d Department of Paediatrics, Obstetrics and Gynaecology, Preventive Medicine, and Public Health. PhD Programme in Methodology of Biomedical Research and Public Health. Universitat Autònoma de Barcelona, Bellaterra, Spain
e Iberoamerican Cochrane Center, Biomedical Research Institute (IIB Sant Pau-CIBERESP), Barcelona, Spain
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x Cochrane Germany, Freiburg-am-Breisgau, Germany
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z Department of Medicine, University of Kansas Medical Center, Kansas City, KS, USA
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d Department of Paediatrics, Obstetrics and Gynaecology, Preventive Medicine, and Public Health. PhD Programme in Methodology of Biomedical Research and Public Health. Universitat Autònoma de Barcelona, Bellaterra, Spain
e Iberoamerican Cochrane Center, Biomedical Research Institute (IIB Sant Pau-CIBERESP), Barcelona, Spain
f Department of Internal Medicine, American University of Beirut, Beirut, Lebanon g Toronto Health Economics and Technology Assessment (THETA) Collaborative, Toronto, Ontario, Canada h National Toxicology Program, National Institute of Environmental Health Sciences, Durham, NC, USA i Department of Veterinary Integrative Biosciences, Texas A&M University, College Station, TX, USA j School of Pharmacy and Chemistry, Liverpool John Moores University, Liverpool, UKk Center for Evidence-Based Medicine and Health Outcome Research, Morsani College of Medicine, University of South Florida, Tampa, Florida, USA
l Institute for Education and Research, Hospital Moinhos de Vento, Porto Alegre, Rio Grande do Sul, Brazil
m ICF International, Durham, NC, USA n Institute of Health & Wellbeing, University of Glasgow, Glasgow, UKo Department of Immunization, Vaccines and Biologicals, World Health Organization, Geneva, Switzerland
p Clinical Epidemiology and Medical Technology Assessment, Maastricht University Medical Centre+, Maastricht, the Netherlands
q LaKind Associates, LLC, Catonsville, MD, USAr Department of Epidemiology and Public Health, University of Maryland School of Medicine, Baltimore, MD, USA
s Department of Clinical Epidemiology, Biostatistics, and Bioinformatics, Academic Medical Center, University of Amsterdam, Amsterdam, the Netherlands
t Department of Surgery, University of California Davis, Sacramento, CA, USAu Department of Medicine, Department of Veterans Affairs, Northern California Health Care System, Mather, CA, USA
v Division of Infection, Immunity and Respiratory Medicine, University Hospital of South Manchester, University of Manchester, Manchester, UK
w Institute for Evidence in Medicine, Medical Center, University of Freiburg, Freiburg-am-Breisgau, Germany
x Cochrane Germany, Freiburg-am-Breisgau, Germanyy National Center for Environmental Assessment, U.S. Environmental Protection Agency, Washington, DC, USA
z Department of Medicine, University of Kansas Medical Center, Kansas City, KS, USA aa Institute of Population Health Sciences, University of Liverpool, Liverpool, UKab National Center for Computational Toxicology, U.S. Environmental Protection Agency, Durham, NC, USA
ac Department of Family Medicine, McMaster University, Hamilton, Ontario, Canada ad EPPI-Centre, Institute of Education, University College London, London, UK ae Programs for Assessment of Technology in Health, McMaster University, Hamilton, Ontario, Canadaaf Evidence-Based Toxicology Collaboration, Johns Hopkins Bloomberg School of Public Health, Baltimore, MD, USA
ag Health Economics Group, Institute of Health and Society, Newcastle University, Newcastle upon Tyne, UK
ah Health Quality Ontario, Toronto, Ontario, Canada 1 Co-first author.All authors analyzed and interpreted the data. J.B. and C.C-A wrote the first version of the article. All authors of this article have read and approved the final version submitted.
* Corresponding author: Jan Brozek, McMaster University, Health Sciences Centre, Area 2C, 1280 Main Street West, Hamilton, Ontario L8S 4K1, Canada.
The publisher's final edited version of this article is available at J Clin EpidemiolThe objective of the study is to present the Grading of Recommendations Assessment, Development, and Evaluation (GRADE) conceptual approach to the assessment of certainty of evidence from modeling studies (i.e., certainty associated with model outputs).
Expert consultations and an international multidisciplinary workshop informed development of a conceptual approach to assessing the certainty of evidence from models within the context of systematic reviews, health technology assessments, and health care decisions. The discussions also clarified selected concepts and terminology used in the GRADE approach and by the modeling community. Feedback from experts in a broad range of modeling and health care disciplines addressed the content validity of the approach.
Workshop participants agreed that the domains determining the certainty of evidence previously identified in the GRADE approach (risk of bias, indirectness, inconsistency, imprecision, reporting bias, magnitude of an effect, dose—response relation, and the direction of residual confounding) also apply when assessing the certainty of evidence from models. The assessment depends on the nature of model inputs and the model itself and on whether one is evaluating evidence from a single model or multiple models. We propose a framework for selecting the best available evidence from models: 1) developing de novo, a model specific to the situation of interest, 2) identifying an existing model, the outputs of which provide the highest certainty evidence for the situation of interest, either “off-the-shelf” or after adaptation, and 3) using outputs from multiple models. We also present a summary of preferred terminology to facilitate communication among modeling and health care disciplines.
This conceptual GRADE approach provides a framework for using evidence from models in health decision-making and the assessment of certainty of evidence from a model or models. The GRADE Working Group and the modeling community are currently developing the detailed methods and related guidance for assessing specific domains determining the certainty of evidence from models across health care—related disciplines (e.g., therapeutic decision-making, toxicology, environmental health, and health economics). © 2020 Published by Elsevier Inc.
Keywords: GRADE, Certainty of evidence, Mathematical models, Modelling studies, Health care Decision making, Guidelines
When direct evidence to inform health decisions is not available or not feasible to measure (e.g., long-term effects of interventions or when studies in certain populations are perceived as unethical), modeling studies may be used to predict that “evidence” and inform decision-making [1,2]. Health decision makers arguably face many more questions than can be reasonably answered with studies that directly measure the outcomes. Modeling studies, therefore, are increasingly used to predict disease dynamics and burden, the likelihood that an exposure represents a health hazard, the impact of interventions on health benefits and harms, or the economic efficiency of health interventions, among others [1]. Irrespective of the modeling discipline, decision makers need to know the best estimates of the modeled outcomes and how much confidence they may have in each estimate [3]. Knowing to what extent one can trust the outputs of a model is necessary when using them to support health decisions [4].
Although a number of guidance documents on how to assess the trustworthiness of estimates obtained from models in several health fields have been previously published [5–16], they are limited by failing to distinguish methodological rigor from completeness of reporting and by failing to clearly distinguish among various components affecting the trustworthiness of model outputs. In particular, they lack clarity regarding sources of uncertainty that may arise from model inputs and from the uncertainty about a model itself. Modelers and those using results from models should assess the credibility of both [4].
Authors have attempted to develop tools to assess model credibility, but many addressed only selected aspects, such as statistical reproducibility of data, the quality of reporting [17], or a combination of reporting with aspects of good modeling practices [7,18–21]. Many tools also do not provide sufficiently detailed guidance on how to apply individual domains or criteria. There is therefore a need for further development and validation of such tools in specific disciplines. Sufficiently detailed guidance for making and reporting these assessments is also necessary.
Models predict outcomes based on model inputs—previous observations, knowledge, and assumptions about the situation being modeled. Thus, when developing new models or assessing whether an existing model has been optimally developed, one should specify a priori the most appropriate and relevant data sources to inform different parameters required for the model. These may be either (seldom) a single study that provides the most direct information for the situation being modeled or (more commonly) a systematic review of multiple studies that identify all relevant sources of data. The risk of bias, directness and consistency of input data, precision of these estimates, and other domains specified in the Grading of Recommendations Assessment, Development, and Evaluation (GRADE) approach determine the certainty of each of the model inputs [22–28].
When assessing the evidence generated, various disciplines in health care and related areas that use modeling face similar challenges and may benefit from shared solutions. Table 1 presents examples of selected models used in health-related disciplines. Building on the existing GRADE approach, we refined and expand guidance regarding assessment of the certainty of model outputs. We formed a GRADE project group which comprised individuals with expertise in developing models and using model results in health-related disciplines, to create a unified framework for assessing the certainty of model outputs in the context of systematic reviews [29], health technology assessments, health care guidelines, and other health decision-making. In this article, we outline the proposed conceptual approach and clarify key terminology ( Table 2 ). The target audience for this article includes researchers who develop models and those who use models to inform health care—related decisions.
Examples of modeling methods in health-related disciplines (not comprehensive) a
Decision analysis models | Structured model representing health care pathways examining effects of an intervention on outcomes of interest. |
Types | |
■ Decision tree models | |
■ State transition models | |
○ Markov cohort simulation | |
○ Individual-based microsimulation (first-order Monte Carlo) | |
■ Discrete event simulation | |
■ Dynamic transmission models | |
■ Agent-based models | |
Examples | |
■ Estimation of long-term benefits and harm outcomes from complex intervention, e.g., minimum unit pricing of alcohol | |
■ Estimation of benefits and harms of population mammography screening based in the microsimulation model, e.g., Wisconsin model from CISNET collaboration [58] | |
■ Susceptible-Infectious-Recovery transmission dynamic model to assess effectiveness of lockdown during the SARS-CoV-2 pandemic [59] | |
Pharmacology and toxicology models | Computational models developed to organize, analyze, simulate, visualize, or predict toxicological and ecotoxicological effects of chemicals. In some cases, these models are used to estimate the toxicity of a substance even before it has been synthesized. |
Types | |
■ Structural alerts and rule-based models | |
■ Read-across | |
■ Dose response and time response | |
■ Toxicokinetic (TK) and toxicodynamic(TD) | |
■ Uncertainty factors | |
■ Quantitative structure activity relationship (QSAR) | |
■ Biomarker-based toxicity models | |
Examples | |
● Structural alerts for mutagenicity and skin sensitization | |
● Read-across for complex endpoints such as chronic toxicity | |
● Pharmacokinetic (PK) models to calculate concentrations of substances in organs, after a variety of exposures and QSAR models for carcinogenicity | |
● TGx-DDI biomarker to detect DNA damage–inducing agents | |
Environmental models | The EPA defined these models as ‘A simplification of reality that is constructed to gain insights into select attributes of a physical, biological, economic, or social system.’ It involves the application of multidisciplinary knowledge to explain, explore, and predict the Earth’s response to environmental change and the interactions between human activities and natural processes. |
Classification (based on the CREM guidance document): | |
● Human activity models | |
● Natural system process | |
● Emission models | |
● Fate and transport models | |
● Exposure models | |
● Human health effect models | |
● Ecological effect models | |
● Economic impact models | |
● Noneconomic impact models | |
Examples | |
● Land use regression models | |
● IH Skin Perm [60] | |
● ConsExpo [61] | |
● Other exposure models [62] | |
Other | ● HopScore: An Electronic Outcomes-Based Emergency Triage System [63] |
● Computational general equilibrium (CGE) models [64] |
a Although not described in this classification, simple calculations incorporating two or more pieces of evidence, as for example, the multiplication of an RR by the baseline risk to obtain the absolute risk difference of an intervention are models, although pragmatic, with their respective assumptions.
Selected commonly used and potentially confusing terms used in the context of modeling and the GRADE approach *
Term | General definition |
---|---|
Sources of evidence (may come from in vitro or in vivo experiment or a mathematical model) | |
Streams of evidence | Parallel information about the same outcome that may have been obtained using different methods of estimating that outcome. For instance, evidence of the increased risk for developing lung cancer in humans after an exposure to certain chemical compound may come from several streams of evidence: 1) mechanistic evidence—models of physiological mechanisms, 2) studies in animals—observations and experiments in animals from different phyla, classes, orders, families, genera, and species (e.g., bacteria, nematodes, insects, fish, mice, rats), and 3) studies in humans. |
Bodies of evidence | Information about multiple different aspects around a decision about the best course of action. For instance, to decide whether or not a given diagnostic test should be used in some people, one needs to integrate the bodies of evidence about the accuracy of the test, the prevalence of the conditions being suspected, the natural history of these conditions, the effects of potential treatments, values and preferences of affected individuals, cost, feasibility, etc. |
Quality (may refer to many concepts, thus alternative terms are preferred to reduce confusion) | |
Certainty of model outputs | |
Alternative terms: | In the context of health decision-making, the certainty of evidence (term preferred over “quality” to avoid confusion with the risk of bias in an individual study) reflects the extent to which one’s confidence in an estimate of an effect is adequate to make a decision or a recommendation. Decisions are influenced not only by the best estimates of the expected desirable and undesirable consequences but also by one’s confidence in these estimates. In the context of evidence syntheses of separate bodies of evidence (e.g., systematic reviews), the certainty of evidence reflects the extent of confidence that an estimate of effect is correct. For instance, the attributable national risk of cardiovascular mortality resulting from exposure to air pollution measured in selected cities. |
■ certainty of modeled evidence | |
■ quality of evidence | |
■ quality of model output | |
■ strength of evidence | |
■ confidence in model outputs | |
The GRADE Working Group published several articles explaining the concept in detail [22 –28,65]. Note that the phrase “confidence in an estimate of an effect” does not refer to statistical confidence intervals. Certainty of evidence is always assessed for the whole body of evidence rather than on a single-study level (single studies are assessed for risk of bias and indirectness). | |
Certainty of model inputs | |
Alternative term: | Characteristics of data that are used to develop, train, or run the model, e.g., source of input values, their manipulation before input into a model, quality control, risk of bias in data, etc. |
■ quality of model inputs | |
Credibility of a model | |
Alternative terms: | To avoid confusion and keep with terminology used by modeling community [7], we suggest using the term credibility rather than quality of a model. The concept refers to the characteristics of a model itself—its design or execution—that affect the risk that the results may overestimate or underestimate the true effect. Various factors influence the overall credibility of a model, such as its structure, the analysis, and the validation of the assumptions made during modeling. |
■ quality of a model | |
■ risk of bias in a model | |
■ validity of a model | |
Quality of reporting | Refers to how comprehensively and clearly model inputs, a model itself, and model outputs have been documented and described such that they can be critically evaluated and used for decision-making. Quality of reporting and quality of a model are separate concepts: a model with a low quality of reporting is not necessarily a low-quality model and vice versa. |
Directness | |
Directness of a model | |
Alternative terms: | By directness of a model, we mean the extent to which the model represents the real-life situation being modeled which is dependent on how well the input data and the model structure reflect the scenario of interest. Directness is the term used in the GRADE approach because each of the alternatives has been used usually in a narrower meaning. |
■ relevance | |
■ external validity | |
■ applicability | |
■ generalizability | |
■ transferability | |
■ translatability |
* There may be either subtle or fundamental differences among some disciplines in how these terms are being used; for the purposes of this article, these terms are generalized rather than discipline specific.GRADE, Grading of Recommendations Assessment, Development, and Evaluation.
Authors have used the term model to describe a variety of different concepts [2] and suggested several broader or narrower definitions [6,30], so even modelers in the relatively narrow context of health sciences can differ in their views regarding what constitutes a model. Models vary in their structure and degree of complexity. A very simple model might be an equation estimating a variable not directly measured, such as the absolute effect of an intervention estimated as the product of the intervention’s relative effect and the assumed baseline risk in a defined population (risk difference equals relative risk reduction multiplied by an assumed baseline risk). On the other end of the spectrum, elaborate mathematical models, such as system dynamics models (e.g., infectious disease transmission) may contain dozens of sophisticated equations that require considerable computing power to solve.
By their nature, such models only resemble the phenomena being modeled—that is, specific parts of the world that are interesting in the context of a particular decision—with necessary approximations and simplifications and to the extent that one actually knows and understands the underlying mechanisms [1]. Given the complexity of the world, decision makers often rely on some sort of a model to answer health-related questions.
In this article, we focus on quantitative mathematical models defined as “mathematical framework representing variables and their interrelationships to describe observed phenomena or predict future events” [30] used in health-related disciplines for decision-making ( Table 1 ). These may be models of systems representing causal mechanisms (aka mechanistic models), models predicting outcomes from input data (aka empirical models), and models combining mechanistic with empirical approaches (aka hybrid models). We do not consider here statistical models used to estimate the associations between measured variables (e.g., proportional hazards models or models used for meta-analysis).
The GRADE Working Group was established in the year 2000 and continues as a community of people striving to create systematic and transparent frameworks for assessing and communicating the certainty of the available evidence used in making decisions in health care—related and health-related disciplines [31]. The GRADE Working Group now includes over 600 active members from 40 countries and serves as a think tank for advancing evidence-based decision-making in multiple health-related disciplines (www.gradeworkinggroup.org). GRADE is widely used internationally by over 110 organizations to address topics related to clinical medicine, public health, coverage decisions, health policy, and environmental health.
The GRADE framework uses concepts familiar to health scientists, grouping specific items to evaluate the certainty of evidence in conceptually coherent domains. Specific approaches to the concepts may differ depending on the nature of the body of evidence ( Table 2 ). GRADE domains include concepts such as risk of bias [28], directness of information [24], precision of an estimate [23], consistency of estimates across studies [25], risk of bias related to selective reporting [26], strength of the association, presence of a dose—response gradient, and the presence of plausible residual confounding that can increase confidence in estimated effects [27].
The general GRADE approach is applicable irrespective of health discipline. It has been applied to rating the certainty of evidence for management interventions, health care—related tests and strategies [32,33], prognostic information [34], evidence from animal studies [35], use of resources and cost-effectiveness evaluations [36], and values and preferences [37,38]. Although the GRADE Working Group has begun to address certainty of modeled evidence in the context of test—treatment strategies [39], health care resource use and costs [36], and environmental health [40], more detailed guidance is needed for complex models such as those used in infectious diseases, health economics, public health, and decision analysis.
On May 15 and 16, 2017, health scientists participated in a GRADE modeling project group workshop in Hamilton, Ontario, Canada, to initiate a collaboration in developing common principles for the application of the GRADE assessment of certainty of evidence to modeled outputs. The National Toxicology Program of the Department of Health and Human Services in the United States of America and the MacGRADE Center in the Department of Health Research Methods, Evidence, and Impact at McMaster University sponsored the workshop which was co-organized by MacGRADE Center and ICF International.
Workshop participants were selected to ensure a broad representation of all modeling related fields (Appendix). Participants had expertise in modeling in the context of clinical practice guidelines, public health, environmental health, dose—response modeling, physiologically based pharmacokinetic (PBPK) modeling, environmental chemistry, physical/chemical property prediction, evidence integration, infectious disease, computational toxicology, exposure modeling, prognostic modeling, diagnostic modeling, cost-effectiveness modeling, biostatistics, and health ethics.
Leading up to the workshop, we held three webinars to introduce participants to the GRADE approach. Several workshop participants (VM, KT, JB, AR, JW, JLB, HJS) collected and summarized findings from literature and the survey of experts as background material that provided a starting point for discussion. The materials included collected terminology representing common concepts across multiple disciplines that relate to evaluating modeled evidence and a draft framework for evaluating modeled evidence. Participants addressed specific tasks in small groups and large group discussion sessions and agreed on key principles both during the workshop and through written documents.
Workshop participants agreed on the importance of clarifying terminology to facilitate communication among modelers, researchers, and users of model outputs from different disciplines. Modeling approaches evolved some-what independently, resulting in different terms being used to describe the same or very similar concepts or the same term being used to describe different concepts. For instance, the concept of extrapolating from the available data to the context of interest has been referred to as directness, applicability, generalizability, relevance, or external validity. The lack of standardized terminology leads to confusion and hinders effective communication and collaboration among modelers and users of models.
Overcoming these obstacles would require clarifying the definitions of concepts and agreeing on terminology across disciplines. Realizing that this involves changing established customary use of terms in several disciplines, workshop participants suggested accepting the use of alternative terminology while always being clear about the preferred terms to be used and the underlying concept to which it refers ( Table 2 ). Experts attending a World Health Organization’s consultation have very recently suggested a more extensive set of terms [41]. To facilitate future communication, participants of this workshop will further collaborate to build a comprehensive glossary of terminology related to modeling.
Workshop participants suggested an approach to incorporate model outputs in health-related decision-making ( Figure 1 ). In this article, we describe only the general outline of the suggested approach; in subsequent articles, we will discuss the details of the approach and provide more specific guidance on its application to different disciplines and contexts.
The general approach to using modeled evidence and assessing its certainty in health-related disciplines.
Researchers should start by conceptualizing the problem and the ideal target model that would best represent the actual phenomenon or decision problem they are considering [13]. This conceptualization would either guide the development of a new model or serve as a reference against which existing models could be compared. The ideal target model should reflect the following: 1) the relevant population (e.g., patients receiving some diagnostic procedure or exposed to some hazardous substance), 2) the exposures or health interventions being considered, 3) the outcomes of interest in that context, and 4) their relationships [42]. Conceptualizing the model will also reduce the risk of intentional or unintentional development of data-driven models, in which inputs and structure would be determined only by what is feasible to develop given the available data at hand.
Participants identified three options in which users may incorporate model outputs in health decision-making ( Figure 1 ):
Develop a model de novo designed specifically to answer the very question at hand. Workshop participants agreed that in an ideal situation, such an approach would almost always be the most appropriate. Following this approach, however, requires suitable skills, ample resources, and time being available. It also requires enough knowledge about the phenomenon being modeled to be able to tell whether or not the new model would have any advantage over already existing models.
Search for an existing model describing the same or a very similar problem and use it “off-the-shelf” or adapt it appropriately to answer the current question. In practice, many researchers initially use this approach because of the aforementioned limitations of developing a new model. However, it is often not possible to find an existing model that would be directly relevant to the problem at hand and/or it is not feasible to adapt an existing model when found. Any adaptation of a model requires availability of input data relevant for current problem, appropriate expertise and resources, and access to the original model. The latter is often not available (e.g., proprietary model or no longer maintained) or the structure of the original model is not being transparent enough to allow adaptation (“black-box”).
Use the results from multiple existing models found in the literature [43]. This approach may be useful when a limited knowledge about the phenomenon being modeled makes it impossible to decide which of the available models are more relevant, or when many alternative models are relevant but use different input parameters. In such situations, one may be compelled to rely on the results of several models because selection of the single, seemingly “best” model may provide incorrect estimates of outputs and lead to incorrect decisions.
Identifying existing models that are similar to the ideal target model often requires performing a scoping of the literature or a complete systematic review of potentially relevant models—a structured process following a standardized set of methods with a goal to identify and assess all available models that are accessible, transparently reported, and fulfill the prespecified eligibility criteria based on the conceptual ideal target model. Some prefer the term systematic survey that differs from a systematic review in the initial intention to use the results: in systematic reviews, the initial intention is to combine the results across studies either statistically through a meta-analysis or narratively summarizing their results when appropriate, whereas in a systematic survey, the initial intention is to examine the various ways that an intervention or exposure has been modeled, to review the input evidence that has been used, and ultimately to identity a single model that fits the conceptual ideal target model the best or requires the least adaptation; only when one cannot identify a single such model will it be necessary to use the results of multiple existing models.
If a systematic search revealed one or more models meeting the eligibility criteria, then researchers would assess the certainty of outputs from each model. Depending on this assessment, researchers may be able to use the results of a single most direct and lowest risk of bias model “off-the-shelf” or proceed to adapt that model. If researchers failed to find an existing model that would be sufficiently direct and low risk of bias, then they would ideally develop their own model de novo.
When researchers develop their own model or when they identify a single model that is considered sufficiently direct to the problem at hand, they should assess the certainty of its outputs (i.e., evidence generated from that model). Note that if a model estimates multiple outputs, researchers need to assess the certainty of each output separately [23—28]. Workshop participants agreed that all GRADE domains are applicable to assess the certainty of model outputs, but further work is needed to identify examples and develop specific criteria to be assessed, which may differ depending on the model being used and/or situation being modeled.
The risk of bias of model outputs (i.e., model outputs being systematically overestimated or underestimated) is determined by the credibility of a model itself and the certainty of evidence for each of model inputs.
The credibility of a model, also referred to as the quality of a model ( Table 2 ), is influenced by its conceptualization, structure, calibration, validation, and other factors. Determinants of model credibility are likely to be specific to a modeling discipline (e.g., health economic models have different determinants of their credibility than PBPK models). There are some discipline-specific guidelines or checklists developed for the assessment of credibility of a model and other factors affecting the certainty of model outputs such as the framework to assess adherence to good practice guidelines in decision-analytic modeling [18], the questionnaire to assess relevance and credibility of modeling studies [18,44,45], good research practices for modeling in health technology assessment [5,6,8,9,12–14], the approaches to assessing uncertainty in read-across [46], and the quantitative structure—activity relationships [47] in predictive toxicology. Workshop participants agreed that there is a need for comprehensive tools developed specifically to assess credibility of various types of models in different modeling disciplines.
The certainty of evidence in each of the model inputs is another critical determinant of the risk of bias in a model. A model has several types of input data—bodies of evidence used to populate a model ( Table 2 ). When researchers develop their model de novo, to minimize the risk of bias, they need to specify those input parameters to which the model outputs are the most sensitive. For instance, in economic models, these key parameters may include health effects, resource use, utility values, and baseline risks of outcomes. Model inputs should reflect the entire body of relevant evidence satisfying clear prespecified criteria rather than an arbitrarily selected evidence that is based on convenience (“any available evidence”) or picked in any other nonsystematic way (e.g., “first evidence found”—single studies that researchers happen to know about or are the first hits in a database search).
The appropriate approach will depend on the type of data and may require performing a systematic review of evidence on each important or crucial input variable [48–50]. Some inputs may have very narrow inclusion criteria, and therefore, evidence from single epidemiological survey or population surveillance may provide all relevant data for the population of interest (e.g., baseline population incidence or prevalence).
The certainty of evidence for each input needs to be assessed following the established GRADE approach specific to that type of evidence (e.g., estimates of intervention effects or baseline risk of outcomes) [22,32,34,37]. Following the logic of the GRADE approach that the overall certainty of evidence cannot be higher than the lowest certainty for any body of evidence that is critical for a decision [51], the overall rating of certainty of evidence across model inputs should be limited by the lowest certainty rating for any body of evidence (in this case, input data) to which the model output(s) was proved sensitive.
Application of this approach requires a priori consideration of likely critical and/or important inputs when specifying the conceptual ideal target model and the examination of the results of back-end sensitivity analyses. It further requires deciding how to judge whether results are or are not sensitive to alternative input parameters. Authors have described several methods to identify the most influential parameters including global sensitivity analysis to obtain “parameter importance measures” (i.e., information-based measures) [52] or alternatively by varying one parameter at a time and assessing their influence in “base case” outputs [52] For example, in a model-based economic evaluation, one might be looking for the influence of sensitivity analysis on cost-effectiveness ratios at a specified willingness-to-pay threshold.
By directness or relevance, we mean the extent to which model outputs directly represent the phenomenon being modeled. To evaluate the relevance of a model, one needs to compare it against the conceptual ideal target model. When there are concerns about the directness of the model or there is limited understanding of the system being modeled making it difficult to assess directness, then one may have lower confidence in model outputs.
Determining the directness of model outputs includes assessing to what extent the modeled population, the assumed interventions and comparators, the time horizon, the analytic perspective, as well as the outcomes being modeled reflect those that are current interest. For instance, if the question is about the risk of birth defects in children of mothers chronically exposed to a certain substance, there may be concerns about the directness of the evidence if the model assumed short-term exposure, the route of exposure was different, or the effects of exposure to a similar but not the same substance were measured.
Assessing indirectness in a single model also requires evaluating two separate sources of indirectness:
Indirectness of input data with respect to the ideal target model’s inputs. Indirectness of model outputs with respect to the decision problem at hand.This conceptual distinction is important because, although they are interrelated, one needs to address each type of indirectness separately. Even if the outputs might be direct to the problem of interest, the final assessment should consider if the inputs used were also direct for the target model.
Using an existing model has potential limitations: its inputs might have been direct for the decision problem addressed by its developers but are not direct with respect to the problem currently at hand. In this context, sensitivity analysis can help to assess to what extent model outputs are robust to the changes in input data or assumptions used in model development.
A single model may yield inconsistent outputs owing to unexplained variability in the results of individual studies informing the pooled estimates of input variables. For instance, when developing a health economic model, a systematic review may yield several credible, but discrepant, utility estimates in the population of interest. If there is no plausible explanation for that difference in utility estimates, outputs of a model based on those inputs may also be qualitatively inconsistent. Again, sensitivity analysis may help to make a judgment to what extent such inconsistency of model inputs would translate into a meaningful inconsistency in model outputs with respect to the decision problem at hand.
Sensitivity analysis characterizes the response of model outputs to parameter variation and helps to determine the robustness of model’s qualitative conclusions [52,53]. The overall certainty of model outputs may also be lower when the outputs are estimated imprecisely. For quantitative outputs, one should examine not only the point estimate (e.g., average predicted event) but also the variability of that estimate (e.g., results of the probabilistic sensitivity analysis based in the distribution of the input parameters). It is essential that a report from a modeling study always includes information about output variability. Further guidance on how to assess imprecision in model outputs will need to take into account if the conclusions change in accordance with that specific parameter. In some disciplines, for instance in environmental health, model inputs are frequently qualitative. Users of such models may assess “adequacy” of the data, that is, the degree of “richness” and quantity of data supporting particular outputs of a model.
The risk of publication bias, also known as “reporting bias”, “non-reporting bias”, or “bias owing to missing results”, as it is currently called in the Cochrane Handbook [54], is the likelihood that relevant models have been constructed but were not published or otherwise made publicly available. Risk of publication bias may not be relevant when assessing the certainty of outputs of a single model constructed de novo. However, when one intends to reuse an existing model but is aware or strongly suspects that similar models had been developed but are not available, then one may be inclined to think that their outputs might have systematically differed from the model that is available. In such a case, one may have lower confidence in the outputs of the identified model if there is no reasonable explanation for the inability to obtain those other models.
The GRADE approach to rating the certainty of evidence recognized three situations when the certainty of evidence can increase: large magnitude of an estimated effect, presence of a dose—response gradient in an estimated effect, and an opposite direction of plausible residual confounding [27]. Workshop participants agreed that presence of a dose—response gradient in model outputs may be applicable in some modeling disciplines (e.g., environmental health). Similarly, whether or not a large magnitude of an effect in model outputs increases the certainty of the evidence may depend on the modeling discipline. The effect of an opposite direction of plausible residual confounding seems theoretically also applicable in assessing the certainty of model outputs (i.e., a conservative model not incorporating input data parameter in favor of an intervention but still finding favorable outputs), but an actual example of this phenomenon in modeling studies is still under discussion.
Not infrequently, particularly in disciplines relying on mechanistic models, the current knowledge about the real system being modeled is very limited precluding the ability to determine which of the available existing models generate higher certainty outputs. Therefore, it may be necessary to rely on the results across multiple models. Other examples include using multiple models when no model was developed for the population directly of interest (e.g., the European breast cancer guidelines for screening and diagnosis relied on a systematic review of modeling studies that compared different mammography screening intervals [55]) or when multiple models of the same situation exist but vary in structure, complexity, and parameter choices (e.g., HIV Modelling Consortium compared several different mathematical models simulating the same antiretroviral therapy program and found that all models predicted that the program has the potential to reduce new HIV infections in the population [56]).
When researchers choose or are compelled to include outputs from several existing models, they should assess the certainty of outputs across all included models. This assessment may be more complex than for single models and single bodies of evidence. The feasibility of GRADE’s guidance to judge the certainty of evidence lies in the availability of accepted methods for assessing most bodies of evidence from experimental to observational studies. However, the methods for systematic reviews of modeling studies are less well-established; some stages of the process are more complex, the number of highly skilled individuals with experience in such systematic reviews is far lower, and there is larger variability in the results [57]. In addition, researchers must be careful to avoid “double counting” the same model as if it were multiple models. For instance, the same model (i.e., same structure and assumptions) may have been used in several modeling studies, in which investigators relied on different inputs. When facing this scenario, researchers may need to decide which of the inputs are the most direct to their particular question and include in only this model in the review.
The assessment of risk of bias across models involves an assessment of the risk of bias in each individual model (see aforementioned discussion of risk of bias in single model) and subsequently making a judgment about the overall risk of bias across all included models. Specific methods for operationalizing this integration remain to be developed.
As for the risk of bias, researchers need to assess indirectness of outputs initially for each of included models and then integrate the judgments across models. Likewise, specific methods for operationalizing this integration still remain to be developed. During this assessment, researchers may find some models too indirect to be informative for their current question and decide to exclude them from further consideration. However, the criteria to determine which models are too indirect should be developed a priori, before the search for the models is performed and their results are known.
The overall certainty of model outputs may also be lower when model outputs are not estimated precisely. If researchers attempt a quantitative synthesis of outputs across models, they will report the range of estimates and variability of that estimates. When researchers choose to perform only a qualitative summary of the results across models, it is desirable that they report some estimate of variability in the outputs of individual models and an assessment of how severe the variability is (e.g., range of estimated effects).
The assessment of inconsistency should focus on unexplained differences across model outputs for a given outcome. If multiple existing models addressing the same issue produce considerably different outputs or reach contrasting conclusions, then careful comparison of the models may lead to a deeper understanding of the factors that drive outputs and conclusions. Ideally, the different modeling groups that developed relevant models would come together to explore the importance of differences in the type and structure of their models and of the data used as model inputs.
Invariably there will be some differences among the estimates from different models. Researchers will need to assess whether or not these differences are important, that is, whether they would lead to different conclusions. If the differences are important but can be explained by model structure, model inputs, the certainty of the evidence of the input parameters, or other relevant reasons, one may present the evidence separately for the relevant subgroups. If differences are important, but cannot be clearly explained, the certainty of model outputs may be lower.
The assessment is similar to that of the risk of publication bias in the context of a single model.
All considerations are the same to those in the context of a single model.
The goal of the GRADE project group on modeling is to provide concepts and operationalization of how to rate the certainty of evidence in model outputs. This article provides an overview of the conclusions of the project group. This work is important because there is a growing need and availability of modeled information resulting from a steadily increasing knowledge of the complexity of the structure and interactions in our environment and computational power to construct and run models. Users of evidence obtained from modeling studies need to know how much trust they may have in model outputs. There is a need to improve the methods of constructing models and to develop methods for assessing the certainty in model outputs. In this article, we have attempted to clarify the most important concepts related to developing and using model outputs to inform health-related decision-making. Our preliminary work identified confusion about terminology, lack of clarity of what is a model, and need for methods to assess certainty in model outputs as priorities to be addressed to improve the use of evidence from modeling studies.
In some situations, decision makers might be better off developing a new model specifically designed to answer their current question. However, we suggest that it is not always feasible to develop a new model or that developing a new model might not be any better than using already existing models, when the knowledge of the real life system to be modeled is limited precluding the ability to choose one model that would be better than any other. Thus, sometimes it may be necessary or more appropriate to use one or multiple existing models depending on their availability, credibility, and relevance to the decision-making context. The assessment of the certainty of model outputs will be conceptually similar when a new model is constructed, or one existing model is used. The main difference between the latter two approaches is the availability of information to perform a detailed assessment. That is, information for one’s own model may be easily accessible, but information required to assess someone else’s model will often be more difficult to obtain. Assessment of the certainty evidence across models can build on existing GRADE domains but requires different operationalization.
Because it builds on an existing, widely used framework that includes a systematic and transparent evaluation process, modeling disciplines’ adoption of the GRADE approach and further development of methods to assess the certainty of model outputs may be beneficial for health decision-making. Systematic approaches improve rigor of research, reducing the risk of error and its potential consequences; transparency of the approach increases its trustworthiness. There may be additional benefits related to other aspects of the broader GRADE approach, for instance, a potential to reduce unnecessary complexity and workload in modeling by careful consideration of the most direct evidence as model inputs. This may allow, for instance, optimization of the use of different streams of evidence as model inputs. Frequently, authors introduce unnecessary complexity by considering multiple measures of the same outcome when focus could be on the most direct outcome measure.
The GRADE Working Group will continue developing methods and guidance for using model outputs in health-related decision-making. In subsequent articles, we will provide more detailed guidance about choosing the “best” model when multiple models are found, using multiple models, integrating the certainty of evidence from various bodies of evidence with credibility of the model and arriving at the overall certainty in model outputs, how to assess the credibility of various types of models themselves, and further clarification of terminology. In the future, we aim to develop and publish the detailed guidance for assessing certainty of evidence from models, the specific guidance for the use of modeling across health care—related disciplines (e.g., toxicology, environmental health, or health economics), validation of the approach, and accompanying training materials and examples.
General concepts determining the certainty of evidence in the GRADE approach (risk of bias, indirectness, inconsistency, imprecision, reporting bias, magnitude of an effect, dose—response relation, and the direction of residual confounding) also apply in the context of assessing the certainty of evidence from models (model outputs).
Detailed assessment of the certainty of evidence from models differs for the assessment of outputs from a single model compared with the assessment of outputs across multiple models.
We propose a framework for selecting the best available evidence from models to inform health care decisions: to develop a model de novo, to identify an existing model, the outputs of which provide the highest certainty evidence, or to use outputs from multiple models.
We suggest that the modeling and health care decision-making communities collaborate further to clarify terminology used in the context of modeling and make it consistent across the disciplines to facilitate communication.
A.R. was supported by the National Institutes of Health, National Institute of Environmental Health Sciences.
Elie Akl (EA)– American University of Beirut, Lebanon
Jim Bowen (JMB)– McMaster University, Canada
Chris Brinkerhoff (CB)– US Environmental Protection Agency, USA
Jan Brozek (JLB)– McMaster University, Canada
John Bucher (JB)– US National Toxicology Program, USA
Carlos Canelo-Aybar (CCA)– Iberoamerican Cochrane Centre, Spain
Marcy Card (MC)– US Environmental Protection Agency, USA
Weihsueh A. Chiu (WCh)– Texas A&M University, USA
Mark Cronin (MC)– Liverpool John Moores University, UK
Tahira Devji (TD)– McMaster University, Canada
Ben Djulbegovic (BD)– University of South Florida, USA
Ken Eng (KE)– Public Health Agency of Canada
Gerald Gartlehner (GG)– Donau-Universität Krems, Austria
Gordon Guyatt (GGu)– McMaster University, Canada
Raymond Hutubessy (RH)– World Health Organization Initiative for Vaccine Research, Switzerland
Manuela Joore (MJ)– Maastricht University, the Netherlands
Richard Judson (RJ)– US Environmental Protection Agency, USA
S. Vittal Katikireddi (SK)– University of Glasgow, UK
Nicole Kleinstreuer (NK)– US National Toxicology Program, USA
Judy LaKind (JL)– University of Maryland, USA
Miranda Langendam (ML)– University of Amsterdam, the Netherlands
Zbyszek Leś (ZL)– Evidence Prime Inc., Canada
Veena Manja (VM)– McMaster University, Canada
Joerg Meerpohl (JM)– GRADE Center Freiburg, Cochrane Germany, University Medical Center Freiburg
Dominik Mertz (DM)– McMaster University, Canada
Roman Mezencev (RM)– US Environmental Protection Agency, USA
Rebecca Morgan (RMo)– McMaster University, Canada
Gian Paolo Morgano (GPM)– McMaster University, Canada
Reem Mustafa (RMu)– University of Kansas, USA
Bhash Naidoo (BN)– National Institute for Health and Clinical Excellence, UK
Martin O'Flaherty (MO)– Public Health and Policy, University of Liverpool, UK
Grace Patlewicz (GP)– US Environmental Protection Agency, USA
John Riva (JR)– McMaster University, Canada
Alan Sasso (AS)– US Environmental Protection Agency, USA
Paul Schlosser (PS)– US Environmental Protection Agency, USA
Holger Schünemann (HJS)– McMaster University, Canada
Lisa Schwartz (LS)– McMaster University, Canada
Ian Shemilt (IS)– University College London, UK
Marek Smieja (MS)– McMaster University, Canada
Ravi Subramaniam (RS)– US Environmental Protection Agency, USA
Jean-Eric Tarride (JT)– McMaster University, Canada
Kris Thayer (KAT)– US Environmental Protection Agency, USA
Katya Tsaioun (KT)– John Hopkins University, USA
Bernhard Ultsch (BU)– Robert Koch Institute, Germany
John Wambaugh (JW)– US Environmental Protection Agency, USA
Jessica Wignall (JWi)– ICF, USA
Ashley Williams (AW)– ICF, USA
Feng Xie (FX)– McMaster University, Canada
Appendix A Supplementary data
Supplementary data to this article can be found online at https://doi.org/10.1016/j.jclinepi.2020.09.018.
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