty on whether an HTA is the appropriate approach to evaluate the interoperability of a MD with other devices or within the hospital system and if a more technical assessment conducted by entities with technical expertise is warranted.

DISCUSSION

This study aimed to reach a consensus via an online Delphi survey on recommendations proposed by the IFMBE-HTA Division to address the perceived gaps in current HTA methods guidelines for MDs. The thirty-two participants were experts with numerous years of experience in the field of HTA or health technology management in an academic hospital or university.

Consensus with a strong agreement was achieved in the first round for 90 percent (27/30) of the recommendations related to the product lifecycle, clinical evaluation, issues in use, and costs and economic evaluations. For the remaining recommendations, consensus was reached but the IQR was wider (e.g., 3 to 5). Comments indicated that panelists were uncertain about the feasibility of accurately measuring the effectiveness and safety of a medical device throughout the product lifecycle given the available evidence and existing statistical methods and economic models used in HTAs. Furthermore, the appropriateness of an HTA to assess the interoperability of a medical device with other devices or within a hospital system was questioned and a more technical assessment was proposed instead.

Unlike drugs, the permission to market MDs may not be based solely on the evaluation of efficacy and safety data from randomized clinical trials. Although manufacturers must perform clinical studies on human subjects for devices labeled as high risk by the regulators, there are no explicit standards on the sample size, design, or follow-up period required (Reference Drummond, Griffin and Tarricone27Reference Sorenson, Tarricone, Siebert and Drummond29). Panelists in the Delphi survey commented that to accurately assess the effectiveness and safety of MDs, more appropriate evidence is required as well as the need for relevant statistical and economic methods to measure the outcomes.

Both participants in the focus group and the survey agree that similar to drug therapies, postmarket surveillance, and observational data are complementary to the premarket process because they can identify durability and rare serious adverse events from long-term use of the device (32). Given the important methodological issues and contextual considerations that require attention in the assessment of MDs, research initiatives are under way to address them (18,19,31Reference Sedrakyan, Campbell and Merino33).

Delphi panelists also agree with focus group results that the adoption of a medical device has a more significant impact in an organization compared with the introduction of a new drug therapy due to implementation consideration and maintenance issues for those lasting longer than single use devices. Furthermore, a medical device can have numerous applications and a shorter lifecycle, and its effectiveness is impacted by the user interaction, setting, and the learning curve to operate it (Reference Drummond, Griffin and Tarricone27Reference Sorenson, Tarricone, Siebert and Drummond29).

An important gap in HTAs identified by focus group experts and, confirmed by panelists, is the need of methods to estimate the impact of the learning curve related to the effectiveness, safety, and costs associated with the use of MDs, and relevant evidence is also lacking. Methods for the estimation of the learning curve are well-established, although these have not yet been incorporated in guidelines or used to inform postmarket data collection (Reference Ramsay, Grant and Wallace34). The incorporation of the learning curve and contextual factors into economic evaluations still represent a great challenge in MD assessments (Reference Borsci, Uchegbu and Buckle35).

In terms of risk assessment, some panelists believed that the original manufacturers of the device should be responsible for reporting risks, including the required maintenance, and provide user, technical, and maintenance training to professionals accountable for the application and maintenance of the MD.

Panelists identified value-based procurement, a process which focuses on health system performance and patient outcomes, and longer-term cost efficiencies, and working with suppliers to identify opportunities to develop innovative products and services (Reference Prada36), as a relevant forum to assess the impact of the maintenance required and financial models (e.g., leasing agreements) represented in economic evaluations because an HTA would unlikely be able to address these items in its current form.

Limitations

The interpretation and application of our study may be influenced by several limitations. The survey presented a description of each gap in the current HTA methods guidelines for medical guidelines and proposed recommendations to address them. Although none of the panelists requested further information or clarifications it is uncertain how the panelists interpreted the descriptions and the items of the survey. Some element of complexity due to the textual presentations of gaps and associated recommendations may also have pushed some respondents to drop-out of the Delphi process. Finally, the panelists represented a variety of perspectives, but it is not feasible to identify all clinical and biomedical engineering perspectives based on the number of survey respondents (n = 32).

Directions for Future Research

The recommendations put forth will help to provide a more integrated and enhanced approach to MD assessments. Based on the scores, the panelists agreed with the proposed recommendations, but remained uncertain on the feasibility for some of them, such as assessing the effectiveness and safety of a medical device in the product lifecycle based on the evidence and current statistical methods and economic models. A more technical assessment was proposed to evaluate the interoperability of a MD with other devices or within a hospital system. Future research on which proposed recommendations are more feasible for an HTA versus which ones are more suitable for a study design or technical assessment of medical device use is warranted. Another follow-up study to this research initiative would be to collaborate with HTA units at different levels in the healthcare system to assess the feasibility of implementing these recommendations based on the available data and evidence and to adapt existing or develop new methods accordingly.

In conclusion, as the MD characteristics and functionality differ from drug therapies, current HTA methods may not accurately reflect the conclusions of their assessment. Our paper presents recommendations informed by the focus group discussions and Delphi survey responses that are aimed to address the perceived gaps in the HTA guidelines and to provide a more integrated and improved approach to HTAs on MDs. They were organized into four categories: product lifecycle, clinical evaluation, issues in use, and costs and economic evaluation. According to the scores from the survey responses, consensus was achieved for all recommendations among thirty-two international panelists in one round. As there is uncertainty on the feasibility in the implementation on some of the recommendations, future research can involve an evaluation on how to implement them in an assessment based on the available data, evidence, and statistical methods, and economic models used in HTAs.

SUPPLEMENTARY MATERIAL

Supplementary Table 1: https://doi.org/10.1017/S0266462318000314

Supplementary File 1: https://doi.org/10.1017/S0266462318000314

CONFLICTS OF INTEREST

The authors have nothing to disclose.

Footnotes

Funding source: The International Federation of Medical and Biological Engineering (IFMBE) supported this study for providing financial support to organize two focus group meetings at the University of Warwick (EPSRC IAA, EP/K503848/1), United Kingdom, in November 2016 and one in Tampere, Finland, in June 2017, and to develop the Web-platform used to administrate the Delphi survey (http://htad.ifmbe.org/). The University of Warwick also provided financial support for the focus group meetings the University of Warwick with a Warwick Impact Found by means of an EPSRC IAA (EP/K503848/1). Rossana Castaldo is sponsored by the University of Warwick through an EPSRC IAA grant (EPSRC IAA, EP/R511808/1). The other authors did not receive additional funding to conduct this study. The authors acknowledge the contributions of Murilo Conto and Mladen Poluta for facilitating the distribution of the survey to their colleagues in South America and Africa, and the contributions of Marjan Hummel and Adriana Velazquez for their input in the project design, all the participants in the survey and members and collaborators of the International Federation of Medical and Biomedical Engineering Federation-Health Technology Assessment Division, who contributed to the focus group discussions.

References

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Figure 0

Table 1. MD Characteristics and Functionality, Impact on HTA Methods, Proposed Recommendations for HTA Guidelines, and Associated EUnetHTA Domains

Figure 1

Table 2. Characteristics of Panelists (N = 32)

Figure 2

Table 3. Recommendations to Address the Gaps in HTA Methods Guidelines for MDs and Delphi Survey Results

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