Epidemiological Studies PDF

Summary

This document provides an overview of epidemiological studies, highlighting different study types such as descriptive, analytical, theoretical, and experimental. Examples of studies and associated methods are included, as well as insights into specific types like case reports, field surveys, and prevalence surveys. The document covers essential notions about risk factors, measure of incidence, and various applications in public health contexts.

Full Transcript

EPIDEMIOLOGICAL
STUDIES
Types of epidemiological investigation

Descriptive
– Those undertaken without specific hypothesis.
– Often the earliest studies done on a new
disease in order to characterize it, quantify its
frequency, and determine how it varies in
relation to individual, place and time.
Analytical
– Analysis of observation using statistical and
diagnostic tests
– Undertaken to identify and test hypotheses
about the association between an exposure of
interest and a particular outcome.
 Types of epidemiological investigation

Theoretical
– Consists of representation of disease using mathematical
models that attempt to simulate natural patterns of
disease occurrence.

Experimental
– Analyzes data from group of animals from which he can
select and from which he can alter the factors associated
with the groups.
– The investigator has the ability to allocate animals into
categories
– also designed to test hypotheses between specific
exposures and outcomes — the major difference is that
in experimental studies the investigator has direct
control over the study conditions
Types Examples
Descriptive Routine data, case reports,
case series, field surveys,
prevalence surveys

Analytical Case-Control studies
Cohort studies
Cross-sectional studies

Theoretical Mathematical modelling
Prediction studies

Experimental Clinical trials
Field trials
Community trials
 Where is the disease
especially common
or rare, and what is
different about those
places?

Usually better presented pictorially in a map
How does disease frequency
change over time, and what
other factors are temporally
associated with those
changes?
 Descriptive Studies
Routine data
Health and productivity profile
Case studies/reports
Case series
Field surveys (ex KAP)
Prevalence surveys
 Routine data

Examination of data routinely
collected and submitted by
various animal facilities
– Slaughterhouses
– laboratories

Health and productivity profile
 Case Report

Case series – collection of case reports
 Field Survey

Locally known as KAP survey-
“KAP” for knowledge,
attitudes and practices
 Prevalence Survey

Cross-sectional surveys
Selection of a random sample
of animals from a population
and the disease status and
exposure status (potential risk
factors) are measured
simultaneously
 Analytical Epidemiology

Explanatory observational studies
Is aimed at determining the strength,
importance and statistical significance of
epidemiological associations.
comparison of two or more groups is the
foundation of this design
 Analytical Studies
Comparative studies testing a hypothesis
1. cross-sectional
a snapshot; no idea on cause-and-effect
relationship
2. cohort
prospective; cause-and-effect relationship
can be inferred
3. case-control
retrospective; cause-and-effect
relationship can be inferred
Are exposures linked with the disease?

E D

Exposure Disease
Hierarchy of Evidence

Gundran, 2015
 Nomenclature of Analytic studies

Cross-Sectional Longitudinal
Case control Cohort
Synonym: Synonyms: Synonyms:
Prevalence Retrospective Prospective
Case comparison Incidence

Case referent Longitudinal
Follow-up
Analytic Studies (observational)
 Cross-sectional studies

Selection of a random sample of animals from
a population and the disease status and
exposure status (potential risk factors) are
measured simultaneously
useful for describing the disease situation at
the time of data collection and it allows
determining prevalence.
Cross-sectional study

Question: What is happening?
 Cross-sectional studies
Often used to study conditions that are
relatively frequent with long duration of
expression
It measures prevalence, not incidence of
disease
It is easy, quick and inexpensive
Example: community surveys
 Cross-sectional studies

Often used to study conditions
Advantages that are
Disadvantages
relatively frequent with long duration of
-When random sample is selected, -Unsuited to the study of rare diseases
expression
disease prevalence and proportions -Unsuited to the study of diseases of
It measures
in exposed and unexposed prevalence,
in target short not incidence of
duration
population can be estimated
disease -Control of extraneous variables
-Relatively quick to mount and maybe incomplete
Example: community-Incidence
conduct surveysin exposed and unexposed
-Inexpensive individuals cannot be estimated
-No risk to subject -Temporal sequence of cause and
-Current records can be used effect cannot necessarily be
-Allow study of multiple potential determined
causes of disease
 Case-control studies

study of persons/animals with the disease
(“cases”) of interest and comparison group of
persons/animals without the disease
(“controls”)
Frequencies of suspected factors are then
measured in two groups
 Case-control study
Note: you start with diseased animals

Question: What happened?
 Case-control studies

Advantages Disadvantages
-Well suited to rare diseases -Exposed and unexposed
-Quick proportions in target population
-Inexpensive cannot be estimated
-Few subjects -rely on recall or records for
-No risk to subjects information on past exposures
-Allow study of multiple potential -Validation of information is difficult
cause of disease or sometimes impossible
-Selection of an appropriate
comparison group may be difficult
-Incidence in exposed and
unexposed individuals cannot be
estimated
 Cohort Studies
A cohort (group) of healthy animals capable of
developing a disease of interest is divided into
two groups
It selects groups according to the presence or
absence of exposure to the hypothesized factor
Followed (monitored) forward for a period of
time
the frequency of disease of interest is compared
between groups
 Cohort Studies

Can either be prospective or retrospective
the most effective observational study for
investigation of causal hypotheses with
respect to disease occurrence
 Prospective cohort study
Note: you start with exposed animals

Question:
What will happen?
 Cohort Studies
Advantages Disadvantages
Often called prospective (concurrent study)
-Incidence in exposed and -Exposed and unexposed target
theindividuals
unexposed most effective
can be observational
population cannotstudy for
be estimated
investigation of causal
calculated hypotheses
-Large with are
numbers of subjects
respect
-well suited to disease
for studying rare occurrence
required to study rare diseases
exposures -Long duration
-Permit flexibility in choosing -Expensive
variables to be systematically -Difficult follow-up
recorded
Retrospective Cohort Study
 Example of Cohort Study:

o Select a population of pregnant cows who took a
drug and some who did not
o Observe group over time to determine how
many exposed and non-exposed calf developed
malformation
o Then now we can compare the proportion of
malformed calf in the exposed group and the
proportion of malformed calf in the non-exposed
 Criteria Cross- sectional Case-control P. Cohort
Sampling Random sample separate separate
of the study samples of samples of
population diseased and exposed and
non-diseased non-exposed
units Unit
Time One time Usually Follow-up over a
retrospective specified period
Measure of Prevalence Prevalence of Incidence density
frequency exposure and cumulative
incidence

Measure of Odds ratio Odds ratio Odds ratio
association Relative/ risk Relative risk
ratio
Experimental study
 Field trial
A field trial is
a comparative study involving new treatments
or preventive measures applied under natural,
field or semi-field conditions.
Measure of Association
 Concept of risk

RISK : that it is the probability of an
untoward event.
Risk factors include any factors associated
with an increased risk of becoming
diseased or to die
Any investigation into the cause-effect
relationships between potential risk
factors and an outcome parameter such as
disease or death involves calculation of
risks.
 Factors that interfere with
assessment of risk
Long latency period/incubation
High prevalence of risk factors/ disease
Low incidence of disease
Multiple causes
Small risk from exposure
 Uses of risks
Prediction
– presence of risk estimate likely future incidence of disease among
comparable individuals
Diagnosis
– Presence of risk factor in an individual increases the likelihood that
an associated disease is present
Cause identification
– Not because risk predict disease, it does not follow that it cause
disease. A risk factor may mark a disease outcome indirectly, by
virtue of an association with some other determinant of disease
– A risk factor that is not a cause of disease is called a “marker”
because it marks the increased probability of disease
Prevention
– If a risk factor is the cause of disease, its removal can be used to
prevent disease even if disease mechanism is unknown.
Comparing risk in cohort studies

To compare risk, several measures of
the association between exposure
and disease, called measures of
effect, are commonly used.
They represent different concepts of
risk and are used for different
purposes
 Measures of effect

Expression Clinical Question Calculation
Relative Risk (risk ratio) How many times more likely are RR = IE/ Ie
exposed individuals to become
diseased relative to unexposed?

Attributable risk (risk What is the incidence of disease AR = IE- Ie
difference) attributable to exposure?

Population attributable What is the incidence of disease in Arp = AR x P
risk a population associated with the
occurrence of a risk factor?

Population attributable What fraction of disease in a AFp = Arp/RT
fraction population is attributable to
exposure to a risk factor?
 Relative Risk

 Also known as Risk Ratio
 RR is the standard measure of association for cohort
studies
 RR is an index of strength of the association between
a risk factor and disease (causal relationship)
 RR = Incidence in exposed (IE)
Incidence in non-exposed (Ie)
 Using the 2x2 contingency table
RR = a / (a + b)
c / (c + d)
If no additional risk is associated with exposure, then both
incidences should be equal and the ratio is equal to one (1)
 Disease
+ - Total

Exp + a b a+b IE = a/ a+b

Exp - c d c+d Ie= c/ c+d
Data from a fixed cohort study of oral contraceptive use (OC) and
myocardial infarction (MI) in pre-menopausal women followed
for 5 years

MI

(+) (-) Total

Yes 23 304 327
OC use
No 133 2816 2949

Total 156 3120 3276
 RR - Interpretation

RR = 1.0
– indicates the rate (risk) of disease among
exposed and non-exposed are identical
– No association
RR = > 1.0
– Risk is higher among exposed
– Positive association
– Larger RR- the stronger the association
RR = < 1.0
– Risk is lower in exposed
– Negative Association (factor is protective)
 Risk of Gastroenteritis
By consumption of a particular food item
(Chicken)
Ill Not Ill Total Incidence

Ate Chicken Yes 43 11 54 80%
No 3 18 21 14%
56 29 75

Risk ratio = 80 / 14 = 5.7
 Relative Risk
Number of people Number of people who
who ate specified item did not eat specified item
Incid
Attack Incid Relative
Attack
Food Ill Well Total ence% Ill Well Total ence%
Rate Rate Risk
Baked Ham 29 17 46 63 17 12 29 59 1.07
Mashed potatoes 23 14 37 62 23 14 37 62 1.00
Spinach 26 17 43 60 20 12 32 62 0.97
Cabbage Salad 18 10 28 64 28 19 47 60 1.07
Milk 2 2 4 50 44 27 71 62 0.81
chicken 43 11 54 80 3 18 21 14 5.71
Fruit salad 4 2 6 67 42 27 69 61 1.10
Ice Cream (Choc) 25 22 47 53 20 7 27 74 0.72

Source: CDC Excite
 Attributable risk (AR)/
risk difference (RD)
AR = IE – Ie
Attributable risk is the additional incidence of
disease attributable to the risk/exposure
itself
AR = Incidence in population if all cases are
associated with risk factor
AR = 0 when there is no association between
exposure and disease
 RR vs RD
Relative risk is a measure of strength of
association between exposure and disease
and is useful in analytical studies
– risk
Risk difference is a measure of how much
disease incidence is attributable to exposure
– burden
 Population attributable risk (ARp)
Arp = AR x prevalence of risk factor in the
population(P)
useful in deciding which factors are important and
which are trivial in the overall incidence of
particular disease in the herd
It provides a measure of how much a risk factor
contributes to the disease incidence at the pop’n
A relatively weak risk factor that is quite prevalent
could contribute more to disease incidence in a
population than a stronger risk factor that is rarely
present.
 Population Attributable Fraction (AFp)

Population Attributable Fraction (AFp)
AFp = Arp / Total incidence of disease in a
population (RT)
It permits to predict the proportion of cases of a
particular disease that will be eliminated through
control of a particular risk factor
If all cases are associated with the risk factor
being measured, then the AFp = 1.00 or 100%
Cohort study of risk in neonatal calves with different levels
of serum gamma globulin

Gamma Cohort size Deaths/ Incidence (%)
globulin (%) culls

1.1 – 6.2* 73 12 16.44
6.3- 46.7 220 6 2.73
Totals 293 18 6.14
*Low gamma globulin
 Calculation of the measures of effect

Simple risk:
1. Incidence of calf losses among low gamma globulin
group (exposed/with risk factor)

2. Incidence of calf losses among remaining calves

3. Prevalence of low gamma globulin levels in all calves

4. Incidence of calf losses
 Compared Risks:

1. Relative risk = 16.44 / 2.73 = 6.03

2. Attributable risk = 16.44 – 2.73 = 13.71%

3. Population attributable risk = 0.137 x 0.249 = 0.0341 or 3.41%

4. Population attributable fraction = 0.0341/0.0614 = 0.556 0r
55.6%
 Interpretation
Calves with low serum gamma globulin levels are approximately
six times more likely to be culled or die relative to their
“normal” counterparts (relative risk)

Low serum gamma globulin levels are associated with an
additional 13.71% incidence of culls and deaths among exposed
calves (attributed risk)

Low serum gamma globulin levels are associated with an
additional 3.41% incidence of culls and deaths among all calves
(population attributable risk)

Low serum gamma globulin levels are associated with
approximately 56% of all calf losses among all calves
(Population attributable fraction)
 Comparing risk in case-control studies

Since case control study begins with the selection of
cases, there is no data on the size of the population at
risk, and consequently incidence of disease
Participants are selected for study participation on the
basis of pre-existing disease status
Cannot estimate prevalence, CI
– Do not know the population at risk
It is not possible to obtain relative risk, we can only
make an estimate – ODDS RATIO
– ratio of odds (likelihood;chance) of exposure among cases
to odds of exposure among controls
 Odds Ratio
Defined as the ratio of the
(number of diseased animals exposed to a factor
multiplied by the number of non-diseased
animals not exposed to the factor)
to
(number of non-diseased animals exposed to
the factor multiplied by the number of diseased
animals not exposed to the factor)

OR = (a/c)/(b/d) = ad/bc
 Odds ratio

Cases Non-
cases
Exposed A B A +B
Not exposed C D C +D
A+C B+D
Calculation of odds ratio using data from the previous
table as if the study were a case control study

Cases Non-cases Total
Expose to low 12 61 73
gamma globulin
levels
Not exposed to 6 214 220
low gamma
globulin levels
Total 18 275 293

ODDS RATIO = AD/BC
=(12x214) /(61x6) = 7.02
 Summary
Risk factors are characteristics that are associated with the
increased likelihood of an event occurring (becoming
diseased). Whether or not the risk factor is a cause of disease,
its presence allows one to predict the probability that the
disease will occur.
Many suspected risk cannot be manipulated for the purpose of
an experiment, so it is usually necessary to study risk by simply
observing individuals experience with the risk factor. One way
to do it is to select cohort and observe the subsequent
incidence of disease.
When disease rates are compared among groups with
different exposures to a risk factor, the results can be
expressed in several ways: RR, AR, Arp, AFp.