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Experimental designs

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Title: Experimental designs


1
Experimental designs
  • The strongest of the research designs

Image www.freeimages.co.uk
2
Categories of research
  • Quantitative
  • Involves numerical data that result from taking
    measurements on subjects
  • Is objective
  • Deductive reasoning
  • Is used to test theories or ideas to determine
    whether or not they are true
  • The researcher is an objective observer

Image www.freeimages.co.uk
3
Categories of research (cont.)
  • Qualitative
  • Involves data derived from words e.g.,
    questionnaires or interviews
  • Is subjective
  • Inductive reasoning
  • Reasoning based on observations which are used to
    create an idea or theory
  • The researcher actively involved at times

4
Quantitative vs. qualitative research
  • Quantitative research employs the scientific
    method and is usually regarded at a higher level
  • But may have limited relevance to clinical
    practice because of strict methods
  • Qualitative research often leads to quantitative
    studies
  • Both forms of research are important

5
Pragmatic and explanatory research
  • Pragmatic research
  • Used to verify the effectiveness of treatments
  • i.e., whether they work under real-life
    conditions
  • Does not determine how or why the treatments work
  • Typically used to help make decisions about the
    effectiveness of new treatments compared with
    existing treatments

6
Pragmatic and explanatory research (cont.)
  • Explanatory research
  • Used to establish the efficacy of treatments
  • i.e., how they work under ideal conditions, as in
    a controlled experiment
  • Capable of answering questions about how and why
    treatments work
  • Strict methods involved are often very different
    from day-to-day clinical practice
  • Consequently, results may not be relevant to
    practitioners

7
Pragmatic and explanatory research (cont.)
  • Patient selection is more strict in explanatory
    studies
  • Patients are excluded because of things like
    co-morbid conditions, prior treatment, severity
    of the condition, age, etc.
  • This may be a disadvantage because it is not
    known whether the treatment will work for
    patients in everyday practice
  • Patients commonly present with many of the
    exclusion criteria

8
Descriptive, relational, and causal research
  • Descriptive (observational) research
  • Observes and records various aspects of
    participants in a study
  • Descriptive statistics involved
  • Relational research
  • Considers relationships that may exist between
    variables
  • Correlation and regression

9
Descriptive, relational, and causal research
(cont.)
  • Causal research
  • Explores whether an intervention causes or
    affects one or more outcome variables
  • The most demanding type of research that involves
    very detailed methods
  • Looks for statistically significant differences
    between groups

10
Experimental and quasi-experimental research
  • Experimental research
  • Random assignment to groups is involved
  • Capable of determining cause-and-effect
    relationships
  • Quasi-experimental research
  • No random assignment
  • Provides much less evidence about
    cause-and-effect relationships

11
Experimental and quasi-experimental research
(cont.)
  • Non-experimental research
  • Does not involve random assignment or even a
    comparison group
  • Merely involves the observation of one group
    before and after an intervention

12
Research design notation
  • R random assignment
  • O observation or measure
  • X treatment or intervention
  • N non-equivalent groups
  • The classic experiment
  • Randomization and 2 groups

R O X O
R O O
Each row represents a group
Time
13
Research designs
  • A quasi-experiment
  • 2 groups but no randomization
  • Non-experiment
  • Only 1 group

N O X O
N O O
O X O
14
Population
  • The units from which a sample is drawn
  • May include people, but can also consist of
    events or observations
  • It is rarely possible to include each and every
    unit of a population
  • Instead, a smaller number of units (a sample) are
    selected to represent the entire population
  • Defined as a subset of observations from a
    population

15
Samples
  • Samples can permit inferences about what is
    happening in a population based on what is
    observed in a sample
  • However, the sample must be representative of the
    population
  • Often achieved through random selection of the
    sample units whereby each unit of the population
    has an equal chance of being selected

16
Sample selection
A sample is selected
17
Samples (cont.)
  • Population parameters that are estimated from
    random samples are known as unbiased estimates
  • Random sampling is rarely employed in clinical
    trials
  • Patients are obtained using sequentially
    presenting patients or recruiting through
    advertisements
  • Referred to as convenience sampling

18
Samples (cont.)
  • Selection criteria in clinical trials
  • Patients are usually included in a clinical trial
    only if they meet certain criteria
  • e.g., severity of the condition, no secondary
    conditions, history, age, etc.
  • It is important to consider features of the
    population in a study when applying its results
    to a specific patient

19
Random assignment
  • Clinical trials often employ random assignment
    (a.k.a., randomization)
  • Refers to the way patients are assigned to groups
  • Used to make groups equivalent regarding
    prognostic factors (e.g., pain levels)
  • Sometimes called probabilistic equivalence
    because there is still a chance the groups will
    be a different after randomization

20
Random assignment (cont.)
  • Blocking
  • Subjects are separated into homogeneous subgroups
    based on factors such as age or disease severity
  • Enhances comparison because the subgroups are
    more alike than the intact groups

21
Random assignment (cont.)
  • Stratified randomization
  • Intact groups are separated into subgroups based
    on prognostic factors
  • e.g., trauma vs. non-trauma patients in a
    whiplash study

22
Random assignment (cont.)
  • Concealment
  • Assignment is often concealed from researchers to
    avoid the temptation of allotting patients with
    certain traits to groups that will receive
    special treatment
  • When concealment is inadequate, the apparent
    effects of the treatment may be distorted as much
    as or more than the size of the effect being
    investigated

23
Sample size determination
  • Articles about clinical trials should discuss why
    the number of subjects was chosen
  • Ethically important
  • Because no more subjects should be inconvenienced
    or put at risk than required to find a treatment
    effect
  • Economically
  • Extra resources required to include unnecessary
    subjects

24
Sample size determination (cont.)
  • Too few subjects reduces the power of a study so
    that a treatment effect may not be noticeable
    when it actually is present
  • Extremely large samples may show statistically
    significant differences between groups that are
    so small they are not clinically important

25
The randomized controlled trial (RCT)
  • Regarded as the ultimate research design in
    health care
  • The classic experiment

26
Placebo
  • An inert substance or treatment
  • Compared to the active substance or treatment in
    RCTs
  • Used in pharmaceutical trials to establish
    whether an active drug is more effective than a
    placebo
  • The drug and placebo groups are compared to
    determine if the drug resulted in a statistically
    significant treatment effect

27
Sham
  • A non-therapeutic intervention that imitates the
    real treatment
  • Similar to placebo, but refers to something done
    rather than something taken
  • Patients should have a very difficult time
    telling the difference between a sham and the
    real treatment
  • A sham chiropractic manipulation is difficult to
    produce

28
Treatment effect
  • The result that a treatment has on outcomes that
    is attributable specifically to the effect of
    the intervention
  • The difference between the mean outcomes observed
    in a treatment group and a control group

29
Why patients improve
  • Natural history
  • Many acute and some chronic pain conditions
    resolve on their own
  • Actual effect of the treatment
  • Nonspecific effects of the treatment
  • Linked to the treatment, but actually due to
    factors other than the active components of the
    treatment
  • Sometimes called placebo effects

30
Components of treatment
31
Effectiveness of a treatment
  • Both the placebo and treatment groups typically
    improve
  • The difference between groups at the conclusion
    of the study is what matters
  • The treatment is considered effective if the mean
    outcome of the treatment group is significantly
    better than the placebo group

32
Bias
  • Systematic errors in a study that are caused by
    problems with
  • The selection or assignment of patients to groups
  • The measurements involved in the study
  • Bias can render a study invalid, although all
    studies have at least some bias

33
Hawthorne effect
  • People tend to react differently when
    participating in experiments
  • Researchers found that the productivity of
    workers increased when they new they were
    involved in a study
  • True under a variety of conditions
  • Even conditions that should have reduced
    productivity

34
Hawthorne effect (cont.)
  • Behavior was more influenced by the attention
    researchers gave to the subjects than the
    effect of the interventions
  • The Hawthorne effect is a factor in all clinical
    studies

35
Types of bias
  • Sampling bias (a.k.a, selection bias)
  • During the selection process, each person does
    not have an equal chance of being selected from
    the source population
  • Random selection is designed to take care of this
    problem
  • Results in systematic differences between groups
    in experimental studies as to factors of
    prognosis or response to treatment

36
Types of bias (cont).
  • Random assignment with concealment is the best
    safeguard against selection bias in RCTs
  • The effect of selection bias is reduced by random
    assignment because it distributes the bias evenly
    between the treatment and control groups

37
Types of bias (cont).
  • Experimenter (researcher) bias
  • Examining or treating doctors may influence a
    studys results because of their expectancies or
    desires for a certain outcome
  • Blinding (masking) of researchers and study
    participants as to group assignment can diminish
    the effect of this bias
  • This bias can be divided into detection bias and
    performance bias

38
Types of bias (cont).
  • Exclusion bias
  • Occurs when patients who drop out of a study are
    systematically different from subjects who remain
  • Perhaps dropouts were having a poor response to
    treatment
  • Would have changed the results of the study if
    they had remained

39
Extraneous and confounding variables
  • In experiments, researchers are able to
    manipulate the explanatory variables and then
    watch what happens to the outcome variable
  • Internal validity
  • The ability of an experiment to show that the
    explanatory variables actually caused the
    observed changes in the outcome variables

40
Extraneous and confounding variables (cont.)
  • Extraneous variables
  • Uncontrolled factors that can influence the
    relationship between variables in an experiment
  • They are not the variables that are being
    studied, yet they affect the outcome of the
    experiment
  • They are unwanted because they create error

41
Extraneous and confounding variables (cont.)
  • Error variance due to extraneous variables is
    distributed evenly between the groups when random
    assignment is utilized
  • Confounding variable
  • A type of extraneous variable that affects the
    explanatory variables differently
  • e.g., it affects the treatment group but not the
    control group
  • Introduces systematic error into the study

42
Extraneous and confounding variables (cont.)
  • The effect of a confounding variable cannot be
    separated from the outcome variable

Explanatory variable e.g., manipulation
Outcome variable e.g., low back pain
Confounding variable e.g., groups receive
manualvs. instrument manipulation
43
Extraneous and confounding variables (cont.)
  • Quasi-experimental designs are particularly
    susceptible to confounding because the individual
    differences of subjects may act as confounding
    variables
  • For example
  • A quasi-experimental study that assigned headache
    patients with more severe pain to the treatment
    group

44
Threats to internal validity
  • History
  • Participants are unintentionally exposed to some
    historical event during the research project
    which affects the results
  • For example
  • A statewide fitness campaign that coincides with
    a lower back pain study
  • Some of the subjects doing the exercises would
    likely affect the studys outcome

45
Threats to internal validity (cont.)
  • Reliability of measures
  • Unreliable measures can invalidate a study
  • Possible causes
  • Faulty equipment, inconsistent instructions to
    study participants, unreliable training of
    examiners, fatigue or boredom of examiners, or
    examiners becoming more skilled at doing the test

46
Threats to internal validity (cont.)
  • Mortality
  • Subjects dropping out of studies
  • Drop-outs may be different from those who remain
  • Occurs for a variety of reasons
  • e.g., poor response to treatment, exceptional
    response to treatment, adverse effects
  • Groups may not be equivalent as a result

47
Threats to internal validity (cont.)
  • Maturation
  • Changes that occur in study participants as time
    passes that are not caused by the explanatory
    variables
  • e.g., in a study investigating strength in
    children, they would most likely get stronger in
    time, even without exposure to the explanatory
    variables

48
Threats to internal validity (cont.)
  • Regression to the mean
  • Extreme scores at the beginning of a study that
    migrate toward the mean as time passes
  • Occurs because extreme symptoms tend to return to
    a more normal state on their own
  • i.e., high initial patient scores are much more
    likely to move toward normality than to go even
    higher
  • Especially problematic when patients are selected
    based on high test values, while patients with
    low values are screened out

49
Read and bring to class
  • Hoiriis et al. A Randomized Clinical Trial
    Comparing Chiropractic Adjustments To Muscle
    Relaxants For Subacute Low Back Pain. JMPT
    200427388-98
  • Bakris, et al. Atlas vertebra realignment and
    achievement of arterial pressure goal in
    hypertensive patients a pilot study. J Hum
    Hypertens. 2007 May21(5)347-52.

50
External validity a.k.a., generalizability
  • The extent results of a study are applicable to
    other populations, other settings, and when
    implemented under different circumstances
  • Should be comparable regarding the intervention,
    age, condition severity, etc.
  • Relating to EBP Are the results of a study
    applicable to the management of a particular
    patient?

51
External validity (cont.)
  • Meade et al. study
  • Office-based chiropractic care was compared with
    hospital-based physical therapy for low back pain
  • Chiropractic was found to be superior, but may
    have been related to patients being treated in
    private chiropractic offices versus out-patient
    PT departments at hospitals

52
Internal validity vs. external validity
53
Group Mean vs. an Individual Patient
  • A RCT only considers the average of a group of
    subjects
  • A given patient will NOT be average
  • Each patient is unique in some way regarding
    condition severity, secondary conditions,
    response to care, etc.
  • Each practitioner is unique with a whole arsenal
    of treatment options

54
Research designs
  • The pretest-posttest randomized experimental
    design
  • Is the classic experiment design mentioned
    earlier
  • The most commonly used design in research
  • Patients are randomized to treatment groups which
    drastically reduces the chance of bias

55
Classic experiment design (cont.)
  • Subjects are evaluated before and after the
    intervention so that pre-treatment differences
    between groups can be considered
  • Groups are rarely exactly equivalent
  • Analysis of covariance (ANCOVA) test factors in
    pretreatment differences between groups as a
    covariate
  • Use of a control group allows separation of the
    active ingredient of the treatment effect from
    non-specific components

56
ANCOVA test
The ANCOVA test factors in pretreat-ment
differences between groups as a covariate
57
ANCOVA test
  • Statistically removes the effect of covariates
    from the analysis
  • Other variables can also be adjusted for using
    ANCOVA
  • e.g., differences between groups regarding age or
    condition severity
  • Example report in journal article
  • ... the effects of pre-treatment differences were
    adjusted for during analysis

58
Two-group pretest-posttest design
  • Comparison with an alternate form of treatment
  • e.g., a new therapy is compared to an established
    therapy
  • Cannot determine whether a new treatment works
    better than no treatment

R O X1 O
R O X2 O
59
Post-test only randomized controlled trial
  • Groups cannot be compared after randomization
    because no pretest is used
  • It is a weaker design because of doubts about the
    success of randomization
  • Sometimes used when groups are large
  • Large groups are much more likely to be
    equivalent

R X O
R O
60
Factorial design
  • Often used when several explanatory variables are
    involved in a study
  • Useful to determine if any interaction exists
    between the variables
  • Explanatory variables are categorized as
  • Factors (the major independent variables)
  • Levels (subgroups)

61
Factorial design (cont.)
  • Two factor by two level (2 X 2) factorial design

X11 X12
X21 X22
62
Factorial design (cont.)
  • Group 1 received Diversified technique and
    palpation as the method of analysis
  • Group 2 Gonstead and palpation
  • Group 3 Diversified and x-ray
  • Group 4 Gonstead and x-ray

R O X11 O
R O X12 O
R O X21 O
R O X22 O
Factorial design notation
63
Crossover design
  • Treatment is provided to one group, while the
    other group receives a placebo or alternate
    treatment
  • Group assignments are switched at some point in
    time without the doctors or subjects knowledge
  • Each group receives both the active treatment and
    the alternate treatment

64
Crossover design (cont.)
  • Each subject acts as their own control, which can
    reduce the required sample size considerably

65
Crossover design (cont.)
Crossover design notation
R O X1 O Optional washout period O X2 O
R O X2 O Optional washout period O X1 O
66
Crossover design (cont.)
  • Crossover design limitations
  • Carry-over effects
  • The therapeutic effects of the first intervention
    continue during the second intervention
  • High dropout rates
  • Because there are 2 or more periods of treatment
  • The negative effect is more harmful to the data
    analysis than other designs because each
    patients data is so important

67
Crossover design (cont.)
  • Treatment sequencing
  • Patients may respond differently when treatment 1
    is given before treatment 2 than if the order is
    reversed
  • For example
  • A chronic neck pain study where treatment 1 is
    manipulation and treatment 2 is massage
  • Results may be different if treatment 2 is
    provided first because the massage may enable
    patients to receive a better effect from the
    manipulation

68
Quasi-experimental designs
  • Very similar to the randomized designs, minus
    random assignment to groups
  • The lack of randomization is a major factor that
    make claims about causality based on
    quasi-experimental evidence doubtful
  • On the other hand, a first-rate quasi-experiment
    can generate stronger evidence than a poorly
    conducted RCT

69
Non-experimental designs
  • Do not utilize randomization or a comparison
    group
  • Are not capable of determining the effect of an
    intervention
  • Includes
  • Survey and observational research
  • Case studies and case series

70
Non-experimental designs (cont.)
  • Non-experimental designs are low on the
    evidentiary scale
  • They are still quite valuable because they
    describe unfamiliar occurrences and often lead to
    more complex studies
  • Pretreatment measures may be taken, but usually
    only one measure is involved

X O
71
Chiropractic interventions and experimental
methods
  • Pharmaceutical experiments work well
  • Because it is fairly easy to make an active pill
    and an identical looking placebo pill
  • Not so with chiropractic interventions
  • It is difficult to deceive doctors and patients
  • Sham adjustments are either so invasive they
    become therapeutic or so dissimilar from
    adjustments that patients know they are in the
    placebo group

72
Chiropractic interventions and experimental
methods (cont.)
  • Patients may actually receive a treatment effect
    when sham adjustments are too invasive
  • Conversely, they may not receive a placebo effect
    when they are aware of their inclusion in the
    placebo group
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