1 / 40

EPI-820 Evidence-Based Medicine

Learn the steps to perform a meta-analysis and understand its importance in summarizing and synthesizing medical information for evidence-based medicine. Explore the challenges and benefits of meta-analysis in healthcare research.

michaudm
Download Presentation

EPI-820 Evidence-Based Medicine

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. EPI-820 Evidence-Based Medicine LECTURE 9: Meta-Analysis I Mat Reeves BVSc, PhD

  2. Objectives • Understand the rationale for quantitative synthesis • Describe the steps in performing a meta-analysis: • identification, selection, abstraction, and analysis. • Know the appropriate analytic approach for meta-analysis of key study designs: • Experimental (RCT’s) • Observational (cohort, case-control, diagnostic tests) • Other issues: • Publication bias • Quality assessment • Random versus fixed effects models • Meta-regression

  3. Background • Facts: • For most clinical problems/public health issues there is an overwhelming amount of existing information, as well as new information produced every year • However, much of this information • isn't very good (= poor quality) • is derived from different methods & definitions (= poor standardization) • is often contradictory (= heterogeneity) • Very few single studies resolve an issue unequivocally (….. a “home run study”) • So how should we go about summarizing medical information?

  4. How do we summarize medical information? • Traditional Approach • Expert Opinion • Narrative review articles • Validity? Unbiased? Reproducible? • Methods? (one study one vote?) • Consensus statements (group expert opinion) • New Approach (Meta-analysis) • Explicit quantitative synthesis of ALL the evidence

  5. Definition - Meta-analysis • A technique for quantitatively combining the results of previous studies to: • Generate a summary estimate of effect, OR • Identify and explain heterogeneity • Alternate definition: a study of studies, to help guide further research and identify reasons for heterogeneity between studies. • Overview or Synthesis

  6. Overview • Initially developed in social sciences in mid-1960’s • Adapted to medical studies in early 1980’s • Initially applied to RCT’s – esp. when indv. studies were small and under-powered • Also applied to observational epidemiologic studies – often with little fore-thought which generated much controversy • Explosion in the number of published meta-analyses in the last 10-15 years.

  7. Overview • Often the initial step of a cost-effectiveness analysis, decision analysis, or grant application (esp. for RCT’s). • Are much cheaper than a big RCT!!! • Usually correspond to later randomized trials, but not always (from LeLorier, 1997):

  8. Discrepancies between meta-analyses and subsequent large RCT’s(LeLorier NEJM 1997) 27/40 (68%) agreement

  9. When is a meta-analysis appropriate? • When several studies are known to exist • When studies disagree (= heterogeneity) resulting in a lack of consensus • When both exposures and outcomes are quantified and presented in a useable format. • When existing individual studies are under-powered • M-A could then produce a precise estimate of effect • When you want to identify reasons for heterogeneity • M-A could illustrate why and identify important sub-group differences • When no one else has done it (yet!), or an update of an existing meta-analysis is justified.

  10. Before you begin…… plan • M-A’s appear easy to do but require careful planning, and adequate resources (time = $$$) • Need to develop study protocol • Specify primary and secondary objectives • Methods • Describe search strategy (sources, published studies only?, fugitive lit?, blinding?, reliability checks?) • Define eligibility criteria • Type of quality assessment (if any) • Analysis • Type of model (fixed vs random, use of quality scores?) • Subgroup analyses? • Sensitivity analysis?

  11. Estimating Time Required to do a M-A • Meta-Works (Boston, MA), private company • Provided estimates based on 37 M-A’s • Size of the body of literature, quality, complexity, reviewer pool and support services all important • Aver. total # hrs per study = 1139 (range 216 – 2516) • Search, selection, abstraction = 588 hrs • Stat Analysis = 144 hrs • Write up = 206 hrs • Other tasks = 201 hrs • Size of body of literature before any deletions (x) is best single guide (Hrs = 721 + 0.243x – 0.0000123x2)

  12. Steps in a meta-analysis • 1. Identification (Search) • 2. Selection • 3. Abstraction • 4. Analysis • 5. Write-up

  13. 1. Identification - Sources • M-A’s use systematic, explicit search procedures (cf. qualitative literature review) • MEDLINE • 4100 journals • 1966 - present • Web search at PubMed: http://www.ncbi.nlm.nih.gov/PubMed • other search engines: BRS Colleague, WinSPIRs, etc • EMBASE • similar to MEDLINE, European version • Expensive, not widely available in US

  14. Identification - Sources • Cochrane Collaboration Controlled Trials Register • Over 160,000 trials, including abstracts (+ translations) • by subscriptions….. MSU Electronic Library database • includes • MEDLINE, EMBASE • non-English publications • non-indexed publications • hand-search of journals • Other MEDLARS • CancerLit, AIDSLINE, TOXLINE, Dissertation Abstracts Online • Index Medicus • important if searching before 1966 • hand-search only

  15. Identification - Steps: • 1. Search own personal files • 2. Search electronic databases • Review titles and on-line abstracts to eliminate irrelevant • Retrieve remaining articles, review, and determine if meet inclusion/exclusion criteria • 3. Review reference lists of articles for missed references • 4. Consult experts/colleagues/companies • 5. Conduct hand-searches of non-electronic databases and/or relevant journals • 6. Consider consulting an expert (medical librarian) with training in MEDLINE and use of MeSH terms.

  16. Limitations of electronic databases • Electronic resources have been essential for growth of M-A, but they are far from perfect • 1. Databases are incomplete • Medline contains only 1/3rd of all biomed journals • 2. Indexing is never perfect • Want search to have high Se (include all relevant studies) and high Sp (but exclude the irrelevant!) • Ratio of retrieved articles : relevant articles can vary widely

  17. Limitations of electronic databases 2. Indexing is never perfect • Accuracy of indexing per se relies on: • authors understanding how studies are categorized • “database” assigning correct category to study • Indexing also depends on ability of search strategies (e.g., MeSH) to identify relevant articles

  18. Limitations of electronic databases 3. Search Strategies are never perfect - Its hard to find all the relevant studies - Average Se of expert searchers using MEDLINE (vs known Registries of studies) = 0.51 Example – National Perinatal RCT Registry

  19. Other search issues…… • Non-English Studies • MEDLINE • Translation of title usually provided but abstracts often not. But N.B. that many non-English journals are not included anyway! • No a priori justification for excluding non-English studies • Quality is often equivalent or even better! • Excluding non-English studies can effect conclusions • But including means you need a translation just to determine eligibility!

  20. Fugitive Literature • unpublished studies (… why are they unpublished?) • dissertations • drug company studies • book chapters • non-indexed studies and abstracts • conference proceedings • government reports • pre-MEDLINE (1966) • Sometimes important sources of information • Hard to track down – contact experts/colleagues • Need to decide whether to include or not - general consensus is that you should.

  21. Publication bias • Published studies are not representative of all studies that have been performed • Articles with “positive findings” (P < 0.05) are more likely to be published • Hence published studies are a biased sub-set • Publication bias = systematic error of M-A that results from using only published studies

  22. Evidence of Publication Bias Easterbrook (1991): 285 analyzed studies reviewed by Oxford Ethics Committee 1984-87

  23. Implications of Publication Bias Simes (1986): Chemotherapy for Advanced Ovarian CA Comparison of Published Trials vs Registered Trials

  24. Publication Bias • Probably results from a combination of author and editor practices and decisions (Ioannidis, 98) • Emphasizes the importance of registries of trials (N.B. Similar registries of observational studies are probably not feasible, although in Social Sciences Campbell Collaboration is attempting to do this) • Simple Solution: • Don’t base publication decisions on statistically significance! • Focus on interval estimation. • Yeah right……!

  25. Publication bias – Approaches • 1. Attempt to Retrieve all Studies • Required for Cochrane Publications • Difficult to identify unpublished studies and then to find out details about them • Worst Case Adjustment • Number of unpublished negative studies to negate a “positive” meta-analysis: • X = [N x (ES) / 1.645]2 - N • where: N = number of studies in meta-analysis, • ES = effect size • Example: • If N = 25, and ES = 0.6 then X = 58.2 • Almost 60 unpublished negative studies would be required to negate the meta-analysis of 25 studies.

  26. 2. Graphical Approaches - Funnel plot Missing studies = small effects size with negative findings X X X X Sample Size (precision) X X X X X X X X X X X X X X X X Effect Size

  27. 2. Selection • Inclusion/eligibility criteria essential to: • Produce a more focused (valid) study • Ensure reproducibility and minimize bias • Apply criteria systematically and rigorously • Balance between highly restrictive versus non-restrictive criteria in terms of • face validity, homogeneity, power (N), generalizability • Always develop in advance and include clinical expert(s) in the team

  28. Typical inclusion criteria: • study design (e.g., RCT’s?, DBPC?, Cohort & CCS?) • setting (emergency department, outpatient, inpatient) • age (adults only, > 60 only, etc) • year of publication or conduct (esp. if technology or typical dosing changes) • similarity of exposure or treatment (e.g., drug class, or dosage) • similarity of outcomes (case definitions) • minimum sample size or follow-up • languages? • complete vs incomplete (abstracts) • published vs fugitive? • pre-1966?

  29. Selection – Other Issues • multiple publications from same study? • Include only one! (double dipping is common!) • report should provide enough information for analysis (i.e. point estimate and variability = SD or SE) • Selection process should be done independently by at least 2 reviewers • Measure agreement (K) and resolve discrepancies • Document excluded studies and reasons for exclusion • Keep pertinent but excluded studies

  30. Typical Searching and Selection Results • First pass, using title in computer search: 300 - 500 articles • Second pass, using abstract in computer search: 60 - 100 articles • Final pass, using copy of entire article: 30 - 60 articles • Included in study: 30 articles

  31. 3. Abstraction • Goal: to abstract reliable, valid and bias free information from all written sources • Should expect a degree of unreliability • intra- and inter- rater reliability is rarely if ever 100%!! • Many sources of potential error: • Article may be wrong due to typographical or copyediting errors • Reported results can be misinterpreted • Errors in data entry during abstraction process

  32. Abstraction • Ways to minimize error: • Develop and pilot test abstraction forms • Develop definitions, abstraction instructions, and rules • Train abstractors, pilot test, get feedback, and refine • Abstraction Forms • Number each data item • Require a response for EVERY item • Distinguish between negative, missing, and not-applicable • Simple instructions/language • Clear skip and stop instructions • Items clearly linked to definitions and abstraction rules

  33. Abstraction • Typical process • 2 independent reviewers • Practice with 2 or 3 articles to “calibrate” • Use a 3rd reviewer or consensus meeting to resolve conflicts • Measure agreement (K) and resolve discrepancies

  34. Other Issues - Abstraction • Outcome measures of interest may have to be calculated from original data • For example, data to calculate relative risk may be present but not described as such. • Multiple estimates from same study? • Exp: intention-to-treat vs not, adjusted for loss-to-follow up • Obs: crude vs age-adjusted vs multiple adjusted (model) • Include only one estimate per study, avoid over-fitted model estimates (as often more imprecise)

  35. Investigator Bias: • Abstractor may be biased in favor of (or against!) a particular outcome (positive or negative finding), or researcher/institution, or journal. • prominent journals may be given greater weight or authority (rightly or wrongly) • if this may be an issue, have research assistant eliminate identifiers from articles (= blind review)

  36. Blind Review • Remove study information that could affect inclusion or quality of abstraction, like: • author, title, journal, institution, country • Berlin (‘97): • compared blinded vs non-blinded reviews • Found discrepancy in which studies to include but little difference in summary effect sizes • Time consuming • Probably can avoid esp. if use well defined abstraction procedures

  37. Assessment of study quality • Quality is an implicit measure of validity • Poor quality studies have lower validity • Using quality scoring should theoretically improve the validity of M-A’s • Process • Develop criteria (…how?) • Develop scale (= scoring system) • Abstract information and score each study • Example RCT scoring systems • Chalmers (1981) – 36 item scale! (see HWK #5) • Jadad (1997) – 5 point scale

  38. Jadad Criteria for Scoring RCTs (1997 Cont Clin Trials 17:1-12) • 1. Randomization • Appropriate (= 1 point) if each patient had equal chance of receiving intervention and investigators could not predict • Add 1 point if mechanism described and appropriate • Deduct 1 point if mechanism described and inappropriate • 2. Double blinding • Appropriate (= 1 point) if stated that neither the patient nor investigators could identify intervention, or if “active placebo”, “identical placebo” or “dummies” mentioned • Add 1 point if method described and appropriate • Deduct 1 point if mechanism described and inappropriate • 3. Withdrawals and dropouts • Appropriate (= 1 point) if number and reasons for loss-to-FU in each group described.

  39. Uses of Quality Scores • Threshold (minimum score for inclusion) • Categorize study quality • High, medium, low quality • Use as sub-group analyses • Sensitivity analysis • Combine study-specific scores with variance (based on N) to generate modified weights • Poorer studies “count less” • Generally not recommended • Meta-regression

  40. Other Issues – Quality Scoring • Quality is difficult to measure • No consensus on method of scale development – not even for RCT’s • Few reliability/validity studies of scoring systems • inter-rater reliability of quality assessment often poor • Relies on quality of the reporting itself • sometimes study is blinded or randomized, but if not explicitly stated then it suffers in quality assessment • Difficult to detect bias from publications • More recent studies score higher – partly because they conform to recent standardized reporting protocols (e.g., RCT’s – CONSORT)

More Related