Title: Case-Control Studies for Outbreak Investigations
1Case-Control Studies for Outbreak
Investigations
2Goals
- Describe the basic steps of conducting a
case-control study - Discuss how to select cases and controls
- Discuss how to conduct basic data analysis (odds,
odds ratios, and matched analysis) - Provide examples of recent outbreak
investigations that have used the case-control
study design
3Quick Review of Case-Control Studies
- Analytic studies answer what is the relationship
between exposure and disease? - Case-control design often conducted with
relatively few diseased individuals (so is
efficient) - Case-control design useful when studying a rare
disease or investigating an outbreakÂ
4Case Selection
- Depends on how the study investigator defines a
case - Case definition a set of standard criteria for
deciding whether an individual should be
classified as having the health condition of
interest (1) - Clinical criteria
- Restricted to time, place, person characteristics
- Simple, objective, and consistently applied
5Case Selection
- Sources for identifying case-patients
- Medical records
- Laboratory results
- Surveillance systems
- Registries
- Mass screening programs
- Case-patients identify other persons who have
similar illness
6Case Selection Example
- August 2001 Illinois Department of Health
notified of a cluster of cases of diarrheal
illness associated with exposure to a
recreational water park in central Illinois (2) - Local media and community networks used to
encourage ill persons to contact the local health
department - Case-patients asked if there were any other ill
persons in their household or if anyone attending
the water park with them was ill
7Control Selection
- Most difficult part of a case-control study!
- We would like to be able to conclude that there
is an association between exposure and disease in
question - Way the controls are selected is major
determinant of whether this conclusion is valid
(3)
8Control Selection (1)
- Controls are persons who do not have the disease
in question - Should be representative of population from which
cases arose (source population) - If a control had developed the disease, would
have been included as a case in the study - Should provide good estimate of the level of
exposure one would expect in that population
9Control Selection
- Sources for controls
- Same health-care institutions or providers as
cases - Same institution or organization as cases (e.g.,
schools, workplaces) - Relatives, friends, or neighbors of cases
- Randomly from the source population (1)
- May choose multiple methods of control selection
- Source will depend on the scope of the outbreak
- May choose multiple controls per case to increase
likelihood of identifying significant
associations (usually no more than 3 controls per
case)
10Control Selection Example
- Persons served by the same health-care
institution or providers as the cases - August 2001 cluster of Ralstonia pickettii
bacteremia among neonatal intensive care unit
(NICU) infants at a California hospital (4) - Controls were NICU infants who
- Had blood cultures taken during either cluster
period (July 30-August 3 and August 19-30) - Had blood cultures that did not yield R.
pickettii and - Had been in the hospital for at least 72 hours.
- Attempted to recruit 2 controls per
- case-patient
11Control Selection Example
- Members of the same institution or organization
- 2004 outbreak of varicella in a primary school
in a suburb of Beijing, China (5) - Case-control study to identify factors
contributing to high rate of transmission and
assess effectiveness of control measures - Controls included randomly-selected students in
grades K-2 of the primary school with no history
of current or previous varicella - One control recruited for each
- case-patient
12Control Selection Example
- Relatives, friends, or neighbors
- August 2000 increase noted in Salmonella
serotype Thompson isolates from Southern
California patients with onset of illness in July
(6) - Preliminary interviews found many case-patients
had eaten at Chain A restaurant in 5 days before
illness onset - Case-control study conducted to evaluate specific
food and drink exposures at Chain A restaurants - Controls were well friends or family members who
shared meals with cases at Chain A during
exposure period
13Control Selection Example
- Random sample of the source population
- January-June 2004 aflatoxicosis outbreak in
eastern Kenya resulted in 317 cases and 125
deaths (7) - Case-control study conducted to identify risk
factors for contamination of implicated maize - Randomly selected 2 controls from each case
patients village - Spun a bottle in front of village elders home
and walked to fifth house in direction indicated
by the bottle (or third house in sparsely
populated areas) - Random number list was used to select one
household member
14Control Selection Example
- Multiple methods of control selection
- In waterpark outbreak in Illinois previously
mentioned, recruited 1 control per case using 3
methods (2) - Case-patients asked to identify another healthy
person - Used local reverse-telephone directory based on
residential address of case-patients - Canvassed local schools and
- community groups
15Selection Bias
- Bias distortion of relationship between exposure
and disease - Systematic difference in way you select your
controls compared to way you select your cases
that could be related to the exposure could
introduce bias - Bias related to the way cases or controls are
chosen for a study is selection bias
16Selection Bias Example
- Case-patients more likely to work on lower floors
of an office building and employees on the lower
floors are more likely to leave the building to
go out for lunch - If control population is mostly employees from
upper floors, conclude there is a real difference
between cases and controls associated with eating
at a local deli - But the difference is due to where they worked in
the building, which resulted in how often they
ate out
17Selection Bias Example
- Outbreak at a gym and a majority of the
case-patients are females - Majority of the controls are male
- Found an association between illness and an
aerobics class - Outbreak was caused by the steam in the sauna in
the womens locker room - Relationship between illness and the aerobics
class due to the fact that women are more likely
to take an aerobics class than men
18Matching
- Validity is dependent on the similarity of cases
and controls in all respects except for exposure - Match cases and controls on characteristics
like age and gender - Matching factors should be important in disease
development, but not the exposure under
investigation - Since matching variable will not be associated
with either case or control status, it cannot
confound, or distort, the exposure-disease
association. - Analysis of data must take matching
- into account
19Matching
- Individual matching (aka matched pairs)
- Matches each case with a control that has
specific characteristics in common with the case - Used when each case has unique and important
characteristics - Group matching (aka frequency matching, category
matching) - Proportion of controls with certain
characteristics to be identical to the proportion
of cases with these same characteristics - Requires that all cases be selected first so
investigator knows the proportions to which the
controls should be matched - If 30 of cases were male, would select so that
- 30 of controls were male
20Matching
- Can be time efficient, cost effective, and
improve statistical power - The more variables that are chosen as matching
characteristics, the more difficult it is to find
a suitable control to match to the case - Once a variable is used for matching, no
relationship can be discerned between this
variable and the disease - Dont match on anything you think might be a risk
factor!
21Individual Matching Example
- Outbreak of tularemia in Sweden in 2000 (8)
- Selected two controls for each case
- Matched for age, sex, and place of residence
- Identified through computerized Swedish National
Population Register (stores name, date of birth,
personal identifying number, address of all
citizens and residents)
22Group Matching Example
- Outbreak of Escherichia coli associated with
petting zoo at 2004 North Carolina State Fair (9) - Recruited 3 controls for each case
- Group-matched by age groups (1-5 years, 6-17
years, and 18 years and older) - Identified from list provided by fair officials
of 23,972 persons who purchased tickets to the
fair online, at kiosks, or in - malls
23Conducting the Investigation
- Gather demographic information and exposure
histories from cases and controls - After you have collected the data you need, you
can begin the analysis and calculate measures of
association
24Analyzing the Data
- Odds ratio is calculated to measure the
association between an exposure and a disease
outcome
25Calculating Odds
- Odds measure occurrence of an event compared to
non-occurrence of same event - Variables with two levels (binary variables) used
to calculate an odds ratio - Examples of binary variables yes/no responses
(disease/no disease, exposed/not exposed)
26Calculating Odds
- Odds of exposure among cases calculated by
dividing number of exposed cases by number of
unexposed cases - Odds of exposure among controls calculated by
dividing number of exposed controls by number of
unexposed controls
27An Odd Measure How are odds different from
probability or risk?
- In a bag containing 20 poker chips 4 red and 16
blue - Probability is the number of times something
occurs divided by the total number of occurrences - Probability of getting red is 4/20 (or 1/5 or
20) - Probability of getting blue is 16/20 (or 4/5 or
80). - Odds are the number of times something occurs
divided by the number of times something does not
occur - Odds of getting red are 4/16 (or 1/4)
- Odds of picking blue are 16/4 (or 4/1)
- May refer to the odds of getting blue as 4 to 1
against getting red - Odds probability/(1-probability)
- If probability for picking red is 20, odds are
0.20/(1-0.20) or 1/4 - Probability odds/(1odds)
- If odds of picking red is 1/4, probability is
0.25/(10.25)0.20
28Calculating Odds
- A 2x2 table shows distribution of cases and
controls
29Calculating Odds Ratios
- Odds ratio is odds of exposure among cases
divided by odds of exposure among controls - Exposure among cases is compared to exposure
among controls to assess if and how exposure
levels differ between cases and controls
30Calculating Odds Ratios
- Odds ratio calculated by dividing odds of
exposure among cases (a/c) by odds of exposure
among controls (b/d) - Numerically the same as dividing the products
obtained when multiplying diagonally across the
2x2 table (ad/bc) - Also known as cross-products ratio
31Calculating Odds Ratios
- To interpret odds ratio, compare value to 1
- If odds ratio 1 odds of exposure is the same
for cases and controls (no association between
disease and exposure) - If odds ratio gt 1 odds of exposure among cases
is greater than among controls (a positive
association between disease and exposure) - If odds ratio lt 1 odds of exposure among cases
is less than among controls (a negative, or
protective, association between disease and
exposure)
32Calculating Odds Example
- Outbreak of Hepatitis A among patrons of a single
Pennsylvania restaurant (10) - 240 case-patients and 134 controls identified
- OR (218/22) (218x89) 19.6
- (45/89) (45x22)
33Matched Analysis
- If individual matching, 2x2 table set up
differently - Examine pairs in table, so have cases along one
side and controls along the other, and each cell
in the table contains pairs
34Matched Analysis
- Cell e contains number of matched case-control
pairs where both case and control were exposed - Concordant cell (and cell h) because case and
control have same exposure status - Cell f contains number of matched case-control
pairs where cases were exposed but controls were
not exposed - Discordant cell (as cell g) because case and
control have different exposure status - Only discordant cells give useful data the
matched odds ratio calculated as cell f divided
by cell g - Matched Odds Ratio f/g
35Odds vs. Risk
- Odds are qualitatively different from risk
(calculated in a cohort study) - Case-control studies select participants based on
disease status and then measure exposure among
the participants - Can only approximate risk of disease given
exposure - Values needed to calculate risk are not available
because entire population at risk is not included
in the study - Finding and accessing all who did not get sick
would be difficult or impossible - Case-control study allows us to use only a subset
of controls and calculate the odds ratio as an - estimate of the risk
36Example Case-Control Study E. coli at fast-food
restaurant
- November 1999 childrens hospital notified
Fresno County Health Department (California) of 5
cases of E. coli O157 infections during a 2-week
period (11) - All case patients had eaten at popular fast-food
restaurant chain A in 7-day period before onset
of illness - Local health officials and clinicians throughout
California asked to enhance surveillance for E.
coli O157 infections - States bordering California asked to review
medical histories of persons with recent E. coli
O157 infections and arrange for subtyping of
isolates - 2 sequential case-control studies conducted
- in early December 1999
37Example Case-Control Study E. coli at fast-food
restaurant
- First study conducted to determine the restaurant
associated with the outbreak - Case defined as patient with
- An infection with the PFGE-defined outbreak
strain of E. coli O157H7, diarrheal illness with
more than 3 loose stools during a 24-hour period,
and/or hemolytic uremic syndrome (HUS) during the
first 2 weeks of November 1999 or - Illness clinically compatible with E. coli
O157H7 infection, without laboratory
confirmation but with epidemiologic connection to
the outbreak - Control defined as person without a diarrheal
illness or HUS during the first 2 weeks of
November 1999
38Example Case-Control Study E. coli at fast-food
restaurant
- Controls age-matched and systematically
identified using computer-assisted telephone
interviewing or residents in the same telephone
exchange area as case patients. - Attempted 2 controls per case
- Enrolled 10 cases and 19 matched controls
- Only chain A showed statistically significant
association with illness among cases and controls
39Example Case-Control Study E. coli at fast-food
restaurant
- Second case-control study involving patrons of
chain A restaurants conducted to determine
specific menu item or ingredient associated with
illness (11) - Case defined as above but restricted to those who
had eaten at chain A and who could be matched
with meal companion-controls - 8 cases and 16 meal companion-controls enrolled
- Consumption of a beef taco was found to be
statistically associated with illness - Traceback investigation implicated an upstream
supplier of beef, but farm investigation was not
possible
40Example Case-Control Study Listeriosis with
deli meat
- July and August 2002 22 cases of listeriosis
were reported in Pennsylvania, a nearly 3-fold
increase over baseline (12) - Subtyping identified cluster of cases caused by
single Liseteria monocytogenes strain - CDC asked health departments in northeast United
States to conduct active case finding, prompt
reporting of listeriosis cases and retrieval of
clinical isolates for rapid PFGE testing - Conducted case-control study to identify cause of
increase in cases
41Example Case-Control Study Listeriosis with
deli meat
- Case-patient defined as person with
culture-confirmed listeriosis between July 1 and
November 30, 2002, whose infection was caused by
the outbreak strain - Control defined as person with culture-confirmed
listeriosis between July 1 and November 30, 2002,
whose infection was caused by any other
non-outbreak strain of L. monocytogenes, and who
lived in a state with at least 1 case patient - Interviewed with standard questionnaire including
more than 70 specific food items to gather
medical and food histories during the 4 weeks
preceding culture for L. monocytogenes.
42Example Case-Control Study Listeriosis with
deli meat
- Study obtained data from 38 case-patients and 53
controls - Infection strongly associated with consumption of
precooked turkey breast products sliced at the
deli counter of groceries and restaurants - Based on traceback investigation, 4 turkey
processing plants investigated outbreak strain
of L. monocytogenes found in plant A and in
turkey breast products from plant B - Both plants suspended production and recalled
more than 30 million pounds of products,
resulting in one of the largest meat recalls in
US historyÂ
43Conclusion
- Important to keep in mind the hypothesis you are
testing - Consideration of underlying population that gave
rise to cases will help select appropriate
controls - Improper selection of controls can introduce bias
and result in a spurious association between
exposure and illness - If controls are representative of the source
population, case-control studies are an efficient
way to conduct an analytic study to determine the
relationship between exposures and a disease
44References
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outbreak of Cryptosporidium hominis infection at
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of Ralstonia pickettii bacteremia in a neonatal
intensive care unit. Pediatr Infect Dis J.
2005241099-1103. - 5. Ma H, Fontaine R. Varicella outbreak among
primary school students--Beijing, China, 2004.
MMWR Morb Mortal Wkly Rep. 200655(suppl)39-43.
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46References
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