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Cluster Randomised Trials

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Title: Cluster Randomised Trials


1
Cluster Randomised Trials
2
Background
  • In most RCTs people are randomised as individuals
    to treatment. Whilst this method is appropriate
    for many interventions (e.g. drug trials), in
    some types of intervention individuals cannot be
    randomised.
  • An alternative approach is randomise groups of
    individuals or clusters.

3
History
  • Cluster trials originated from educational
    research. Intact classes or schools were
    randomised to an intervention or no intervention.
  • Sadly educational researchers have all but
    abandoned RCTs in favour of qualitative research.

4
Rationale For Cluster Randomisation
  • Some interventions have to be delivered at a
    group level.
  • Guidelines for clinicians
  • Interventions to reduce infectious diseases
  • Practical considerations
  • Potential for treatment contamination

5
Clusters
  • A cluster can take many forms
  • GP practice or patients belonging to an
    individual practitioner
  • Hospital ward
  • A period of time (week day month)
  • Geographical area (village town postal
    district).

6
Cluster allocation
  • Because the unit of allocation is the cluster and
    the sample size of clusters tends to be small
    care needs to be taken with cluster allocation.
  • With typically only 10 or so clusters simple
    randomisation is likely to lead to chance
    imbalance.

7
Cluster allocation
  • Need to use some form of stratification.
  • Pairing is often used match clusters on an
    important co-variate and randomly allocate a
    member of each pair to the intervention.
  • Stratification using blocking or the use of
    minimisation is an alternative.

8
Problems with Cluster Randomisation
  • Possible Selection Bias
  • Inadequate uptake of intervention by either group
    reduces study power
  • Sample size needs to be increased (typically
    between 50 to 100), which will often increase
    the cost and complexity of a trial.

9
Selection Bias - A Reminder
  • This is where individuals who are using a
    treatment have some difference, unrelated to the
    treatment, that affects outcome.
  • For example, women using HRT take more exercise,
    are slimmer, have higher social class compared
    with those who do not - may explain
    cardiovascular benefit.

10
Randomisation
  • Randomisation, or similar procedure, will balance
    known and unknown co-variates or confounders
    across the groups and therefore selection bias
    should not occur.
  • Thus, in an HRT trial women in treatment and
    placebo groups will have the same weight,
    exercise levels etc.

11
Selection Bias in Randomised Trials
  • This should not occur in an individually
    randomised trial unless the randomisation has
    been subverted.
  • However, in cluster trials it is possible for
    selection bias to occur after successful cluster
    randomisation.
  • This defeats the objective of randomisation.

12
Selection Bias in Cluster Trials
  • Given enough clusters bias should not occur in
    cluster trials as randomisation will deal with
    this.
  • HOWEVER, the clusters are balanced at the
    individual level ONLY if all eligible people, or
    a random sample, within the cluster are included
    in the trial.

13
Recruitment into cluster trials
  • A key issue is individual participant recruitment
    into cluster trials.
  • There are a number of ways where biased
    participant recruitment can occur, which can lead
    to baseline imbalances in important prognostic
    factors.

14
Participant flow in cluster trial sources of bias
15
Identification Problems
  • For example, in a cluster trial of backpain equal
    number of patients with same severity of back
    pain will be present in both clusters. The
    problem lies in how to identify such patients to
    include them in the interventions. Unless one is
    very careful different numbers and types of
    patient can be selected.

16
UK BEAM Trial
  • The UKBEAM pilot study used a cluster design.
    Eligible patients were identified by GPs for
    trial inclusion.
  • GP practices were randomised to usual care or
    extra training.
  • The primary care team were trained to deliver
    active management of backpain.

17
UK BEAM Selection bias
  • The pilot showed that practices allocated to
    active management were more adept at
    identifying patients with low back pain and
    including them in the trial.
  • Patients had different characteristics in one arm
    than the other.

18
UK BEAM participant recruitment
P 0.025 P 0.001 P 0.03
19
UKBEAM pilot study.
20
UK BEAM
  • Because of the selection bias in the cluster
    design that element of the trial was abandoned
    and the trial reverted to completely individual
    allocation.

21
Cluster Trials Rule 1
  • All eligible patients or a random sample ideally
    MUST be identified BEFORE clusters are
    randomised.
  • Alternatively systems must be put into place to
    PREVENT selective recruitment.

22
Trial Consent Problems
  • Even when it is possible to identify all eligible
    members of a cluster some may not consent to take
    part in the trial. If there is differential
    consent, in particular, this can lead to
    selection bias again.

23
Hip Protector Trial
At this point trial is balanced for all
co-variates
Kannus. N Eng J Med 20003431506.
24
First Rule
  • Kannus trial DID identify all eligible patients
    at baseline, thus, fulfilling first rule of
    cluster randomisation.

25
Hip Protector Trial
Selection Bias
26
Fracture risk Important Co-variates
  • Most important risk factors for hip fracture are
    (in order of importance)
  • Being Female
  • Age
  • Body Weight

27
Important Co-variates Balanced at baseline?
28
Results of Trial.
  • Hip fractures were reduced by 60 (95 CI 0.2 to
    0.8)
  • HOWEVER, arm fractures were also reduced by 30
    (0.3 to 1.5).
  • Suggesting that some or all of the hip fracture
    effect could have been due to selection bias.

29
Hip Protector Trial
30
Cluster Trials Rule 2
  • As in individually randomised trials imperative
    to use intention to treat analysis.

31
Inadequate uptake of intervention
  • Because a robust cluster trial consent to
    randomisation is not given only consent to
    treatment this results in a proportion of
    eligible participants declining the intervention
    BUT have to stay in the trial for intention to
    treat analysis and this reduces study power.
  • This also leads to DILUTION BIAS.

32
Accident prevention
  • In a cluster trial of accident prevention among
    young children 25 of parents in the experimental
    arm did not receive the intervention. Clearly
    this will reduce the power of that trial AND
    dilute any likely treatment effect.

Kendrick et al. BMJ 1999318980.
33
Cluster Trials Rule 3
  • Increase sample size to compensate for less than
    100 uptake of intervention.
  • Or alternatively and in conjunction identify and
    consent before randomisation and then only use
    those participants who have expressed a
    willingness to take part in the trial.

34
Review of Cluster Trials
  • Because of the BEAM problem we decided to
    undertake a methodological review of cluster
    trials.
  • We identified all cluster trials published in the
    BMJ, Lancet, NEJM since 1997.

Puffer et al. BMJ 2003327785.
35
Results
  • We identified 36 relevant trials. ONLY 13 had
    identified participants prior to randomisation.
  • Of the 23 not identifying participants a priori 7
    showed evidence of differential recruitment or
    consent.
  • Other biases included differential of inclusion
    criteria or attrition.
  • In total 14 (39) showed evidence of bias.

36
Underestimate of problem
  • Only in 5 papers did authors alert reader to
    possible problem.
  • Subsequently one of the trials that looked OK
    was published elsewhere where recruitment bias
    was admitted to have occurred.
  • Cluster trials are DIFFICULT to undertake
    robustly.
  • Is there an ALTERNATIVE?

37
Cluster Sample Size
  • Usual sample size estimaes assume independence of
    observations. When people are members of the
    same cluster (e.g., classroom, GP surgery) they
    are more related than we would expect to be at
    random.
  • This is the intra-cluster correlation
    co-efficient.

38
ICC
  • The ICC needs to incorporated into the sample
    size calculations. The formula is as follows
    Design effect 1 (m 1) X ICC. Design effect
    is the size the sample needs to be inflated by.
    M is the number of people in the cluster.

39
Sample size example.
  • Lets assume for an individually randomised trial
    we need 128 people to detect 0.5 of an effect
    size with 80 power (2p 0.05). Now assume we
    have 24 groups with 7 members. The ICC is 0.05,
    which is quite high.
  • 1 (7 1) x 0.05 1.3, we need to increase the
    sample size by 30. Therefore, we will need 166
    participants.

40
What happens if cluster gets bigger?
  • If our cluster size is twice as big (14), things
    begin to get really interesting.
  • 1(14-1)x0.05 1.65.
  • What about 30? (1(30-1)x 0.05 2.45 (I.e, 314
    participants).

41
What makes the ICC large?
  • If the treatment is applied to health care
    provider (e.g., guidelines will increase ICCs for
    patients).
  • If cluster relates to outcome variable (e.g.,
    smoking cessation and schools)
  • If members of cluster are expected to influence
    each other (e.g., households).

42
Reviews of Cluster Trials
Authors Source Years Clustering allowed for in sample size Clustering allowed for in analysis
Donner et al. (1990) 16 non-therapeutic intervention trials 1979 1989 lt20 lt50
Simpson et al. (1995) 21 trials from American Journal of Public Health and Preventive Medicine 1990 1993 19 57
Isaakidis and Ioannidis (2003) 51 trials in Sub-Saharan Africa 1973 2001 (half post 1995) 20 37
Puffer et al. (2003) 36 trials in British Medical Journal, Lancet, and New England Journal of Medicine 1997 2002 56 92
Eldridge et al. (Clinical Trials 2004) 152 trials in primary health care 1997 - 2000 20 59
43
Sample Size Problems
Cluster Trials Demand Larger Sample Sizes
44
Summary of sample size
  • The KEY thing is the size of the cluster. It is
    nearly always best to get lots of small clusters
    than a few large ones (e.g, a trial with small
    hospital wards, GP practices, classrooms will,
    ceteris paribus, be better than large clusters).
  • BUT if the ICC is tiny may not affect the sample
    too much.

45
Analysis
  • Many cluster randomised health care trials have
    been INCOMPETENTLY analysed. Most analyses use
    t-tests, chi-squared tests, which assumes
    independence of observations, which are violated
    in a cluster trial.
  • This leads to spurious p values and narrow CIs.
  • Various methods exist, e.g., multilevel models,
    comparing means of clusters, which will produce
    correct estimates.

46
Cluster Trials Should I do one?
  • If possible avoid like the plague. BUT although
    they are difficult to do, properly, they WILL
    give more robust answers than other methods,
    (e.g., observational data), when done properly.
  • Is it possible to avoid doing them and do an
    individually randomised trial?

47
Contamination
  • An important justification for their use is
    SUPPOSED contamination between participants
    allocated to the intervention with people
    allocated to the control.

48
Spurious Contamination?
  • Trial proposal to cluster randomise practices for
    a breast feeding study new mothers might talk
    to each other!
  • Trial for reducing cardiac risk factors patients
    again might talk to each other.
  • Trial for removing allergens from homes of
    asthmatic children.

49
Contamination
  • Contamination occurs when some of the control
    patients receive the novel intervention.
  • It is a problem because it reduces the effect
    size, which increases the risk of a Type II error
    (concluding there is no effect when there
    actually is).

50
Patient level contamination
  • In a trial of counselling adults to reduce their
    risk of cardiovascular disease general practices
    were randomised to avoid contamination of control
    participants by intervention patients.

Steptoe. BMJ 1999319943.
51
Accepting Contamination
  • We should accept some contamination and deal with
    it through individual randomisation and by
    boosting the sample size rather than going for
    cluster randomisation

Torgerson BMJ 2001322355.
52
Counselling Trial
  • Steptoe et al, wanted to detect a 9 reduction in
    smoking prevalence with a health promotion
    intervention. They needed 2000 participants
    (rather than 1282) because of clustering.
  • If they had randomised 2000 individuals this
    would have been able to detect a 7 reduction
    allowing for a 20 CONTAMINATION.

Steptoe. BMJ 1999319943.
53
Comparison of Sample Sizes
NB Assuming an ICC of 0.02.
54
Misplaced contamination
  • The ONLY study, Im aware of to date, to directly
    compare an individually randomised study with a
    cluster design, showed no evidence of
    contamination.
  • In an RCT of nurse led cardiovascular risk factor
    screening some intervention clusters had
    participants allocated to no treatment. NO
    contamination was observed.

55
Cluster Trials
  • Can cluster trials give different results?
  • All things being equal this shouldnt happen
    (except for a more imprecise estimate). BUT
    because of the greater potential for selection
    bias cluster trials MAY give the wrong answer.

56
An example.
  • There are 14 RCTs of hip protectors for the
    prevention of hip fracture.
  • Nine RCTs are individually randomised trials,
    whilst 5 are cluster trials (e.g., hospital ward,
    nursing home).
  • Cluster trials, without exception show a benefit
    of hip protectors.

57
Hip Protector Trials
Individual RCTS Cluster RCTs
1.19 (0.8 to 1.7) 0.34
0.94 (0.5 to 1.7) 0.53
0.93 (0.5 to 1.7) 0.44
1.17 (0.4 to 3.0) 0.34
0.39 (0.1 to 1.4) 0.11
0.20 (0.0 to 1.6) All Cluster trials, bar , significant, No individual trial was significant
1.49 (0.3 to 7.1) All Cluster trials, bar , significant, No individual trial was significant
3.03 (0.6 to 14.8) All Cluster trials, bar , significant, No individual trial was significant
58
Hip Protector Trials Cluster vs Individually
Randomised.
59
Age differences between good cluster and poor
cluster trials.
Data from Puffer et al.
60
Guidelines
  • Royal College of Physician guidelines for
    fracture prevention grade hip protectors as grade
    A evidence based on flawed, cluster trial,
    evidence.

61
Cluster Trials- What Should We Do?
  • Identify ALL eligible people if possible BEFORE
    randomisation
  • ALWAYS use Intention To Treat analysis
  • INCREASE sample size not only for cluster effects
    but also because of treatment refusal

62
Cluster designs
63
Cluster designs
64
Cluster designs
65
Summary
  • Cluster Trials are currently very trendy
  • Whilst in principle they are a robust. design in
    practice fraught with difficulty.
  • If possible avoid and opt for individual
    randomisation
  • If cluster trial is necessary follow rules to
    avoid bias.
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