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Basic Investigation of Outbreaks. Karin Galil, MD MPH Centers for Disease Control and Prevention Atlanta, Georgia. Outline. Identify the outbreak Investigate the outbreak Interpret results Institute control measures Report results. Identify Potential Outbreaks. What is an outbreak ?
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Basic Investigation of Outbreaks Karin Galil, MD MPH Centers for Disease Control and Prevention Atlanta, Georgia
Outline • Identify the outbreak • Investigate the outbreak • Interpret results • Institute control measures • Report results
Identify Potential Outbreaks • What is an outbreak ? • How can one detect outbreaks ? • Why should one look for outbreaks ?
Outbreak: Definition • An increase in the occurrence of a complication or disease above the background rate • One rare event • e.g. GAS surgical site infection • Many episodes of common occurrence • e.g. MRSA surgical site infections
Background Rate of Disease • Ongoing surveillance • Determine rates—compare within and between institutions • Trends • Requires common, accepted case definitions • Retrospective review of data
Pitfalls in Rate Estimates • Case definitions • Numerator • Different definition increased or decreased number • Population at risk • Denominator • Different definition increased or decreased rate
Who Identifies Potential Outbreaks ? • Routine surveillance • Infection control • Registries • Clinical staff • Laboratory staff
Reasons to Investigate • Outbreak control • Increased knowledge • Pathogen • Risk factors for acquisition • Transmission • Epidemiology
Clusters that Suggest Nosocomial Transmission • Similar cases on one unit or among similar patients • Cases associated with invasive device • HCW and patients with same infection • Typical nosocomial pathogen • multiply-resistant • opportunistic
Determining Risk Factors for Disease • Known risk factors in hospital-acquired infections: • Invasive devices • Severe illness or underlying disease • Environmental factors • Especially immunocompromised patients (e.g. aspergillosis)
Institute Control Measures • Immediate control measures needed even before investigation begun or completed Simple: e.g. improved handwashing Complex: cohorting patients, closing unit, halting use of device or product
Before the Investigation • Cooperation • All involved personnel and administration • Laboratory capacity • Antimicrobial susceptibility testing, typing (molecular and nonmolecular methods) • Resources • Personnel, supplies, lead investigator, statistician
The Investigation • Define “case” • Find cases • Confirm outbreak • Review charts • Describe epidemiology • Generate hypothesis • Test hypothesis • Analyze data • Communicate results
Case Definitions • “Working” case definition • Person, place, time • Clinical, laboratory or diagnostic findings • Confirmed vs. possible cases • Case definitions usually change during the investigation
Example: Case Definition “A case of multi-drug resistant tuberculosis was defined as any patient in Hospital X diagnosed with active tuberculosis from January 1, 1999 to December 31, 1999 whose isolate was resistant to at least isoniazid and rifampin.”
Case Finding Use case definition to find other cases in the source population • Large potential source population: discharge diagnoses, microbiology log books, emergency room visits, use of diagnostic technique • Small population (unit of hospital): review charts of entire cohort
Confirm the Outbreak • Calculate background rate of disease • Compare rate during outbreak with background rate • Define periods from incubation timeto last case (or present)
Rate Ratio=attack rate (outbreak period)attack rate (background period)
Pseudo-Outbreaks • Clusters of positive cultures in patients without evidence of disease • Perceived increase in infections • New or enhanced surveillance • Different laboratory methods
Descriptive Epidemiology • Line listing of case-patients (person, place, time) • Demographic information • Clinical information • Epidemic curve • Point source • Person-to-person
Point Source Outbreak • Shorter duration • Sharp peak in epidemic curve • Rapid resolution • May resolve without intervention
Epidemic Curve:Contaminated Product N=87 Number of persons with abscess 1995 1996
Bloodstream infection Pyrogenic reaction Bloodstream Infections and Pyrogenic ReactionsExtrinsic Contamination
Person-to-Person or Contaminated Equipment • Poor infection control technique or contaminated patient equipment • Long duration • May not resolve without intervention • If HCW and patients affected, plot separately and together to determine mode of transmission
Clues • Location • Tb skin test conversion associated with outpatient HIV clinicair flow • Patient characteristics • Immunocompromised patients • Persons of a certain age • Persons with same disease/procedure
Hypotheses • What caused the outbreak ? • Available data from the outbreak • Published literature • Expert opinion • Hypothesis testing
Epidemiologic Studies • Case-control studies • Cases : disease • Controls : equal likelihood of exposure as cases • Cohort studies • Cohort selected on the basis of exposure status
Case-Control Study • Advantages: small number of cases, better for rare diseases, diseases with long latency periods, multiple exposures • Disadvantages: selection and recall bias, not good if exposure is rare, cannot measure disease incidence rate (OR vs. RR)
Cohort Study • Advantages: can study rare exposures, can calculate disease incidence rates, selection bias less likely • Disadvantages: feasibility, not suited to rare diseases
Collect Data • Complete: same data for cases and controls • Unbiased: same way to avoid bias
Potential Types of Bias • Selection bias • Self-selection • Diagnostic bias • Information bias • Differential vs. misclassification • Recall bias
Questionnaire • Design questionnaire • Demographic information • Potential risk factors • Outcomes • Field test • Complete for on all patients
Enter and Clean Data • Line listing • Statistical program • EpiInfo, SAS, STATA • Clean data • Correct errors
Data Analysis • Descriptive statistics • Univariate analysis • Stratified analysis • Complex analysis
Descriptive Statistics • Vital first step • Describe person, place, time • Describe frequency of all variables collected • Look for errors • Decide on further analysesbased on these results
Disease . Yes No Yes Exposure No
Risk Estimate • OR/RR >> 1 • Strong positive association • OR/RR = 1 • No association • OR/RR << 1 • Strong negative association
Statistical Significance • Confidence Intervals • Include 1 • Exclude 1 • P value • p > 0.05 • p << 0.05
Univariate Analysis:Categorical Variables • Categorical variables (yes/no; young/old) • Odds Ratio (OR) case-control study • Relative Risk (RR) cohort study
Odds Ratio • Case-control study • OR = odds that person with disease was exposed compared to odds that a person without disease was not exposed to risk factor • OR estimates the relative risk
Calculating the Odds RatioOR = ad / bcOR = (14)(8) / (7)(5)OR = 3.2
Relative Risk • Cohort study • RR = risk ratio = incidence rate ratio = relative rate • RR = risk of disease among exposed compared to risk among the unexposed
Confidence Intervals • Sampling estimates the OR or RR • 95% confidence Intervals—if we resampled numerous times, our estimate would fall within these bounds 95% of the time • Finite population correction
Statistical Tests for 2x2 Tables • Chi-square test • Fisher’s exact test—if value of any cell <5 • P value indicates level of certainty that association was not due to chance alone
Risk Estimate vs. P Value • OR or RR –direction & strength of association • >>1: strong association • = 1 : no association • <<1: strong inverse association • P Value—level of certainty about the estimate of the association • <<.05: unlikely to be due to chance