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Wikipedia

Meta-analysis

January 11, 2023

For the process in historical linguistics known as metanalysis, see Rebracketing.

A meta-analysis is a statistical analysis that combines the results of multiple scientific studies. Meta-analyses can be performed when there are multiple scientific studies addressing the same question, with each individual study reporting measurements that are expected to have some degree of error. The aim then is to use approaches from statistics to derive a pooled estimate closest to the unknown common truth based on how this error is perceived. Meta-analytic results are considered the most trustworthy source of evidence by the evidence-based medicine literature.[1][2][3]

Graphical summary of a meta-analysis of over 1,000 cases of diffuse intrinsic pontine glioma and other pediatric gliomas, in which information about the mutations involved as well as generic outcomes were distilled from the underlying primary literature.

Not only can meta-analyses provide an estimate of the unknown effect size, it also has the capacity to contrast results from different studies and identify patterns among study results, sources of disagreement among those results, or other interesting relationships that may come to light with multiple studies.[4]

However, there are some methodological problems with meta-analysis. If individual studies are systematically biased due to questionable research practices (e.g., data dredging, data peeking, dropping studies) or the publication bias at the journal level, the meta-analytic estimate of the overall treatment effect may not reflect the actual efficacy of a treatment.[5][6] Meta-analysis has also been criticized for averaging differences among heterogeneous studies because these differences could potentially inform clinical decisions.[7] For example, if there are two groups of patients experiencing different treatment effects studies in two randomised control trials (RCTs) reporting conflicting results, the meta-analytic average is representative of neither group, similarly to averaging the weight of apples and oranges, which is neither accurate for apples nor oranges.[8] In performing a meta-analysis, an investigator must make choices which can affect the results, including deciding how to search for studies, selecting studies based on a set of objective criteria, dealing with incomplete data, analyzing the data, and accounting for or choosing not to account for publication bias.[9] This makes meta-analysis malleable in the sense that these methodological choices made in completing a meta-analysis are not determined but may affect the results.[10] For example, Wanous and colleagues examined four pairs of meta-analyses on the four topics of (a) job performance and satisfaction relationship, (b) realistic job previews, (c) correlates of role conflict and ambiguity, and (d) the job satisfaction and absenteeism relationship, and illustrated how various judgement calls made by the researchers produced different results.[11]

Meta-analyses are often, but not always, important components of a systematic review procedure. For instance, a meta-analysis may be conducted on several clinical trials of a medical treatment, in an effort to obtain a better understanding of how well the treatment works. Here it is convenient to follow the terminology used by the Cochrane Collaboration,[12] and use "meta-analysis" to refer to statistical methods of combining evidence, leaving other aspects of 'research synthesis' or 'evidence synthesis', such as combining information from qualitative studies, for the more general context of systematic reviews. A meta-analysis is a secondary source.[13][14] In addition, meta-analysis may also be applied to a single study in cases where there are many cohorts which have not gone through identical selection criteria or to which the same investigational methodologies have not been applied to all in the same manner or under the same exacting conditions. Under these circumstances each cohort is treated as an individual study and meta-analysis is used to draw study-wide conclusions.[15]

History

The historical roots of meta-analysis can be traced back to 17th century studies of astronomy,[16] while a paper published in 1904 by the statistician Karl Pearson in the British Medical Journal[17] which collated data from several studies of typhoid inoculation is seen as the first time a meta-analytic approach was used to aggregate the outcomes of multiple clinical studies.[18][19] The first meta-analysis of all conceptually identical experiments concerning a particular research issue, and conducted by independent researchers, has been identified as the 1940 book-length publication Extrasensory Perception After Sixty Years, authored by Duke University psychologists J. G. Pratt, J. B. Rhine, and associates.[20] This encompassed a review of 145 reports on ESP experiments published from 1882 to 1939, and included an estimate of the influence of unpublished papers on the overall effect (the file-drawer problem). The term "meta-analysis" was coined in 1976 by the statistician Gene V. Glass,[21][22][23] who stated "my major interest currently is in what we have come to call ...the meta-analysis of research. The term is a bit grand, but it is precise and apt ... Meta-analysis refers to the analysis of analyses". Although this led to him being widely recognized as the modern founder of the method, the methodology behind what he termed "meta-analysis" predates his work by several decades.[24][25] The statistical theory surrounding meta-analysis was greatly advanced by the work of Nambury S. Raju, Larry V. Hedges, Harris Cooper, Ingram Olkin, John E. Hunter, Jacob Cohen, Thomas C. Chalmers, Robert Rosenthal, Frank L. Schmidt, John E. Hunter, and Douglas G. Claurett.[23][26][clarification needed] In 1992, meta-analysis was first applied to ecological questions[27] by Jessica Gurevitch who used meta-analysis to study competition in field experiments.[28][29] The field of meta-analysis has expanded greatly since the 1970s and touches multiple disciplines including psychology, medicine, and ecology.[22] Further the more recent creation of evidence synthesis communities has increased the cross pollination of ideas, methods, and the creation of software tools across disciplines.[30][31][32]

Steps in a meta-analysis

A meta-analysis is usually preceded by a systematic review, as this allows identification and critical appraisal of all the relevant evidence (thereby limiting the risk of bias in summary estimates). The general steps are then as follows:[1]

  1. Formulation of the research question, e.g. using the PICO model (Population, Intervention, Comparison, Outcome).
  2. Search of literature
  3. Selection of studies ('incorporation criteria')
    1. Based on quality criteria, e.g. the requirement of randomization and blinding in a clinical trial
    2. Selection of specific studies on a well-specified subject, e.g. the treatment of breast cancer.
    3. Decide whether unpublished studies are included to avoid publication bias (file drawer problem)
  4. Decide which dependent variables or summary measures are allowed. For instance, when considering a meta-analysis of published (aggregate) data:
    • Differences (discrete data)
    • Means (continuous data)
    • Hedges' g is a popular summary measure for continuous data that is standardized in order to eliminate scale differences, but it incorporates an index of variation between groups:
      1.   in which   is the treatment mean,   is the control mean,   the pooled variance.
  5. Selection of a meta-analysis model, e.g. fixed effect or random effects meta-analysis.
  6. Examine sources of between-study heterogeneity, e.g. using subgroup analysis or meta-regression.

Formal guidance for the conduct and reporting of meta-analyses is provided by the Cochrane Handbook.

For reporting guidelines, see the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement.[33]

Methods and assumptions

Approaches

In general, two types of evidence can be distinguished when performing a meta-analysis: individual participant data (IPD), and aggregate data (AD). The aggregate data can be direct or indirect.

AD is more commonly available (e.g. from the literature) and typically represents summary estimates such as odds ratios or relative risks. This can be directly synthesized across conceptually similar studies using several approaches (see below). On the other hand, indirect aggregate data measures the effect of two treatments that were each compared against a similar control group in a meta-analysis. For example, if treatment A and treatment B were directly compared vs placebo in separate meta-analyses, we can use these two pooled results to get an estimate of the effects of A vs B in an indirect comparison as effect A vs Placebo minus effect B vs Placebo.

IPD evidence represents raw data as collected by the study centers. This distinction has raised the need for different meta-analytic methods when evidence synthesis is desired, and has led to the development of one-stage and two-stage methods.[34] In one-stage methods the IPD from all studies are modeled simultaneously whilst accounting for the clustering of participants within studies. Two-stage methods first compute summary statistics for AD from each study and then calculate overall statistics as a weighted average of the study statistics. By reducing IPD to AD, two-stage methods can also be applied when IPD is available; this makes them an appealing choice when performing a meta-analysis. Although it is conventionally believed that one-stage and two-stage methods yield similar results, recent studies have shown that they may occasionally lead to different conclusions.[35][36]

Statistical models for aggregate data

Direct evidence: Models incorporating study effects only

Fixed effects model

The fixed effect model provides a weighted average of a series of study estimates. The inverse of the estimates' variance is commonly used as study weight, so that larger studies tend to contribute more than smaller studies to the weighted average. Consequently, when studies within a meta-analysis are dominated by a very large study, the findings from smaller studies are practically ignored.[37] Most importantly, the fixed effects model assumes that all included studies investigate the same population, use the same variable and outcome definitions, etc. This assumption is typically unrealistic as research is often prone to several sources of heterogeneity; e.g. treatment effects may differ according to locale, dosage levels, study conditions, ...

Random effects model

A common model used to synthesize heterogeneous research is the random effects model of meta-analysis. This is simply the weighted average of the effect sizes of a group of studies. The weight that is applied in this process of weighted averaging with a random effects meta-analysis is achieved in two steps:[38]

  1. Step 1: Inverse variance weighting
  2. Step 2: Un-weighting of this inverse variance weighting by applying a random effects variance component (REVC) that is simply derived from the extent of variability of the effect sizes of the underlying studies.

This means that the greater this variability in effect sizes (otherwise known as heterogeneity), the greater the un-weighting and this can reach a point when the random effects meta-analysis result becomes simply the un-weighted average effect size across the studies. At the other extreme, when all effect sizes are similar (or variability does not exceed sampling error), no REVC is applied and the random effects meta-analysis defaults to simply a fixed effect meta-analysis (only inverse variance weighting).

The extent of this reversal is solely dependent on two factors:[39]

  1. Heterogeneity of precision
  2. Heterogeneity of effect size

Since neither of these factors automatically indicates a faulty larger study or more reliable smaller studies, the re-distribution of weights under this model will not bear a relationship to what these studies actually might offer. Indeed, it has been demonstrated that redistribution of weights is simply in one direction from larger to smaller studies as heterogeneity increases until eventually all studies have equal weight and no more redistribution is possible.[39] Another issue with the random effects model is that the most commonly used confidence intervals generally do not retain their coverage probability above the specified nominal level and thus substantially underestimate the statistical error and are potentially overconfident in their conclusions.[40][41] Several fixes have been suggested[42][43] but the debate continues on.[41][44] A further concern is that the average treatment effect can sometimes be even less conservative compared to the fixed effect model[45] and therefore misleading in practice. One interpretational fix that has been suggested is to create a prediction interval around the random effects estimate to portray the range of possible effects in practice.[46] However, an assumption behind the calculation of such a prediction interval is that trials are considered more or less homogeneous entities and that included patient populations and comparator treatments should be considered exchangeable[47] and this is usually unattainable in practice.

There are many methods used to estimate between studies variance with restricted maximum likelihood estimator being the least prone to bias and one of the most commonly used.[48] Several advanced iterative techniques for computing the between studies variance exist including both maximum likelihood and restricted maximum likelihood method and random effects models using these methods can be run with multiples software platforms including in Excel,[49] Stata,[50] SPSS,[51] and R.[52]

Most meta-analyses include between 2 and 4 studies and such a sample is more often than not inadequate to accurately estimate heterogeneity. Thus it appears that in small meta-analyses, an incorrect zero between study variance estimate is obtained, leading to a false homogeneity assumption. Overall, it appears that heterogeneity is being consistently underestimated in meta-analyses and sensitivity analyses in which high heterogeneity levels are assumed could be informative.[53] These random effects models and software packages mentioned above relate to study-aggregate meta-analyses and researchers wishing to conduct individual patient data (IPD) meta-analyses need to consider mixed-effects modelling approaches.[54]

IVhet model

Doi & Barendregt working in collaboration with Khan, Thalib and Williams (from the University of Queensland, University of Southern Queensland and Kuwait University), have created an inverse variance quasi likelihood based alternative (IVhet) to the random effects (RE) model for which details are available online.[49] This was incorporated into MetaXL version 2.0,[55] a free Microsoft excel add-in for meta-analysis produced by Epigear International Pty Ltd, and made available on 5 April 2014. The authors state that a clear advantage of this model is that it resolves the two main problems of the random effects model. The first advantage of the IVhet model is that coverage remains at the nominal (usually 95%) level for the confidence interval unlike the random effects model which drops in coverage with increasing heterogeneity.[40][41] The second advantage is that the IVhet model maintains the inverse variance weights of individual studies, unlike the RE model which gives small studies more weight (and therefore larger studies less) with increasing heterogeneity. When heterogeneity becomes large, the individual study weights under the RE model become equal and thus the RE model returns an arithmetic mean rather than a weighted average. This side-effect of the RE model does not occur with the IVhet model which thus differs from the RE model estimate in two perspectives:[49] Pooled estimates will favor larger trials (as opposed to penalizing larger trials in the RE model) and will have a confidence interval that remains within the nominal coverage under uncertainty (heterogeneity). Doi & Barendregt suggest that while the RE model provides an alternative method of pooling the study data, their simulation results[56] demonstrate that using a more specified probability model with untenable assumptions, as with the RE model, does not necessarily provide better results. The latter study also reports that the IVhet model resolves the problems related to underestimation of the statistical error, poor coverage of the confidence interval and increased MSE seen with the random effects model and the authors conclude that researchers should henceforth abandon use of the random effects model in meta-analysis. While their data is compelling, the ramifications (in terms of the magnitude of spuriously positive results within the Cochrane database) are huge and thus accepting this conclusion requires careful independent confirmation. The availability of a free software (MetaXL)[55] that runs the IVhet model (and all other models for comparison) facilitates this for the research community.

Direct evidence: Models incorporating additional information

Quality effects model

Doi and Thalib originally introduced the quality effects model.[57] They[58] introduced a new approach to adjustment for inter-study variability by incorporating the contribution of variance due to a relevant component (quality) in addition to the contribution of variance due to random error that is used in any fixed effects meta-analysis model to generate weights for each study. The strength of the quality effects meta-analysis is that it allows available methodological evidence to be used over subjective random effects, and thereby helps to close the damaging gap which has opened up between methodology and statistics in clinical research. To do this a synthetic bias variance is computed based on quality information to adjust inverse variance weights and the quality adjusted weight of the ith study is introduced.[57] These adjusted weights are then used in meta-analysis. In other words, if study i is of good quality and other studies are of poor quality, a proportion of their quality adjusted weights is mathematically redistributed to study i giving it more weight towards the overall effect size. As studies become increasingly similar in terms of quality, re-distribution becomes progressively less and ceases when all studies are of equal quality (in the case of equal quality, the quality effects model defaults to the IVhet model – see previous section). A recent evaluation of the quality effects model (with some updates) demonstrates that despite the subjectivity of quality assessment, the performance (MSE and true variance under simulation) is superior to that achievable with the random effects model.[59][60] This model thus replaces the untenable interpretations that abound in the literature and a software is available to explore this method further.[55]

Indirect evidence: Network meta-analysis methods

 
A network meta-analysis looks at indirect comparisons. In the image, A has been analyzed in relation to C and C has been analyzed in relation to b. However the relation between A and B is only known indirectly, and a network meta-analysis looks at such indirect evidence of differences between methods and interventions using statistical method.

Indirect comparison meta-analysis methods (also called network meta-analyses, in particular when multiple treatments are assessed simultaneously) generally use two main methodologies. First, is the Bucher method[61] which is a single or repeated comparison of a closed loop of three-treatments such that one of them is common to the two studies and forms the node where the loop begins and ends. Therefore, multiple two-by-two comparisons (3-treatment loops) are needed to compare multiple treatments. This methodology requires that trials with more than two arms have two arms only selected as independent pair-wise comparisons are required. The alternative methodology uses complex statistical modelling to include the multiple arm trials and comparisons simultaneously between all competing treatments. These have been executed using Bayesian methods, mixed linear models and meta-regression approaches.[citation needed]

Bayesian framework

Specifying a Bayesian network meta-analysis model involves writing a directed acyclic graph (DAG) model for general-purpose Markov chain Monte Carlo (MCMC) software such as WinBUGS.[62] In addition, prior distributions have to be specified for a number of the parameters, and the data have to be supplied in a specific format.[62] Together, the DAG, priors, and data form a Bayesian hierarchical model. To complicate matters further, because of the nature of MCMC estimation, overdispersed starting values have to be chosen for a number of independent chains so that convergence can be assessed.[63] Recently, multiple R software packages were developed to simplify the model fitting (e.g., metaBMA[64] and RoBMA[65]) and even implemented in statistical software with graphical user interface (GUI): JASP. Although the complexity of the Bayesian approach limits usage of this methodology, recent tutorial papers are trying to increase accessibility of the methods.[66][67] Methodology for automation of this method has been suggested[62] but requires that arm-level outcome data are available, and this is usually unavailable. Great claims are sometimes made for the inherent ability of the Bayesian framework to handle network meta-analysis and its greater flexibility. However, this choice of implementation of framework for inference, Bayesian or frequentist, may be less important than other choices regarding the modeling of effects[68] (see discussion on models above).

Frequentist multivariate framework

On the other hand, the frequentist multivariate methods involve approximations and assumptions that are not stated explicitly or verified when the methods are applied (see discussion on meta-analysis models above). For example, the mvmeta package for Stata enables network meta-analysis in a frequentist framework.[69] However, if there is no common comparator in the network, then this has to be handled by augmenting the dataset with fictional arms with high variance, which is not very objective and requires a decision as to what constitutes a sufficiently high variance.[62] The other issue is use of the random effects model in both this frequentist framework and the Bayesian framework. Senn advises analysts to be cautious about interpreting the 'random effects' analysis since only one random effect is allowed for but one could envisage many.[68] Senn goes on to say that it is rather naıve, even in the case where only two treatments are being compared to assume that random-effects analysis accounts for all uncertainty about the way effects can vary from trial to trial. Newer models of meta-analysis such as those discussed above would certainly help alleviate this situation and have been implemented in the next framework.

Generalized pairwise modelling framework

An approach that has been tried since the late 1990s is the implementation of the multiple three-treatment closed-loop analysis. This has not been popular because the process rapidly becomes overwhelming as network complexity increases. Development in this area was then abandoned in favor of the Bayesian and multivariate frequentist methods which emerged as alternatives. Very recently, automation of the three-treatment closed loop method has been developed for complex networks by some researchers[49] as a way to make this methodology available to the mainstream research community. This proposal does restrict each trial to two interventions, but also introduces a workaround for multiple arm trials: a different fixed control node can be selected in different runs. It also utilizes robust meta-analysis methods so that many of the problems highlighted above are avoided. Further research around this framework is required to determine if this is indeed superior to the Bayesian or multivariate frequentist frameworks. Researchers willing to try this out have access to this framework through a free software.[55]

Tailored meta-analysis

Another form of additional information comes from the intended setting. If the target setting for applying the meta-analysis results is known then it may be possible to use data from the setting to tailor the results thus producing a 'tailored meta-analysis'.,[70][71] This has been used in test accuracy meta-analyses, where empirical knowledge of the test positive rate and the prevalence have been used to derive a region in Receiver Operating Characteristic (ROC) space known as an 'applicable region'. Studies are then selected for the target setting based on comparison with this region and aggregated to produce a summary estimate which is tailored to the target setting.

Aggregating IPD and AD

Meta-analysis can also be applied to combine IPD and AD. This is convenient when the researchers who conduct the analysis have their own raw data while collecting aggregate or summary data from the literature. The generalized integration model (GIM)[72] is a generalization of the meta-analysis. It allows that the model fitted on the individual participant data (IPD) is different from the ones used to compute the aggregate data (AD). GIM can be viewed as a model calibration method for integrating information with more flexibility.

Validation of meta-analysis results

The meta-analysis estimate represents a weighted average across studies and when there is heterogeneity this may result in the summary estimate not being representative of individual studies. Qualitative appraisal of the primary studies using established tools can uncover potential biases,[73][74] but does not quantify the aggregate effect of these biases on the summary estimate. Although the meta-analysis result could be compared with an independent prospective primary study, such external validation is often impractical. This has led to the development of methods that exploit a form of leave-one-out cross validation, sometimes referred to as internal-external cross validation (IOCV).[75] Here each of the k included studies in turn is omitted and compared with the summary estimate derived from aggregating the remaining k- 1 studies. A general validation statistic, Vn based on IOCV has been developed to measure the statistical validity of meta-analysis results.[76] For test accuracy and prediction, particularly when there are multivariate effects, other approaches which seek to estimate the prediction error have also been proposed.[77]

Challenges

A meta-analysis of several small studies does not always predict the results of a single large study.[78] Some have argued that a weakness of the method is that sources of bias are not controlled by the method: a good meta-analysis cannot correct for poor design or bias in the original studies.[79] This would mean that only methodologically sound studies should be included in a meta-analysis, a practice called 'best evidence synthesis'.[79] Other meta-analysts would include weaker studies, and add a study-level predictor variable that reflects the methodological quality of the studies to examine the effect of study quality on the effect size.[80] However, others have argued that a better approach is to preserve information about the variance in the study sample, casting as wide a net as possible, and that methodological selection criteria introduce unwanted subjectivity, defeating the purpose of the approach.[81]

Publication bias: the file drawer problem

 
A funnel plot expected without the file drawer problem. The largest studies converge at the tip while smaller studies show more or less symmetrical scatter at the base
 
A funnel plot expected with the file drawer problem. The largest studies still cluster around the tip, but the bias against publishing negative studies has caused the smaller studies as a whole to have an unjustifiably favorable result to the hypothesis

Another potential pitfall is the reliance on the available body of published studies, which may create exaggerated outcomes due to publication bias, as studies which show negative results or insignificant results are less likely to be published.[82] For example, pharmaceutical companies have been known to hide negative studies and researchers may have overlooked unpublished studies such as dissertation studies or conference abstracts that did not reach publication. This is not easily solved, as one cannot know how many studies have gone unreported.[83]

This file drawer problem (characterized by negative or non-significant results being tucked away in a cabinet), can result in a biased distribution of effect sizes thus creating a serious base rate fallacy, in which the significance of the published studies is overestimated, as other studies were either not submitted for publication or were rejected. This should be seriously considered when interpreting the outcomes of a meta-analysis.[83][6]

The distribution of effect sizes can be visualized with a funnel plot which (in its most common version) is a scatter plot of standard error versus the effect size. It makes use of the fact that the smaller studies (thus larger standard errors) have more scatter of the magnitude of effect (being less precise) while the larger studies have less scatter and form the tip of the funnel. If many negative studies were not published, the remaining positive studies give rise to a funnel plot in which the base is skewed to one side (asymmetry of the funnel plot). In contrast, when there is no publication bias, the effect of the smaller studies has no reason to be skewed to one side and so a symmetric funnel plot results. This also means that if no publication bias is present, there would be no relationship between standard error and effect size.[84] A negative or positive relation between standard error and effect size would imply that smaller studies that found effects in one direction only were more likely to be published and/or to be submitted for publication.

Apart from the visual funnel plot, statistical methods for detecting publication bias have also been proposed.[85] These are controversial because they typically have low power for detection of bias, but also may make false positives under some circumstances.[86] For instance small study effects (biased smaller studies), wherein methodological differences between smaller and larger studies exist, may cause asymmetry in effect sizes that resembles publication bias. However, small study effects may be just as problematic for the interpretation of meta-analyses, and the imperative is on meta-analytic authors to investigate potential sources of bias.[87]

A Tandem Method for analyzing publication bias has been suggested for cutting down false positive error problems.[88] This Tandem method consists of three stages. Firstly, one calculates Orwin's fail-safe N, to check how many studies should be added in order to reduce the test statistic to a trivial size. If this number of studies is larger than the number of studies used in the meta-analysis, it is a sign that there is no publication bias, as in that case, one needs a lot of studies to reduce the effect size. Secondly, one can do an Egger's regression test, which tests whether the funnel plot is symmetrical. As mentioned before: a symmetrical funnel plot is a sign that there is no publication bias, as the effect size and sample size are not dependent. Thirdly, one can do the trim-and-fill method, which imputes data if the funnel plot is asymmetrical.

The problem of publication bias is not trivial as it is suggested that 25% of meta-analyses in the psychological sciences may have suffered from publication bias.[88] However, low power of existing tests and problems with the visual appearance of the funnel plot remain an issue, and estimates of publication bias may remain lower than what truly exists.

Most discussions of publication bias focus on journal practices favoring publication of statistically significant findings. However, questionable research practices, such as reworking statistical models until significance is achieved, may also favor statistically significant findings in support of researchers' hypotheses.[89][90]

Problems related to studies not reporting non-statistically significant effects

Studies often do not report the effects when they do not reach statistical significance[citation needed]. For example, they may simply say that the groups did not show statistically significant differences, without reporting any other information (e.g. a statistic or p-value). Exclusion of these studies would lead to a situation similar to publication bias, but their inclusion (assuming null effects) would also bias the meta-analysis. MetaNSUE, a method created by Joaquim Radua, has shown to allow researchers to include unbiasedly these studies.[91] Its steps are as follows:

Problems related to the statistical approach

Other weaknesses are that it has not been determined if the statistically most accurate method for combining results is the fixed, IVhet, random or quality effect models, though the criticism against the random effects model is mounting because of the perception that the new random effects (used in meta-analysis) are essentially formal devices to facilitate smoothing or shrinkage and prediction may be impossible or ill-advised.[92] The main problem with the random effects approach is that it uses the classic statistical thought of generating a "compromise estimator" that makes the weights close to the naturally weighted estimator if heterogeneity across studies is large but close to the inverse variance weighted estimator if the between study heterogeneity is small. However, what has been ignored is the distinction between the model we choose to analyze a given dataset, and the mechanism by which the data came into being.[93] A random effect can be present in either of these roles, but the two roles are quite distinct. There's no reason to think the analysis model and data-generation mechanism (model) are similar in form, but many sub-fields of statistics have developed the habit of assuming, for theory and simulations, that the data-generation mechanism (model) is identical to the analysis model we choose (or would like others to choose). As a hypothesized mechanisms for producing the data, the random effect model for meta-analysis is silly and it is more appropriate to think of this model as a superficial description and something we choose as an analytical tool – but this choice for meta-analysis may not work because the study effects are a fixed feature of the respective meta-analysis and the probability distribution is only a descriptive tool.[93]

Problems arising from agenda-driven bias

The most severe fault in meta-analysis often occurs when the person or persons doing the meta-analysis have an economic, social, or political agenda such as the passage or defeat of legislation. People with these types of agendas may be more likely to abuse meta-analysis due to personal bias. For example, researchers favorable to the author's agenda are likely to have their studies cherry-picked while those not favorable will be ignored or labeled as "not credible". In addition, the favored authors may themselves be biased or paid to produce results that support their overall political, social, or economic goals in ways such as selecting small favorable data sets and not incorporating larger unfavorable data sets. The influence of such biases on the results of a meta-analysis is possible because the methodology of meta-analysis is highly malleable.[10]

A 2011 study done to disclose possible conflicts of interests in underlying research studies used for medical meta-analyses reviewed 29 meta-analyses and found that conflicts of interests in the studies underlying the meta-analyses were rarely disclosed. The 29 meta-analyses included 11 from general medicine journals, 15 from specialty medicine journals, and three from the Cochrane Database of Systematic Reviews. The 29 meta-analyses reviewed a total of 509 randomized controlled trials (RCTs). Of these, 318 RCTs reported funding sources, with 219 (69%) receiving funding from industry (i.e. one or more authors having financial ties to the pharmaceutical industry). Of the 509 RCTs, 132 reported author conflict of interest disclosures, with 91 studies (69%) disclosing one or more authors having financial ties to industry. The information was, however, seldom reflected in the meta-analyses. Only two (7%) reported RCT funding sources and none reported RCT author-industry ties. The authors concluded "without acknowledgment of COI due to industry funding or author industry financial ties from RCTs included in meta-analyses, readers' understanding and appraisal of the evidence from the meta-analysis may be compromised."[94]

For example, in 1998, a US federal judge found that the United States Environmental Protection Agency had abused the meta-analysis process to produce a study claiming cancer risks to non-smokers from environmental tobacco smoke (ETS) with the intent to influence policy makers to pass smoke-free–workplace laws. The judge found that:

EPA's study selection is disturbing. First, there is evidence in the record supporting the accusation that EPA "cherry picked" its data. Without criteria for pooling studies into a meta-analysis, the court cannot determine whether the exclusion of studies likely to disprove EPA's a priori hypothesis was coincidence or intentional. Second, EPA's excluding nearly half of the available studies directly conflicts with EPA's purported purpose for analyzing the epidemiological studies and conflicts with EPA's Risk Assessment Guidelines. See ETS Risk Assessment at 4-29 ("These data should also be examined in the interest of weighing all the available evidence, as recommended by EPA's carcinogen risk assessment guidelines (U.S. EPA, 1986a) (emphasis added)). Third, EPA's selective use of data conflicts with the Radon Research Act. The Act states EPA's program shall "gather data and information on all aspects of indoor air quality" (Radon Research Act § 403(a)(1)) (emphasis added).[95]

As a result of the abuse, the court vacated Chapters 1–6 of and the Appendices to EPA's "Respiratory Health Effects of Passive Smoking: Lung Cancer and other Disorders".[95]

Comparability and validity of included studies

Meta-analysis may often not be a substitute for an adequately powered primary study.[96]

Heterogeneity of methods used may lead to faulty conclusions.[97] For instance, differences in the forms of an intervention or the cohorts that are thought to be minor or are unknown to the scientists could lead to substantially different results, including results that distort the meta-analysis' results or are not adequately considered in its data. Vice versa, results from meta-analyses may also make certain hypothesis or interventions seem nonviable and preempt further research or approvals, despite certain modifications – such as intermittent administration, personalized criteria and combination measures – leading to substantially different results, including in cases where such have been successfully identified and applied in small-scale studies that were considered in the meta-analysis.[citation needed] Standardization, reproduction of experiments, open data and open protocols may often not mitigate such problems, for instance as relevant factors and criteria could be unknown or not be recorded.[citation needed]

There is a debate about the appropriate balance between testing with as few animals or humans as possible and the need to obtain robust, reliable findings. It has been argued that unreliable research is inefficient and wasteful and that studies are not just wasteful when they stop too late but also when they stop too early. In large clinical trials, planned, sequential analyses are sometimes used if there is considerable expense or potential harm associated with testing participants.[98] In applied behavioural science, "megastudies" have been proposed to investigate the efficacy of many different interventions designed in an interdisciplinary manner by separate teams.[99] One such study used a fitness chain to recruit a large number participants. It has been suggested that behavioural interventions are often hard to compare [in meta-analyses and reviews], as "different scientists test different intervention ideas in different samples using different outcomes over different time intervals", causing a lack of comparability of such individual investigations which limits "their potential to inform policy".[99]

Weak inclusion standards lead to misleading conclusions

Meta-analyses in education are often not restrictive enough in regards to the methodological quality of the studies they include. For example, studies that include small samples or researcher-made measures lead to inflated effect size estimates.[100] However, this problem also troubles meta-analysis of clinical trials. The use of different quality assessment tools (QATs) lead to including different studies and obtaining conflicting estimates of average treatment effects.[101][102]

Applications in modern science

Modern statistical meta-analysis does more than just combine the effect sizes of a set of studies using a weighted average. It can test if the outcomes of studies show more variation than the variation that is expected because of the sampling of different numbers of research participants. Additionally, study characteristics such as measurement instrument used, population sampled, or aspects of the studies' design can be coded and used to reduce variance of the estimator (see statistical models above). Thus some methodological weaknesses in studies can be corrected statistically. Other uses of meta-analytic methods include the development and validation of clinical prediction models, where meta-analysis may be used to combine individual participant data from different research centers and to assess the model's generalisability,[103][104] or even to aggregate existing prediction models.[105]

Meta-analysis can be done with single-subject design as well as group research designs.[106] This is important because much research has been done with single-subject research designs.[107] Considerable dispute exists for the most appropriate meta-analytic technique for single subject research.[108]

Meta-analysis leads to a shift of emphasis from single studies to multiple studies. It emphasizes the practical importance of the effect size instead of the statistical significance of individual studies. This shift in thinking has been termed "meta-analytic thinking". The results of a meta-analysis are often shown in a forest plot.

Results from studies are combined using different approaches. One approach frequently used in meta-analysis in health care research is termed 'inverse variance method'. The average effect size across all studies is computed as a weighted mean, whereby the weights are equal to the inverse variance of each study's effect estimator. Larger studies and studies with less random variation are given greater weight than smaller studies. Other common approaches include the Mantel–Haenszel method[109] and the Peto method.[110]

Seed-based d mapping (formerly signed differential mapping, SDM) is a statistical technique for meta-analyzing studies on differences in brain activity or structure which used neuroimaging techniques such as fMRI, VBM or PET.

Different high throughput techniques such as microarrays have been used to understand Gene expression. MicroRNA expression profiles have been used to identify differentially expressed microRNAs in particular cell or tissue type or disease conditions or to check the effect of a treatment. A meta-analysis of such expression profiles was performed to derive novel conclusions and to validate the known findings.[111]

See also

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Further reading

  • Cornell JE, Mulrow CD (1999). "Meta-analysis". In Mellenbergh GJ (ed.). Research methodology in the life, behavioural, and social sciences. London: SAGE. pp. 285–323. ISBN 978-0-7619-5883-3.
  • Ellis PD (2010). The Essential Guide to Effect Sizes: An Introduction to Statistical Power, Meta-Analysis and the Interpretation of Research Results. Cambridge: Cambridge University Press. ISBN 978-0-521-14246-5.
  • Sutton AJ, Jones DR, Abrams KR, Sheldon TA, Song F (2000). Methods for meta-analysis in medical research. London: John Wiley. ISBN 978-0-471-49066-1.
  • Wilson DB, Lipsey MW (2001). Practical meta-analysis. Thousand Oaks: Sage publications. ISBN 978-0-7619-2168-4.
  • Cooper H, Hedges LV, eds. (1994). The Handbook of Research Synthesis. New York: Russell Sage Foundation. ISBN 978-0-87154-226-7.
  • Bonett DG (December 2010). "Varying coefficient meta-analytic methods for alpha reliability". Psychological Methods. 15 (4): 368–385. doi:10.1037/a0020142. PMID 20853952. S2CID 207710319.
  • Bonett DG, Price RM (November 2014). "Meta-analysis methods for risk differences". The British Journal of Mathematical and Statistical Psychology. 67 (3): 371–387. doi:10.1111/bmsp.12024. PMID 23962020.
  • Bonett DG (September 2008). "Meta-analytic interval estimation for bivariate correlations". Psychological Methods. 13 (3): 173–181. doi:10.1037/a0012868. PMID 18778150. S2CID 5690835.
  • Bonett DG (September 2009). "Meta-analytic interval estimation for standardized and unstandardized mean differences". Psychological Methods. 14 (3): 225–238. doi:10.1037/a0016619. PMID 19719359.
  • Bonett DG, Price RM (September 2015). "Varying coefficient meta-analysis methods for odds ratios and risk ratios". Psychological Methods. 20 (3): 394–406. doi:10.1037/met0000032. PMID 25751513.
  • Bonett DG (November 2020). "Point-biserial correlation: Interval estimation, hypothesis testing, meta-analysis, and sample size determination". The British Journal of Mathematical and Statistical Psychology. 73 Suppl 1 (Suppl 1): 113–144. doi:10.1111/bmsp.12189. PMID 31565811. S2CID 203607297.
  • Normand SL (February 1999). "Meta-analysis: formulating, evaluating, combining, and reporting". Statistics in Medicine. 18 (3): 321–359. doi:10.1002/(SICI)1097-0258(19990215)18:3<321::AID-SIM28>3.0.CO;2-P. PMID 10070677.
  • Owen AB (December 2009). (PDF). The Annals of Statistics. 37 (6B): 3867–2892. arXiv:0911.3531. doi:10.1214/09-AOS697. S2CID 7632667. Archived from the original (PDF) on 26 July 2011.
  • Slough, Tara; Tyson, Scott A. (2022). "External Validity and Meta‐Analysis". American Journal of Political Science. doi:10.1111/ajps.12742. ISSN 0092-5853.
  • Thompson SG, Pocock SJ (November 1991). (PDF). Lancet. 338 (8775): 1127–1130. doi:10.1016/0140-6736(91)91975-Z. PMID 1682553. S2CID 29743240. Archived from the original (PDF) on 22 November 2011. Retrieved 17 June 2011.. Explores two contrasting views: does meta-analysis provide "objective, quantitative methods for combining evidence from separate but similar studies" or merely "statistical tricks which make unjustified assumptions in producing oversimplified generalisations out of a complex of disparate studies"?
  • O'Rourke K (2007). (PDF). Oxford: University of Oxford, Department of Statistics. Archived from the original (PDF) on 2 November 2011. Gives technical background material and details on the "An historical perspective on meta-analysis" paper cited in the references.

External links

 
Wikiversity has learning resources about Meta-analysis
  • Cochrane Handbook for Systematic Reviews of Interventions
  • Meta-Analysis at 25 (Gene V Glass)
  • Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) Statement 27 July 2011 at the Wayback Machine – "an evidence-based minimum set of items for reporting in systematic reviews and meta-analyses."
  • "metansue" R package and graphical interface
  • Best Evidence Encyclopedia

January 11, 2023
meta, analysis, process, historical, linguistics, known, metanalysis, rebracketing, meta, analysis, statistical, analysis, that, combines, results, multiple, scientific, studies, meta, analyses, performed, when, there, multiple, scientific, studies, addressing. For the process in historical linguistics known as metanalysis see Rebracketing A meta analysis is a statistical analysis that combines the results of multiple scientific studies Meta analyses can be performed when there are multiple scientific studies addressing the same question with each individual study reporting measurements that are expected to have some degree of error The aim then is to use approaches from statistics to derive a pooled estimate closest to the unknown common truth based on how this error is perceived Meta analytic results are considered the most trustworthy source of evidence by the evidence based medicine literature 1 2 3 Graphical summary of a meta analysis of over 1 000 cases of diffuse intrinsic pontine glioma and other pediatric gliomas in which information about the mutations involved as well as generic outcomes were distilled from the underlying primary literature Not only can meta analyses provide an estimate of the unknown effect size it also has the capacity to contrast results from different studies and identify patterns among study results sources of disagreement among those results or other interesting relationships that may come to light with multiple studies 4 However there are some methodological problems with meta analysis If individual studies are systematically biased due to questionable research practices e g data dredging data peeking dropping studies or the publication bias at the journal level the meta analytic estimate of the overall treatment effect may not reflect the actual efficacy of a treatment 5 6 Meta analysis has also been criticized for averaging differences among heterogeneous studies because these differences could potentially inform clinical decisions 7 For example if there are two groups of patients experiencing different treatment effects studies in two randomised control trials RCTs reporting conflicting results the meta analytic average is representative of neither group similarly to averaging the weight of apples and oranges which is neither accurate for apples nor oranges 8 In performing a meta analysis an investigator must make choices which can affect the results including deciding how to search for studies selecting studies based on a set of objective criteria dealing with incomplete data analyzing the data and accounting for or choosing not to account for publication bias 9 This makes meta analysis malleable in the sense that these methodological choices made in completing a meta analysis are not determined but may affect the results 10 For example Wanous and colleagues examined four pairs of meta analyses on the four topics of a job performance and satisfaction relationship b realistic job previews c correlates of role conflict and ambiguity and d the job satisfaction and absenteeism relationship and illustrated how various judgement calls made by the researchers produced different results 11 Meta analyses are often but not always important components of a systematic review procedure For instance a meta analysis may be conducted on several clinical trials of a medical treatment in an effort to obtain a better understanding of how well the treatment works Here it is convenient to follow the terminology used by the Cochrane Collaboration 12 and use meta analysis to refer to statistical methods of combining evidence leaving other aspects of research synthesis or evidence synthesis such as combining information from qualitative studies for the more general context of systematic reviews A meta analysis is a secondary source 13 14 In addition meta analysis may also be applied to a single study in cases where there are many cohorts which have not gone through identical selection criteria or to which the same investigational methodologies have not been applied to all in the same manner or under the same exacting conditions Under these circumstances each cohort is treated as an individual study and meta analysis is used to draw study wide conclusions 15 Contents 1 History 2 Steps in a meta analysis 3 Methods and assumptions 3 1 Approaches 3 2 Statistical models for aggregate data 3 2 1 Direct evidence Models incorporating study effects only 3 2 1 1 Fixed effects model 3 2 1 2 Random effects model 3 2 1 3 IVhet model 3 2 2 Direct evidence Models incorporating additional information 3 2 2 1 Quality effects model 3 2 3 Indirect evidence Network meta analysis methods 3 2 3 1 Bayesian framework 3 2 3 2 Frequentist multivariate framework 3 2 3 3 Generalized pairwise modelling framework 3 2 3 4 Tailored meta analysis 3 2 4 Aggregating IPD and AD 3 3 Validation of meta analysis results 4 Challenges 4 1 Publication bias the file drawer problem 4 2 Problems related to studies not reporting non statistically significant effects 4 3 Problems related to the statistical approach 4 4 Problems arising from agenda driven bias 4 5 Comparability and validity of included studies 4 6 Weak inclusion standards lead to misleading conclusions 5 Applications in modern science 6 See also 7 References 8 Further reading 9 External linksHistory EditThe historical roots of meta analysis can be traced back to 17th century studies of astronomy 16 while a paper published in 1904 by the statistician Karl Pearson in the British Medical Journal 17 which collated data from several studies of typhoid inoculation is seen as the first time a meta analytic approach was used to aggregate the outcomes of multiple clinical studies 18 19 The first meta analysis of all conceptually identical experiments concerning a particular research issue and conducted by independent researchers has been identified as the 1940 book length publication Extrasensory Perception After Sixty Years authored by Duke University psychologists J G Pratt J B Rhine and associates 20 This encompassed a review of 145 reports on ESP experiments published from 1882 to 1939 and included an estimate of the influence of unpublished papers on the overall effect the file drawer problem The term meta analysis was coined in 1976 by the statistician Gene V Glass 21 22 23 who stated my major interest currently is in what we have come to call the meta analysis of research The term is a bit grand but it is precise and apt Meta analysis refers to the analysis of analyses Although this led to him being widely recognized as the modern founder of the method the methodology behind what he termed meta analysis predates his work by several decades 24 25 The statistical theory surrounding meta analysis was greatly advanced by the work of Nambury S Raju Larry V Hedges Harris Cooper Ingram Olkin John E Hunter Jacob Cohen Thomas C Chalmers Robert Rosenthal Frank L Schmidt John E Hunter and Douglas G Claurett 23 26 clarification needed In 1992 meta analysis was first applied to ecological questions 27 by Jessica Gurevitch who used meta analysis to study competition in field experiments 28 29 The field of meta analysis has expanded greatly since the 1970s and touches multiple disciplines including psychology medicine and ecology 22 Further the more recent creation of evidence synthesis communities has increased the cross pollination of ideas methods and the creation of software tools across disciplines 30 31 32 Steps in a meta analysis EditA meta analysis is usually preceded by a systematic review as this allows identification and critical appraisal of all the relevant evidence thereby limiting the risk of bias in summary estimates The general steps are then as follows 1 Formulation of the research question e g using the PICO model Population Intervention Comparison Outcome Search of literature Selection of studies incorporation criteria Based on quality criteria e g the requirement of randomization and blinding in a clinical trial Selection of specific studies on a well specified subject e g the treatment of breast cancer Decide whether unpublished studies are included to avoid publication bias file drawer problem Decide which dependent variables or summary measures are allowed For instance when considering a meta analysis of published aggregate data Differences discrete data Means continuous data Hedges g is a popular summary measure for continuous data that is standardized in order to eliminate scale differences but it incorporates an index of variation between groups d m t m c s displaystyle delta frac mu t mu c sigma in which m t displaystyle mu t is the treatment mean m c displaystyle mu c is the control mean s 2 displaystyle sigma 2 the pooled variance Selection of a meta analysis model e g fixed effect or random effects meta analysis Examine sources of between study heterogeneity e g using subgroup analysis or meta regression Formal guidance for the conduct and reporting of meta analyses is provided by the Cochrane Handbook For reporting guidelines see the Preferred Reporting Items for Systematic Reviews and Meta Analyses PRISMA statement 33 Methods and assumptions EditApproaches Edit In general two types of evidence can be distinguished when performing a meta analysis individual participant data IPD and aggregate data AD The aggregate data can be direct or indirect AD is more commonly available e g from the literature and typically represents summary estimates such as odds ratios or relative risks This can be directly synthesized across conceptually similar studies using several approaches see below On the other hand indirect aggregate data measures the effect of two treatments that were each compared against a similar control group in a meta analysis For example if treatment A and treatment B were directly compared vs placebo in separate meta analyses we can use these two pooled results to get an estimate of the effects of A vs B in an indirect comparison as effect A vs Placebo minus effect B vs Placebo IPD evidence represents raw data as collected by the study centers This distinction has raised the need for different meta analytic methods when evidence synthesis is desired and has led to the development of one stage and two stage methods 34 In one stage methods the IPD from all studies are modeled simultaneously whilst accounting for the clustering of participants within studies Two stage methods first compute summary statistics for AD from each study and then calculate overall statistics as a weighted average of the study statistics By reducing IPD to AD two stage methods can also be applied when IPD is available this makes them an appealing choice when performing a meta analysis Although it is conventionally believed that one stage and two stage methods yield similar results recent studies have shown that they may occasionally lead to different conclusions 35 36 Statistical models for aggregate data Edit Direct evidence Models incorporating study effects only Edit Fixed effects model Edit The fixed effect model provides a weighted average of a series of study estimates The inverse of the estimates variance is commonly used as study weight so that larger studies tend to contribute more than smaller studies to the weighted average Consequently when studies within a meta analysis are dominated by a very large study the findings from smaller studies are practically ignored 37 Most importantly the fixed effects model assumes that all included studies investigate the same population use the same variable and outcome definitions etc This assumption is typically unrealistic as research is often prone to several sources of heterogeneity e g treatment effects may differ according to locale dosage levels study conditions Random effects model Edit A common model used to synthesize heterogeneous research is the random effects model of meta analysis This is simply the weighted average of the effect sizes of a group of studies The weight that is applied in this process of weighted averaging with a random effects meta analysis is achieved in two steps 38 Step 1 Inverse variance weighting Step 2 Un weighting of this inverse variance weighting by applying a random effects variance component REVC that is simply derived from the extent of variability of the effect sizes of the underlying studies This means that the greater this variability in effect sizes otherwise known as heterogeneity the greater the un weighting and this can reach a point when the random effects meta analysis result becomes simply the un weighted average effect size across the studies At the other extreme when all effect sizes are similar or variability does not exceed sampling error no REVC is applied and the random effects meta analysis defaults to simply a fixed effect meta analysis only inverse variance weighting The extent of this reversal is solely dependent on two factors 39 Heterogeneity of precision Heterogeneity of effect sizeSince neither of these factors automatically indicates a faulty larger study or more reliable smaller studies the re distribution of weights under this model will not bear a relationship to what these studies actually might offer Indeed it has been demonstrated that redistribution of weights is simply in one direction from larger to smaller studies as heterogeneity increases until eventually all studies have equal weight and no more redistribution is possible 39 Another issue with the random effects model is that the most commonly used confidence intervals generally do not retain their coverage probability above the specified nominal level and thus substantially underestimate the statistical error and are potentially overconfident in their conclusions 40 41 Several fixes have been suggested 42 43 but the debate continues on 41 44 A further concern is that the average treatment effect can sometimes be even less conservative compared to the fixed effect model 45 and therefore misleading in practice One interpretational fix that has been suggested is to create a prediction interval around the random effects estimate to portray the range of possible effects in practice 46 However an assumption behind the calculation of such a prediction interval is that trials are considered more or less homogeneous entities and that included patient populations and comparator treatments should be considered exchangeable 47 and this is usually unattainable in practice There are many methods used to estimate between studies variance with restricted maximum likelihood estimator being the least prone to bias and one of the most commonly used 48 Several advanced iterative techniques for computing the between studies variance exist including both maximum likelihood and restricted maximum likelihood method and random effects models using these methods can be run with multiples software platforms including in Excel 49 Stata 50 SPSS 51 and R 52 Most meta analyses include between 2 and 4 studies and such a sample is more often than not inadequate to accurately estimate heterogeneity Thus it appears that in small meta analyses an incorrect zero between study variance estimate is obtained leading to a false homogeneity assumption Overall it appears that heterogeneity is being consistently underestimated in meta analyses and sensitivity analyses in which high heterogeneity levels are assumed could be informative 53 These random effects models and software packages mentioned above relate to study aggregate meta analyses and researchers wishing to conduct individual patient data IPD meta analyses need to consider mixed effects modelling approaches 54 IVhet model Edit Doi amp Barendregt working in collaboration with Khan Thalib and Williams from the University of Queensland University of Southern Queensland and Kuwait University have created an inverse variance quasi likelihood based alternative IVhet to the random effects RE model for which details are available online 49 This was incorporated into MetaXL version 2 0 55 a free Microsoft excel add in for meta analysis produced by Epigear International Pty Ltd and made available on 5 April 2014 The authors state that a clear advantage of this model is that it resolves the two main problems of the random effects model The first advantage of the IVhet model is that coverage remains at the nominal usually 95 level for the confidence interval unlike the random effects model which drops in coverage with increasing heterogeneity 40 41 The second advantage is that the IVhet model maintains the inverse variance weights of individual studies unlike the RE model which gives small studies more weight and therefore larger studies less with increasing heterogeneity When heterogeneity becomes large the individual study weights under the RE model become equal and thus the RE model returns an arithmetic mean rather than a weighted average This side effect of the RE model does not occur with the IVhet model which thus differs from the RE model estimate in two perspectives 49 Pooled estimates will favor larger trials as opposed to penalizing larger trials in the RE model and will have a confidence interval that remains within the nominal coverage under uncertainty heterogeneity Doi amp Barendregt suggest that while the RE model provides an alternative method of pooling the study data their simulation results 56 demonstrate that using a more specified probability model with untenable assumptions as with the RE model does not necessarily provide better results The latter study also reports that the IVhet model resolves the problems related to underestimation of the statistical error poor coverage of the confidence interval and increased MSE seen with the random effects model and the authors conclude that researchers should henceforth abandon use of the random effects model in meta analysis While their data is compelling the ramifications in terms of the magnitude of spuriously positive results within the Cochrane database are huge and thus accepting this conclusion requires careful independent confirmation The availability of a free software MetaXL 55 that runs the IVhet model and all other models for comparison facilitates this for the research community Direct evidence Models incorporating additional information Edit Quality effects model Edit Doi and Thalib originally introduced the quality effects model 57 They 58 introduced a new approach to adjustment for inter study variability by incorporating the contribution of variance due to a relevant component quality in addition to the contribution of variance due to random error that is used in any fixed effects meta analysis model to generate weights for each study The strength of the quality effects meta analysis is that it allows available methodological evidence to be used over subjective random effects and thereby helps to close the damaging gap which has opened up between methodology and statistics in clinical research To do this a synthetic bias variance is computed based on quality information to adjust inverse variance weights and the quality adjusted weight of the ith study is introduced 57 These adjusted weights are then used in meta analysis In other words if study i is of good quality and other studies are of poor quality a proportion of their quality adjusted weights is mathematically redistributed to study i giving it more weight towards the overall effect size As studies become increasingly similar in terms of quality re distribution becomes progressively less and ceases when all studies are of equal quality in the case of equal quality the quality effects model defaults to the IVhet model see previous section A recent evaluation of the quality effects model with some updates demonstrates that despite the subjectivity of quality assessment the performance MSE and true variance under simulation is superior to that achievable with the random effects model 59 60 This model thus replaces the untenable interpretations that abound in the literature and a software is available to explore this method further 55 Indirect evidence Network meta analysis methods Edit A network meta analysis looks at indirect comparisons In the image A has been analyzed in relation to C and C has been analyzed in relation to b However the relation between A and B is only known indirectly and a network meta analysis looks at such indirect evidence of differences between methods and interventions using statistical method Indirect comparison meta analysis methods also called network meta analyses in particular when multiple treatments are assessed simultaneously generally use two main methodologies First is the Bucher method 61 which is a single or repeated comparison of a closed loop of three treatments such that one of them is common to the two studies and forms the node where the loop begins and ends Therefore multiple two by two comparisons 3 treatment loops are needed to compare multiple treatments This methodology requires that trials with more than two arms have two arms only selected as independent pair wise comparisons are required The alternative methodology uses complex statistical modelling to include the multiple arm trials and comparisons simultaneously between all competing treatments These have been executed using Bayesian methods mixed linear models and meta regression approaches citation needed Bayesian framework Edit Specifying a Bayesian network meta analysis model involves writing a directed acyclic graph DAG model for general purpose Markov chain Monte Carlo MCMC software such as WinBUGS 62 In addition prior distributions have to be specified for a number of the parameters and the data have to be supplied in a specific format 62 Together the DAG priors and data form a Bayesian hierarchical model To complicate matters further because of the nature of MCMC estimation overdispersed starting values have to be chosen for a number of independent chains so that convergence can be assessed 63 Recently multiple R software packages were developed to simplify the model fitting e g metaBMA 64 and RoBMA 65 and even implemented in statistical software with graphical user interface GUI JASP Although the complexity of the Bayesian approach limits usage of this methodology recent tutorial papers are trying to increase accessibility of the methods 66 67 Methodology for automation of this method has been suggested 62 but requires that arm level outcome data are available and this is usually unavailable Great claims are sometimes made for the inherent ability of the Bayesian framework to handle network meta analysis and its greater flexibility However this choice of implementation of framework for inference Bayesian or frequentist may be less important than other choices regarding the modeling of effects 68 see discussion on models above Frequentist multivariate framework Edit On the other hand the frequentist multivariate methods involve approximations and assumptions that are not stated explicitly or verified when the methods are applied see discussion on meta analysis models above For example the mvmeta package for Stata enables network meta analysis in a frequentist framework 69 However if there is no common comparator in the network then this has to be handled by augmenting the dataset with fictional arms with high variance which is not very objective and requires a decision as to what constitutes a sufficiently high variance 62 The other issue is use of the random effects model in both this frequentist framework and the Bayesian framework Senn advises analysts to be cautious about interpreting the random effects analysis since only one random effect is allowed for but one could envisage many 68 Senn goes on to say that it is rather naive even in the case where only two treatments are being compared to assume that random effects analysis accounts for all uncertainty about the way effects can vary from trial to trial Newer models of meta analysis such as those discussed above would certainly help alleviate this situation and have been implemented in the next framework Generalized pairwise modelling framework Edit An approach that has been tried since the late 1990s is the implementation of the multiple three treatment closed loop analysis This has not been popular because the process rapidly becomes overwhelming as network complexity increases Development in this area was then abandoned in favor of the Bayesian and multivariate frequentist methods which emerged as alternatives Very recently automation of the three treatment closed loop method has been developed for complex networks by some researchers 49 as a way to make this methodology available to the mainstream research community This proposal does restrict each trial to two interventions but also introduces a workaround for multiple arm trials a different fixed control node can be selected in different runs It also utilizes robust meta analysis methods so that many of the problems highlighted above are avoided Further research around this framework is required to determine if this is indeed superior to the Bayesian or multivariate frequentist frameworks Researchers willing to try this out have access to this framework through a free software 55 Tailored meta analysis Edit Another form of additional information comes from the intended setting If the target setting for applying the meta analysis results is known then it may be possible to use data from the setting to tailor the results thus producing a tailored meta analysis 70 71 This has been used in test accuracy meta analyses where empirical knowledge of the test positive rate and the prevalence have been used to derive a region in Receiver Operating Characteristic ROC space known as an applicable region Studies are then selected for the target setting based on comparison with this region and aggregated to produce a summary estimate which is tailored to the target setting Aggregating IPD and AD Edit Meta analysis can also be applied to combine IPD and AD This is convenient when the researchers who conduct the analysis have their own raw data while collecting aggregate or summary data from the literature The generalized integration model GIM 72 is a generalization of the meta analysis It allows that the model fitted on the individual participant data IPD is different from the ones used to compute the aggregate data AD GIM can be viewed as a model calibration method for integrating information with more flexibility Validation of meta analysis results Edit The meta analysis estimate represents a weighted average across studies and when there is heterogeneity this may result in the summary estimate not being representative of individual studies Qualitative appraisal of the primary studies using established tools can uncover potential biases 73 74 but does not quantify the aggregate effect of these biases on the summary estimate Although the meta analysis result could be compared with an independent prospective primary study such external validation is often impractical This has led to the development of methods that exploit a form of leave one out cross validation sometimes referred to as internal external cross validation IOCV 75 Here each of the k included studies in turn is omitted and compared with the summary estimate derived from aggregating the remaining k 1 studies A general validation statistic Vn based on IOCV has been developed to measure the statistical validity of meta analysis results 76 For test accuracy and prediction particularly when there are multivariate effects other approaches which seek to estimate the prediction error have also been proposed 77 Challenges EditA meta analysis of several small studies does not always predict the results of a single large study 78 Some have argued that a weakness of the method is that sources of bias are not controlled by the method a good meta analysis cannot correct for poor design or bias in the original studies 79 This would mean that only methodologically sound studies should be included in a meta analysis a practice called best evidence synthesis 79 Other meta analysts would include weaker studies and add a study level predictor variable that reflects the methodological quality of the studies to examine the effect of study quality on the effect size 80 However others have argued that a better approach is to preserve information about the variance in the study sample casting as wide a net as possible and that methodological selection criteria introduce unwanted subjectivity defeating the purpose of the approach 81 Publication bias the file drawer problem Edit A funnel plot expected without the file drawer problem The largest studies converge at the tip while smaller studies show more or less symmetrical scatter at the base A funnel plot expected with the file drawer problem The largest studies still cluster around the tip but the bias against publishing negative studies has caused the smaller studies as a whole to have an unjustifiably favorable result to the hypothesis Another potential pitfall is the reliance on the available body of published studies which may create exaggerated outcomes due to publication bias as studies which show negative results or insignificant results are less likely to be published 82 For example pharmaceutical companies have been known to hide negative studies and researchers may have overlooked unpublished studies such as dissertation studies or conference abstracts that did not reach publication This is not easily solved as one cannot know how many studies have gone unreported 83 This file drawer problem characterized by negative or non significant results being tucked away in a cabinet can result in a biased distribution of effect sizes thus creating a serious base rate fallacy in which the significance of the published studies is overestimated as other studies were either not submitted for publication or were rejected This should be seriously considered when interpreting the outcomes of a meta analysis 83 6 The distribution of effect sizes can be visualized with a funnel plot which in its most common version is a scatter plot of standard error versus the effect size It makes use of the fact that the smaller studies thus larger standard errors have more scatter of the magnitude of effect being less precise while the larger studies have less scatter and form the tip of the funnel If many negative studies were not published the remaining positive studies give rise to a funnel plot in which the base is skewed to one side asymmetry of the funnel plot In contrast when there is no publication bias the effect of the smaller studies has no reason to be skewed to one side and so a symmetric funnel plot results This also means that if no publication bias is present there would be no relationship between standard error and effect size 84 A negative or positive relation between standard error and effect size would imply that smaller studies that found effects in one direction only were more likely to be published and or to be submitted for publication Apart from the visual funnel plot statistical methods for detecting publication bias have also been proposed 85 These are controversial because they typically have low power for detection of bias but also may make false positives under some circumstances 86 For instance small study effects biased smaller studies wherein methodological differences between smaller and larger studies exist may cause asymmetry in effect sizes that resembles publication bias However small study effects may be just as problematic for the interpretation of meta analyses and the imperative is on meta analytic authors to investigate potential sources of bias 87 A Tandem Method for analyzing publication bias has been suggested for cutting down false positive error problems 88 This Tandem method consists of three stages Firstly one calculates Orwin s fail safe N to check how many studies should be added in order to reduce the test statistic to a trivial size If this number of studies is larger than the number of studies used in the meta analysis it is a sign that there is no publication bias as in that case one needs a lot of studies to reduce the effect size Secondly one can do an Egger s regression test which tests whether the funnel plot is symmetrical As mentioned before a symmetrical funnel plot is a sign that there is no publication bias as the effect size and sample size are not dependent Thirdly one can do the trim and fill method which imputes data if the funnel plot is asymmetrical The problem of publication bias is not trivial as it is suggested that 25 of meta analyses in the psychological sciences may have suffered from publication bias 88 However low power of existing tests and problems with the visual appearance of the funnel plot remain an issue and estimates of publication bias may remain lower than what truly exists Most discussions of publication bias focus on journal practices favoring publication of statistically significant findings However questionable research practices such as reworking statistical models until significance is achieved may also favor statistically significant findings in support of researchers hypotheses 89 90 Problems related to studies not reporting non statistically significant effects Edit Studies often do not report the effects when they do not reach statistical significance citation needed For example they may simply say that the groups did not show statistically significant differences without reporting any other information e g a statistic or p value Exclusion of these studies would lead to a situation similar to publication bias but their inclusion assuming null effects would also bias the meta analysis MetaNSUE a method created by Joaquim Radua has shown to allow researchers to include unbiasedly these studies 91 Its steps are as follows Maximum likelihood estimation of the meta analytic effect and the heterogeneity between studies Multiple imputation of the NSUEs adding noise to the estimate of the effect Separate meta analyses for each imputed dataset Pooling of the results of these meta analyses Problems related to the statistical approach Edit Other weaknesses are that it has not been determined if the statistically most accurate method for combining results is the fixed IVhet random or quality effect models though the criticism against the random effects model is mounting because of the perception that the new random effects used in meta analysis are essentially formal devices to facilitate smoothing or shrinkage and prediction may be impossible or ill advised 92 The main problem with the random effects approach is that it uses the classic statistical thought of generating a compromise estimator that makes the weights close to the naturally weighted estimator if heterogeneity across studies is large but close to the inverse variance weighted estimator if the between study heterogeneity is small However what has been ignored is the distinction between the model we choose to analyze a given dataset and the mechanism by which the data came into being 93 A random effect can be present in either of these roles but the two roles are quite distinct There s no reason to think the analysis model and data generation mechanism model are similar in form but many sub fields of statistics have developed the habit of assuming for theory and simulations that the data generation mechanism model is identical to the analysis model we choose or would like others to choose As a hypothesized mechanisms for producing the data the random effect model for meta analysis is silly and it is more appropriate to think of this model as a superficial description and something we choose as an analytical tool but this choice for meta analysis may not work because the study effects are a fixed feature of the respective meta analysis and the probability distribution is only a descriptive tool 93 Problems arising from agenda driven bias Edit The most severe fault in meta analysis often occurs when the person or persons doing the meta analysis have an economic social or political agenda such as the passage or defeat of legislation People with these types of agendas may be more likely to abuse meta analysis due to personal bias For example researchers favorable to the author s agenda are likely to have their studies cherry picked while those not favorable will be ignored or labeled as not credible In addition the favored authors may themselves be biased or paid to produce results that support their overall political social or economic goals in ways such as selecting small favorable data sets and not incorporating larger unfavorable data sets The influence of such biases on the results of a meta analysis is possible because the methodology of meta analysis is highly malleable 10 A 2011 study done to disclose possible conflicts of interests in underlying research studies used for medical meta analyses reviewed 29 meta analyses and found that conflicts of interests in the studies underlying the meta analyses were rarely disclosed The 29 meta analyses included 11 from general medicine journals 15 from specialty medicine journals and three from the Cochrane Database of Systematic Reviews The 29 meta analyses reviewed a total of 509 randomized controlled trials RCTs Of these 318 RCTs reported funding sources with 219 69 receiving funding from industry i e one or more authors having financial ties to the pharmaceutical industry Of the 509 RCTs 132 reported author conflict of interest disclosures with 91 studies 69 disclosing one or more authors having financial ties to industry The information was however seldom reflected in the meta analyses Only two 7 reported RCT funding sources and none reported RCT author industry ties The authors concluded without acknowledgment of COI due to industry funding or author industry financial ties from RCTs included in meta analyses readers understanding and appraisal of the evidence from the meta analysis may be compromised 94 For example in 1998 a US federal judge found that the United States Environmental Protection Agency had abused the meta analysis process to produce a study claiming cancer risks to non smokers from environmental tobacco smoke ETS with the intent to influence policy makers to pass smoke free workplace laws The judge found that EPA s study selection is disturbing First there is evidence in the record supporting the accusation that EPA cherry picked its data Without criteria for pooling studies into a meta analysis the court cannot determine whether the exclusion of studies likely to disprove EPA s a priori hypothesis was coincidence or intentional Second EPA s excluding nearly half of the available studies directly conflicts with EPA s purported purpose for analyzing the epidemiological studies and conflicts with EPA s Risk Assessment Guidelines See ETS Risk Assessment at 4 29 These data should also be examined in the interest of weighing all the available evidence as recommended by EPA s carcinogen risk assessment guidelines U S EPA 1986a emphasis added Third EPA s selective use of data conflicts with the Radon Research Act The Act states EPA s program shall gather data and information on all aspects of indoor air quality Radon Research Act 403 a 1 emphasis added 95 As a result of the abuse the court vacated Chapters 1 6 of and the Appendices to EPA s Respiratory Health Effects of Passive Smoking Lung Cancer and other Disorders 95 Comparability and validity of included studies Edit Meta analysis may often not be a substitute for an adequately powered primary study 96 Heterogeneity of methods used may lead to faulty conclusions 97 For instance differences in the forms of an intervention or the cohorts that are thought to be minor or are unknown to the scientists could lead to substantially different results including results that distort the meta analysis results or are not adequately considered in its data Vice versa results from meta analyses may also make certain hypothesis or interventions seem nonviable and preempt further research or approvals despite certain modifications such as intermittent administration personalized criteria and combination measures leading to substantially different results including in cases where such have been successfully identified and applied in small scale studies that were considered in the meta analysis citation needed Standardization reproduction of experiments open data and open protocols may often not mitigate such problems for instance as relevant factors and criteria could be unknown or not be recorded citation needed There is a debate about the appropriate balance between testing with as few animals or humans as possible and the need to obtain robust reliable findings It has been argued that unreliable research is inefficient and wasteful and that studies are not just wasteful when they stop too late but also when they stop too early In large clinical trials planned sequential analyses are sometimes used if there is considerable expense or potential harm associated with testing participants 98 In applied behavioural science megastudies have been proposed to investigate the efficacy of many different interventions designed in an interdisciplinary manner by separate teams 99 One such study used a fitness chain to recruit a large number participants It has been suggested that behavioural interventions are often hard to compare in meta analyses and reviews as different scientists test different intervention ideas in different samples using different outcomes over different time intervals causing a lack of comparability of such individual investigations which limits their potential to inform policy 99 Weak inclusion standards lead to misleading conclusions Edit Meta analyses in education are often not restrictive enough in regards to the methodological quality of the studies they include For example studies that include small samples or researcher made measures lead to inflated effect size estimates 100 However this problem also troubles meta analysis of clinical trials The use of different quality assessment tools QATs lead to including different studies and obtaining conflicting estimates of average treatment effects 101 102 Applications in modern science EditModern statistical meta analysis does more than just combine the effect sizes of a set of studies using a weighted average It can test if the outcomes of studies show more variation than the variation that is expected because of the sampling of different numbers of research participants Additionally study characteristics such as measurement instrument used population sampled or aspects of the studies design can be coded and used to reduce variance of the estimator see statistical models above Thus some methodological weaknesses in studies can be corrected statistically Other uses of meta analytic methods include the development and validation of clinical prediction models where meta analysis may be used to combine individual participant data from different research centers and to assess the model s generalisability 103 104 or even to aggregate existing prediction models 105 Meta analysis can be done with single subject design as well as group research designs 106 This is important because much research has been done with single subject research designs 107 Considerable dispute exists for the most appropriate meta analytic technique for single subject research 108 Meta analysis leads to a shift of emphasis from single studies to multiple studies It emphasizes the practical importance of the effect size instead of the statistical significance of individual studies This shift in thinking has been termed meta analytic thinking The results of a meta analysis are often shown in a forest plot Results from studies are combined using different approaches One approach frequently used in meta analysis in health care research is termed inverse variance method The average effect size across all studies is computed as a weighted mean whereby the weights are equal to the inverse variance of each study s effect estimator Larger studies and studies with less random variation are given greater weight than smaller studies Other common approaches include the Mantel Haenszel method 109 and the Peto method 110 Seed based d mapping formerly signed differential mapping SDM is a statistical technique for meta analyzing studies on differences in brain activity or structure which used neuroimaging techniques such as fMRI VBM or PET Different high throughput techniques such as microarrays have been used to understand Gene expression MicroRNA expression profiles have been used to identify differentially expressed microRNAs in particular cell or tissue type or disease conditions or to check the effect of a treatment A meta analysis of such expression profiles was performed to derive novel conclusions and to validate the known findings 111 See also Edit Mathematics portalEstimation statistics Metascience Newcastle Ottawa scale Reporting bias Review journal Secondary research Study heterogeneity Systematic 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Higgins JP Altman DG et al Cochrane Statistical Methods Group 2021 Chapter 10 Analysing data and undertaking meta analyses 10 4 2 Peto odds ratio method In Higgins J Thomas J Chandler J Cumpston M Li T Page M Welch V eds Cochrane Handbook for Systematic Reviews of Interventions Version 6 2 ed The Cochrane Collaboration Bargaje R Hariharan M Scaria V Pillai B January 2010 Consensus miRNA expression profiles derived from interplatform normalization of microarray data RNA 16 1 16 25 doi 10 1261 rna 1688110 PMC 2802026 PMID 19948767 Further reading EditCornell JE Mulrow CD 1999 Meta analysis In Mellenbergh GJ ed Research methodology in the life behavioural and social sciences London SAGE pp 285 323 ISBN 978 0 7619 5883 3 Ellis PD 2010 The Essential Guide to Effect Sizes An Introduction to Statistical Power Meta Analysis and the Interpretation of Research Results Cambridge Cambridge University Press ISBN 978 0 521 14246 5 Sutton AJ Jones DR Abrams KR Sheldon TA Song F 2000 Methods for meta analysis in medical research London John Wiley ISBN 978 0 471 49066 1 Wilson DB Lipsey MW 2001 Practical meta analysis Thousand Oaks Sage publications ISBN 978 0 7619 2168 4 Cooper H Hedges LV eds 1994 The Handbook of Research Synthesis New York Russell Sage Foundation ISBN 978 0 87154 226 7 Bonett DG December 2010 Varying coefficient meta analytic methods for alpha reliability Psychological Methods 15 4 368 385 doi 10 1037 a0020142 PMID 20853952 S2CID 207710319 Bonett DG Price RM November 2014 Meta analysis methods for risk differences The British Journal of Mathematical and Statistical Psychology 67 3 371 387 doi 10 1111 bmsp 12024 PMID 23962020 Bonett DG September 2008 Meta analytic interval estimation for bivariate correlations Psychological Methods 13 3 173 181 doi 10 1037 a0012868 PMID 18778150 S2CID 5690835 Bonett DG September 2009 Meta analytic interval estimation for standardized and unstandardized mean differences Psychological Methods 14 3 225 238 doi 10 1037 a0016619 PMID 19719359 Bonett DG Price RM September 2015 Varying coefficient meta analysis methods for odds ratios and risk ratios Psychological Methods 20 3 394 406 doi 10 1037 met0000032 PMID 25751513 Bonett DG November 2020 Point biserial correlation Interval estimation hypothesis testing meta analysis and sample size determination The British Journal of Mathematical and Statistical Psychology 73 Suppl 1 Suppl 1 113 144 doi 10 1111 bmsp 12189 PMID 31565811 S2CID 203607297 Normand SL February 1999 Meta analysis formulating evaluating combining and reporting Statistics in Medicine 18 3 321 359 doi 10 1002 SICI 1097 0258 19990215 18 3 lt 321 AID SIM28 gt 3 0 CO 2 P PMID 10070677 Owen AB December 2009 Karl Pearson s meta analysis revisited PDF The Annals of Statistics 37 6B 3867 2892 arXiv 0911 3531 doi 10 1214 09 AOS697 S2CID 7632667 Archived from the original PDF on 26 July 2011 Slough Tara Tyson Scott A 2022 External Validity and Meta Analysis American Journal of Political Science doi 10 1111 ajps 12742 ISSN 0092 5853 Thompson SG Pocock SJ November 1991 Can meta analyses be trusted PDF Lancet 338 8775 1127 1130 doi 10 1016 0140 6736 91 91975 Z PMID 1682553 S2CID 29743240 Archived from the original PDF on 22 November 2011 Retrieved 17 June 2011 Explores two contrasting views does meta analysis provide objective quantitative methods for combining evidence from separate but similar studies or merely statistical tricks which make unjustified assumptions in producing oversimplified generalisations out of a complex of disparate studies O Rourke K 2007 Just the history from the combining of information investigating and synthesizing what is possibly common in clinical observations or studies via likelihood PDF Oxford University of Oxford Department of Statistics Archived from the original PDF on 2 November 2011 Gives technical background material and details on the An historical perspective on meta analysis paper cited in the references External links Edit Wikiversity has learning resources about Meta analysis Cochrane Handbook for Systematic Reviews of Interventions Meta Analysis at 25 Gene V Glass Preferred Reporting Items for Systematic Reviews and Meta Analyses PRISMA Statement Archived 27 July 2011 at the Wayback Machine an evidence based minimum set of items for reporting in systematic reviews and meta analyses metansue R package and graphical interface Best Evidence Encyclopedia Retrieved from https en wikipedia org w index php title Meta analysis amp oldid 1130436693, wikipedia, wiki, book, books, library,

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