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Understanding Statistics in Research Articles

Understanding Statistics in Research Articles. Elizabeth Crabtree, MPH, PhD (c) Director of Evidence-Based Practice, Quality Management Assistant Professor, Library. Statistics – definition and concepts.

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Understanding Statistics in Research Articles

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  1. Understanding Statistics in Research Articles Elizabeth Crabtree, MPH, PhD (c) Director of Evidence-Based Practice, Quality Management Assistant Professor, Library

  2. Statistics – definition and concepts Statistics are used to describe something, or to examine differences among groups, or relationships among characteristics • Descriptive Statistics • Mean and median • Standard deviation • Inferential Statistics • Statistical significance – p-value • Confidence intervals • Odds ratio • Relative Risk • Sensitivity/Specificity • Positive/Negative Predictive Values

  3. Mean and Median What’s the average cost of a house in this neighborhood?

  4. Mean and Median What’s the average cost of a house in this neighborhood? Mean value: $1,009,000

  5. Mean and Median What’s the average cost of a house in this neighborhood? Median value: $10,000

  6. Standard Deviation Howspread out is the data from the mean?

  7. The P value “factors that raise your chance of divorce include living in a red state, having twins, and contracting cervical or testicular cancer…” differences between groups relationships between things Taking statistics to the next level…

  8. Testing for significance Sample size Findings Characteristics of population

  9. Testing for significance Sample size Findings Characteristics of population p < 0.05

  10. Confidence Intervals: another (and maybe better?) test for statistical significance Confidence intervals provide information about a range in which the true value lieswith a certain degree of probability

  11. Risk Factors for Deep Vein Thrombosis and Pulmonary Embolism (Heit et al., 2000) Objective: To identify independent risk factors for deep vein thrombosis and pulmonary embolism and to estimate the magnitude of risk for each. Results: “Independent risk factors for VTE included surgery (odds ratio [OR], 21.7; 95% confidence interval [CI], 9.4-49.9), ….”

  12. Interpreting the Results What does odds ratio 21.7 (95% CI 9.4-49.9) mean? • We can be 95% confident that the odds ratio will fall between 9.4 and 49.9 if the study were replicated • OR if we performed the study 100 times, the odds ratio would be between 9.4 and 49.9 in 95 of the studies

  13. P-values vs. Confidence Intervals

  14. Statistical significance and clinical relevance: one in the same?

  15. Odds ratio compares whether the odds of a certain event happening is the same for two groups The odds of an event happening is found by taking the odds the event will happen/odds the event will not happen • An odds ratio of 1 implies the event is equally likely in both groups • An odds ratio > 1 implies the event is more likely in the first group • An odds ratio < 1 implies that the event is less likely in the first group

  16. Males and Females on the Titanic The odds ratio compares the relative odds of death in each group. For females the odds were 154/308=0.5 (or 2 to 1 against dying). For males the odds were almost 5 to 1 in favor of death (709/142=4.993). The odds ratio then is 4.993/0.5=9.986. There is a 10 fold greater odds of death for males than for females.

  17. Relative Risk (sometimes called the risk ratio) compares the probability of death in each group In the case of our Titanic example, the probability of death for females is 154/462=0.3333. For males the probability is 709/851=0.8331. The RR is then 0.8331/0.3333=2.5. There is a 2.5 greater probability of death for males than females. Relative Risk comes closer to what most people think of when they compare the relative likelihood of events, but sometimes it is not possible to compute RR in a research design.

  18. Interpreting Relative Risk

  19. Huh? Odds and Probability Explained Example: for every 3 attempts there will be one successful outcome The language differs: “one to two” is an odds; expressed as the number; 0.5 “one in three” is a probability; expressed as a fraction; 1/3

  20. Risk Factors for Deep Vein Thrombosis and Pulmonary Embolism (Heit et al., 2000) Objective: To identify independent risk factors for deep vein thrombosis and pulmonary embolism and to estimate the magnitude of risk for each. Results: “Independent risk factors for VTE included surgery (odds ratio [OR], 21.7; 95% confidence interval [CI], 9.4-49.9), ….”

  21. Interpreting the Results What does (OR 21.7, 95% CI 9.4 – 49.9) mean? • Patients who have had surgery have a 21.7 to 1 odds of developing a venous thromboembolism, compared to patients who have not undergone surgery • We can be 95% confident that the odds ratio would be between 9.4 and 49.9 if the study were repeated

  22. Sensitivity and Specificity • Sensitivity is the proportion of true positives that are correctly identified by a test or measure (e.g., percent of sick people correctly identified as having the condition) • Ex: If 100 patients known to have a disease were tested, and 43 test positive, then the test has 43% sensitivity. • Specificity is the proportion of true negatives that are correctly identified by the test (e.g., percent of healthy people correctly identified as not having the condition) • Ex: If 100 patients with no disease are tested and 96 return a negative result, then the test has 96% specificity.

  23. Relationship between results of liver scan and correct diagnosis: sensitivity/specificity How good (sensitive/specific) is the liver scan at diagnosing abnormal pathology? There are 258 true positives and 86 true negatives. The proportions of these two groups that were correctly diagnosed by the scan were 231/258=0.90 and 54/86=0.63. We can expect that 90% of patients with abnormal pathology to have abnormal (positive) liver scans: 90% sensitivity. We can expect that 63% of the patients with normal pathology to have normal (negative) liver scans.: 63% specificity.

  24. Patients and clinicians have a different question… Positive and Negative Predictive Values • Positive predictive value is the probability that a patient with a positive test result really does have the conditionfor which the test was conducted. • Negative predictive value is the probability that a patient with a negative test result really is free of the conditionfor which the test was conducted • Predictive values give a direct assessment of the usefulness of the test in practice • influenced by the prevalenceof disease in the population that is being tested

  25. Relationship between results of liver scan and correct diagnosis: +/- predictive values Of the 263 patients with abnormal liver scans 231 had abnormal pathology, giving the proportion of correct diagnoses as 231/263 = 0.88. Similarly, among the 81 patients with normal liver scans the proportion of correct diagnoses was 54/81 = 0.67.

  26. Prevalence, Predictive Values and Sensitivity/Specificity

  27. Acknowledgements Dr. Charles Macias, lecture, Evidence-based medicine: why does it matter? Texas Children’s Hospital Evidence-Based Outcomes Center Evidence-Based Medicine course handouts Texas Children’s Hospital Lean Six Sigma Green Belt Certification material Craig Hospital, Those Scary Statistics!

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