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Basic concept of clinical study. Vuthiphan Vongmongkol Weranuch Wongwatanakul. Epidemiology. Basic science of public health.
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Basic concept of clinical study Vuthiphan Vongmongkol WeranuchWongwatanakul
Epidemiology Basic science of public health “The study of the distribution and determinants of health-related states or events in specified population and the application of this study to control of health problems” Last JM:A dictionary of Epidemiology,ed 2. New York, Oxford University Press,1988 Distribution (Prevalence, Incidence) Determinants (Risk factors, Causes of diseases) *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Research question in Epidemiology • Size of the problems • Prevalence of DM in the population • How many people don’t have adequate health care? • Association of the problems • Did the DM in this population related to education level? • Did those Whose do not have adequate health care relate to geographic region of residences? *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Measurements in Epidemiology • Size of the problems (Measuring the occurrence) • Prevalence • Incidence • Association of the Problems (Measuring the association) • Prevalence Rate Ratio ===> Cross-Sectional Study • Odds Ratio ===> Case-Control study • Relative Risk ===> Cohort study *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Rate • The central tool of Epidemiology is the comparison of RATES - Mortality Rate - Prevalence - Incidence
Prevalence “The number of existing case of disease at a particular point in time.”
Incidence (1) There are two ways of measuring • Cumulative incidence
Measuring the incidence (2) 2) Incidence density or Incidence rate • Adding “Time Dimension” into the denominator “Person-time” • person-month, person-year • 1 person-year = Following 1 person for 1 year period • 10 person-year = Following 1 person for 10 year period • or Following 10 persons for 1 year period *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Measuring the incidence (3) 2) Incidence density or Incidence rate If 100 subjects are followed for 1 year and 20 develop disease, the incidence density is 20 cases/ 100 person-years of observation = 20/100 person-years
ความสัมพันธ์ระหว่างการสูบบุหรี่กับอุบัติการการเกิดอัมพาต ของประชากร 118,539 คนในเวลา 8 ปี Smoking No. of stroke Person-years Incidence rate of observation /100,000 person-years Never 70 395,594 17.7 Ex-smoker 65 232,712 27.9 Smoker 139 280,141 49.6 Total 274 908,477 30.2 Cumulative incidence = 274 / 118,539 = 2.31 / 1,000
Cross-sectional Case control Cohort Classification of Clinical Study Design Observation (natural exposure) Experiment (exposure given by researcher) Randomized controlled trials
Cohort Study !!!! We are dealing with “INCIDENCE” *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Cohort Study (1) • The most powerful observational study for identifying an association between risk factors and a disease • The most time consuming • The most expensive *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Cohort Study (2) • Start with a group of people without the disease • Then divide people based on the basis of the exposure to a suspected risk factor • Follow the “whole group” for a period of time • Then assess the disease occurrence outcome *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Cause Effect • Lung Cancer • Disease • Death • Intermediate outcomes • - CD4+count • - Increased Creatinine • Cigarette • Exposure • Risk factor • Covariate • - Age • - Gender • - Income *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
disease Peoplewithout The disease Exposed no disease Population disease Not Exposed no disease Design of a cohort study Time Direction of inquiry
Risk “ The probability of disease incidence” Risk = number of cases of disease number of people at risk
CA Lung No CA A B Smoke A+B C D Not Smoke C+D Relative Risk Relative Risk = A / A+B C / C+D
CA Lung No CA 45 445 Smoke 500 1 499 Not Smoke 500 Interpretation of Relative Risk (RR) Incidence of smoker who develop Lung Cancer = 45/500 Incidence of Non-smoker who develop Lung Cancer = 1/500 Relative Risk of smoking for Lung Cancer = 45/500 = 45 1/500 “Those who smoked were 45 times more likely to develop lung cancer than those who did not smoke” *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Population Exposed Controls (People without disease) Not Exposed Design of case-control study Exposed Cases (People with disease) Not Exposed Time Direction of inquiry
Cause Effect Factors Disease Case-Control Factors Disease Cohort Case-control VS Cohort *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Case-Control Study • Strengths • Uniquely suited to diseases with long incubation periods • More efficient in terms of time and money • Good for study of rare disease • Can look at multiple exposures for a single disease • Case-control studies usually require much smaller sample sizes than do equivalent cohort studies • Case-control studies are generally able to evaluate confounding and interaction rather more precisely for the same overall sample size than are cohort studies. *Janit Kaewkungwal Faculty of Tropical Medicine Mahidol University
Case-Control Study • Limitation • Inefficient for evaluation of rare exposures • Cannot directly compute incidence rates of disease • Temporal relationship between E and D may be hard to establish. Case-control studies often do not involve a time sequence, and so are limited in their ability to demonstrate causality. • Particularly prone to bias (selection and recall in particular) • Being identified as a case might reflect survival rather than morbidity. • Case-control studies can investigate only one disease outcome. • May be confounded by unknown exposures • Appropriate control group often difficult to find *Janit Kaewkungwal Faculty of Tropical Medicine Mahidol University
Odds “The number of times the outcome occurs relative to the number of times its does not.” Odds = number of cases of disease number of non-cases of disease
a b a+b c+d d c a+c b+d N Odds Ratio Disease CA lung (case) No CA (control) smoke Exposure Not smoke Odds of exposure if case = [a/(a+c)] / [c/(a+c)] = a/c Odds of exposure if control = [b/(b+d)] / [d/(b+d)] = b/d OR = Odds of exposure if case = a/c Odds of exposure if controlb/d
Relative risk VS Odds ratio (1) If disease is rare relative risk Odds ratio Relative Risk = A / A+B = 0.75%/0.25% = 3.0 C / C+D
Relative risk VS Odds ratio (2) Odds ratio = 75X50 = 3.0 25x50 relative risk Odds ratio
Cross-sectional studies • Measure the prevalence of disease and often called prevalence studies • The easiest step to find an association (Factor & Disease) by comparing exposed and non-exposed population • Assess both EXPOSURE and DISEASE at the SAME TIME (simultaneously) • Analyze results from a survey *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine
Design of a Cross-sectional study +Exposure +Disease Gather data on Exposure and disease (simultaneously) +Exposure -Disease Defined population -Exposure +Disease -Exposure -Disease
Prevalence Rate Ratio • Estimate the “Relative Risk” from a cross-sectional study • Prevalence Rate Ratio = 10% / 5% = 2 • “Those who had high cholesterol were 2 times more likely to develop HT than those who did not” *Ram Ragsin, MD MPH DrPH Department of Military & Community Medicine Phramongkutklao College of Medicine