introduction to biostatistics for clinical and translational researchers
DESCRIPTION
Introduction to Biostatistics for Clinical and Translational Researchers. KUMC Departments of Biostatistics & Internal Medicine University of Kansas Cancer Center FRONTIERS: The Heartland Institute of Clinical and Translational Research. Course Information. Jo A. Wick, PhD - PowerPoint PPT PresentationTRANSCRIPT
Introduction to Biostatistics for Clinical and Translational
Researchers
KUMC Departments of Biostatistics & Internal Medicine
University of Kansas Cancer Center
FRONTIERS: The Heartland Institute of Clinical and Translational Research
Course Information
Jo A. Wick, PhDOffice Location: 5028 RobinsonEmail: [email protected]
Lectures are recorded and posted at http://biostatistics.kumc.edu under ‘Events & Lectures’
Objectives
Understand the role of statistics in the scientific process and how it is a core component of evidence-based medicine
Understand features, strengths and limitations of descriptive, observational and experimental studies
Distinguish between association and causationUnderstand roles of chance, bias and
confounding in the evaluation of research
Course Calendar
July 5: Introduction to Statistics: Core ConceptsJuly 12: Quality of Evidence: Considerations for
Design of Experiments and Evaluation of LiteratureJuly 19: Hypothesis Testing & Application of
Concepts to Common Clinical Research QuestionsJuly 26: (Cont.) Hypothesis Testing & Application
of Concepts to Common Clinical Research Questions
Why is there conflicting evidence?
Answer: There is no perfect research study.Every study has limitations.Every study has context.
Medicine (and research!) is an art as well as a science.
Unfortunately, the literature is full of poorly designed, poorly executed and improperly interpreted studies—it is up to you, the consumer, to critically evaluate its merit.
Critical Evaluation
Validity and RelevanceIs the article from a peer-reviewed journal?How does the location of the study reflect the
larger context of the population?Does the sample reflect the targeted population?Is the study sponsored by an organization that
may influence the study design or results?Is the intervention feasible? available?
Critical Evaluation
IntentTherapy: testing the efficacy of drug treatments, surgical
procedures, alternative methods of delivery, etc. (RCT)Diagnosis: demonstrating whether a new diagnostic test is
valid (Cross-sectional survey)Screening: demonstrating the value of tests which can be
applied to large populations and which pick up disease at a presymptomatic stage (Cross-sectional survey)
Prognosis: determining what is likely to happen to someone whose disease is picked up at an early stage (Longitudinal cohort)
Critical Evaluation
Causation: determining whether a harmful agent is related to development of illness (Cohort or case-control)
Critical Evaluation
Validity based on intentWhat is the study design? Is it appropriate and
optimal for the intent?Are all participants who entered the trial accounted
for in the conclusion?What protections against bias were put into place?
Blinding? Controls? Randomization?If there were treatment groups, were the groups
similar at the start of the trial?Were the groups treated equally (aside from the
actual intervention)?
Critical Evaluation
If statistically significant, are the results clinically meaningful?
If negative, was the study powered prior to execution?
Were there other factors not accounted for that could have affected the outcome?
Miser, WF Primary Care 2006.
Experimental Design
Statistical analysis, no matter how intricate, cannot rescue a poorly designed study.
No matter how efficient, statistical analysis cannot be done overnight.
A researcher should plan and state what they are going to do, do it, and then report those results.Be transparent!
Types of Samples
Random sample: each person has equal chance of being selected.
Convenience sample: persons are selected
The principal way to guarantee that the sample
population sample
because they are convenient or readily available.Systematic sample: persons selected based
on a pattern.Stratified sample: persons selected from
within subgroup.
Random Sampling
For studies, it is optimal (but not always possible) for the sample providing the data to be representative of the population under study.
Simple random sampling provides a representative sample (theoretically) and protections against selection bias.A sampling scheme in which every possible sub-sample of
size n from a population is equally likely to be selectedAssuming the sample is representative, the summary
statistics (e.g., mean) should be ‘good’ estimates of the true quantities in the population.• The larger n is, the better estimates will be.
Random Samples
The Fundamental Rule of Using Data for Inference requires the use of random sampling or random assignment.
Random sampling or random assignment ensures control over “nuisance” variables.
We can randomly select individuals to ensure that the population is well-represented.Equal sampling of males and femalesEqual sampling from a range of agesEqual sampling from a range of BMI, weight, etc.
Random Samples
Randomly assigning subjects to treatment levels to ensure that the levels differ only by the treatment administered.weightsagesrisk factors
Nuisance Variation
Nuisance variation is any undesired sources of variation that affect the outcome.Can systematically distort results in a particular direction
—referred to as bias.Can increase the variability of the outcome being
measured—results in a less powerful test because of too much ‘noise’ in the data.
Example: Albino Rats
It is hypothesized that exposing albino rats to microwave radiation will decrease their food consumption.
Intervention: exposure to radiationLevels exposure or non-exposureLevels 0, 20000, 40000, 60000 uW
Measurable outcome: amount of food consumedPossible nuisance variables: sex, weight,
temperature, previous feeding experiences
Experimental Design
Types of data collected in a clinical trial:Treatment – the patient’s assigned treatment and actual
treatment receivedResponse – measures of the patient’s response to
treatment including side-effectsPrognostic factors (covariates) – details of the patient’s
initial condition and previous history upon entry into the trial
Experimental Design
Three basic types of outcome data:Qualitative – nominal or ordinal, success/failure, CR,
PR, Stable disease, Progression of diseaseQuantitative – interval or ratio, raw score, difference,
ratio, %Time to event – survival or disease-free time, etc.
Experimental Design
Formulate statistical hypotheses that are germane to the scientific hypothesis.
Determine:experimental conditions to be used (independent
variable(s))measurements to be recordedextraneous conditions to be controlled (nuisance
variables)
Experimental Design
Specify the number of subjects required and the population from which they will be sampled.Power, Type I & II errors
Specify the procedure for assigning subjects to the experimental conditions.
Determine the statistical analysis that will be performed.
Experimental Design
Considerations:Does the design permit the calculation of a valid
estimate of treatment effect?Does the data-collection procedure produce reliable
results?Does the design possess sufficient power to permit and
adequate test of the hypotheses?
Experimental Design
Considerations:Does the design provide maximum efficiency within the
constraints imposed by the experimental situation?Does the experimental procedure conform to accepted
practices and procedures used in the research area?• Facilitates comparison of findings with the results of other
investigations
Types of Studies
Purpose of research1) To explore
2) To describe or classify
3) To establish relationships
4) To establish causalityStrategies for accomplishing these purposes:
1) Naturalistic observation
2) Case study
3) Survey
4) Quasi-experiment
5) Experiment
Ambiguity C
ontrol
Generating Evidence
Studies
Descriptive Studies
Populations Individuals
Case Reports
Case Series
Cross Sectional
Analytic Studies
Observational
Case Control Cohort
Experimental
RCT
Complexity and Confidence
Observation versus Experiment
A designed experiment involves the investigator assigning (preferably randomly) some or all conditions to subjects.
An observational study includes conditions that are observed, not assigned.
Example: Heart Study
Question: How does serum total cholesterol vary by age, gender, education, and use of blood pressure medication? Does smoking affect any of the associations?
Recruit n = 3000 subjects over two yearsTake blood samples and have subjects answer a
CVD risk factor surveyOutcome: Serum total cholesterolFactors: BP meds (observed, not assigned)Confounders?
Example: Diabetes
Question: Will a new treatment help overweight people with diabetes lose weight?
N = 40 obese adults with Type II (non-insulin dependent) diabetes (20 female/20 male)
Randomized, double-blind, placebo-controlled study of treatment versus placebo
Outcome: Weight lossFactor: Treatment versus placebo
Cross-Sectional Studies
Designed to assess the association between an independent variable (exposure?) and a dependent variable (disease?)
Selection of study subjects is based on both their exposure and outcome status, thus there is no direction of inquiry
Cross-Sectional StudiesD
efin
ed P
opul
atio
n
Gather data on Exposure & Disease
Exposed
Diseased
Exposed
No Disease
Not Exposed
Diseased
Not Exposed
No Disease
Cross-Sectional Studies
Cannot determine causal relationships between exposure and outcome
Cannot determine temporal relationship between exposure and outcome
“Exposure is associated with Disease”
“Exposure causes Disease”
“Disease follows Exposure”
Analysis of Cross-Sectional Data
Disease+ -
Exposure
+a b
-c d
Prevalence of disease compared in exposed versus non-exposed groups:
( ) a|p D E
a b+ + =
+
( )|c
p D Ec d
+ - =+
Prevalence of exposure compared in diseased versus non-diseased groups:
( ) a| |p E D
a c+ + =
+
( )|b
p E Db d
+ - =+
Case-Control Studies
Designed to assess the association between disease and past exposures
Selection of study subjects is based on their disease status
Direction of inquiry is backward
Case-Control Studies
De
fine
d
Po
pula
tion
Gather data on Disease
Diseased
Unexposed
Exposed
No Disease
Unexposed
Exposed
Time
Direction of Inquiry
Analysis of Case-Control Data
Disease+ - Total
Exposure
+a b a+b
-c d c+d
Total a+c b+d
Odds ratio: odds of case exposure . odds of control exposure
aadcOR b bc
d
= =
Cohort Studies
Designed to assess the association between exposures and disease occurrence
Selection of study subjects is based on their exposure status
Direction of inquiry is forward
Cohort StudiesD
efin
ed P
opul
atio
n
Gather data on Exposure
ExposedDisease
No Disease
Not ExposedDisease
No Disease
Time
Direction of Inquiry
Cohort Studies
Attrition or loss to follow-upTime and money!Inefficient for very rare outcomesBias
Outcome ascertainmentInformation biasNon-response bias
Analysis of Cohort Data
Disease+ - Total
Exposur
e
+a b a+b
-c d c+d
Total a+c b+d
Relative Risk: risk of disease in exposed . risk of disease in unexposed
aa bRR c
c d
+=
+
Randomized Controlled Trials
Designed to test the association between exposures and disease
Selection of study subjects is based on their assigned exposure status
Direction of inquiry is forward
Randomized Controlled TrialsD
efin
ed P
opul
atio
n
Randomize to Exposure
Exposed (Treated)
Disease
No Disease
Not Exposed (Control)
Disease
No Disease
Time
Direction of Inquiry
Why do we randomize?
Suppose we wish to compare surgery for CAD to a drug used to treat CAD. We know that such major heart surgery is invasive and complex—some people die during surgery. We may assign the patients with less severe CAD (on purpose or not) to the surgery group.If we see a difference in patient survival, is it due to
surgery versus drugs or to less severe disease versus more severe disease?
Such a study would be inconclusive and a waste of time, money and patients.
How could we fix it?
Randomize!Randomization is critical because there is no way for a
researcher to be aware of all possible confounders.Observational studies have little to no formal control for
any confounders—thus we cannot conclude cause and effect based on their results.
Randomization forms the basis of inference.
Other Protections Against Bias
BlindingSingle (patient only), double (patient and evaluator), and
triple (patient, evaluator, statistician) blinding is possibleEliminates biases that can arise from knowledge of
treatmentControl
Null (no treatment), placebo (no active treatment), active (current standard of care) controls are used
Eliminates biases that can arise from the natural progression of disease (null control) or simply from the act of being treated (placebo)
Analysis of RCT Data
What kind of outcome do you have?Continuous? Categorical?
How many samples (groups) do you have?Are they related or independent?
Types of Tests
Parametric methods: make assumptions about the distribution of the data (e.g., normally distributed) and are suited for sample sizes large enough to assess whether the distributional assumption is met
Nonparametric methods: make no assumptions about the distribution of the data and are suitable for small sample sizes or large samples where parametric assumptions are violatedUse ranks of the data values rather than actual data values
themselvesLoss of power when parametric test is appropriate
Two independent percentages? Fisher’s Exact test, chi-square test, logistic regression
Two independent means? Mann-Whitney, Two-sample t-test, analysis of variance, linear regression
Two independent time-to-event outcomes? Log-rank test, Wilcoxon test, Cox regression
Any adjustments for other prognostic factors can be accomplished with the appropriate regression models (e.g., logistic for yes/no outcomes, linear for continuous, Cox for time-to)
Analysis of RCT Data
Threats to Valid Inference
Statistical Conclusion Validity• Low statistical power - failing to reject a false hypothesis because
of inadequate sample size, irrelevant sources of variation that are not controlled, or the use of inefficient test statistics.
• Violated assumptions - test statistics have been derived conditioned on the truth of certain assumptions. If their tenability is questionable, incorrect inferences may result.
Many methods are based on approximations to a normal distribution or another probability distribution that becomes more accurate as sample size increases—using these methods for small sample sizes may produce unreliable results.
Threats to Valid Inference
Statistical Conclusion ValidityReliability of measures and treatment implementation.Random variation in the experimental setting and/or
subjects.• Inflation of variability may result in not rejecting a false hypothesis
(loss of power).
Threats to Valid Inference
Internal ValidityUncontrolled events - events other than the
administration of treatment that occur between the time the treatment is assigned and the time the outcome is measured.
The passing of time - processes not related to treatment that occur simply as a function of the passage of time that may affect the outcome.
Threats to Valid Inference
Internal ValidityInstrumentation - changes in the calibration of a
measuring instrument, the use of more than one instrument, shifts in subjective criteria used by observers, etc.• The “John Henry” effect - compensatory rivalry by subjects
receiving less desirable treatments.• The “placebo” effect - a subject behaves in a manner consistent
with his or her expectations.
Threats to Valid Inference
External Validity—GeneralizabilityReactive arrangements - subjects who are aware that
they are being observed may behave differently that subjects who are not aware.
Interaction of testing and treatment - pretests may sensitize subjects to a topic and enhance the effectiveness of a treatment.
Threats to Valid Inference
External Validity—GeneralizabilitySelf-selection - the results may only generalize to
volunteer populations.Interaction of setting and treatment - results obtained in a
clinical setting may not generalize to the outside world.
Clinical Trials—Purpose
Prevention trials look for more effective/safer ways to prevent a disease in individuals who have never had it, or to prevent a disease from recurring in individuals who have.
Screening trials attempt to identify the best methods for detecting diseases or health conditions.
Diagnostic trials are conducted to distinguish better tests or procedures for diagnosing a particular disease or condition.
Clinical Trials—Purpose
Treatment trials assess experimental treatments, new combinations of drugs, or new approaches to surgery or radiation therapy for efficacy and safety.
Quality of life (supportive care) trials explore means to improve comfort and quality of life for individuals with chronic illness.
Classification according to the U.S. National Institutes of Health
Clinical Trials—Phases
Pre-clinical studies involve in vivo and in vitro testing of promising compounds to obtain preliminary efficacy, toxicity, and pharmacokinetic information to assist in making decisions about future studies in humans.
Clinical Trials—Phases
Phase 0 studies are exploratory, first-in-human trials, that are designed to establish very early on whether the drug behaves in human subjects as was anticipated from preclinical studies.Typically utilizes N = 10 to 15 subjects to assess
pharmacokinetics and pharmacodynamics.Allows the go/no-go decision usually made from animal
studies to be based on preliminary human data.
Clinical Trials—Phases
Phase I studies assess the safety, tolerability, pharmacokinetics, and pharmacodynamics of a drug in healthy volunteers (industry standard) or patients (academic/research standard).Involves dose-escalation studies which attempt to identify
an appropriate therapeutic dose.Utilizes small samples, typically N = 20 to 80 subjects.
Clinical Trials—Phases
Phase II studies assess the efficacy of the drug and continue the safety assessments from phase I.Larger groups are usually used, N = 20 to 300.Their purpose is to confirm efficacy (i.e., estimation of
effect), not necessarily to compare experimental drug to placebo or active comparator.
Clinical Trials—Phases
Phase III studies are the definitive assessment of a drug’s effectiveness and safety in comparison with the current gold standard treatment.Much larger sample sizes are utilized, N = 300 to 3,000,
and multiple sites can be used to recruit patients.Because they are quite an investment, they are usually
randomized, controlled studies.
Clinical Trials—Phases
Phase IV studies are also known as post-marketing surveillance trials and involve the ongoing or long-term assessment of safety in drugs that have been approved for human use.Detect any rare or long-term adverse effects in a much
broader patient population
The Size of a Clinical Trial
Lasagna’s LawOnce a clinical trial has started, the number of suitable
patients dwindles to a tenth of what was calculated before the trial began.
The Size of a Clinical Trial
“How many patients do we need?”Statistical methods can be used to determine the
required number of patients to meet the trial’s principal scientific objectives.
Other considerations that must be accounted for include availability of patients and resources and the ethical need to prevent any patient from receiving inferior treatment.We want the minimum number of patients required to
achieve our principal scientific objective.
The Size of a Clinical Trial
Estimation trials involve the use of point and interval estimates to describe an outcome of interest.
Hypothesis testing is typically used to detect a difference between competing treatments.
The Size of a Clinical Trial
Type I error rate (α): the risk of concluding a significant difference exists between treatments when the treatments are actually equally effective.
Type II error rate (β): the risk of concluding no significant difference exists between treatments when the treatments are actually different.
The Size of a Clinical Trial
Power (1 – β): the probability of correctly detecting a difference between treatments—more commonly referred to as the power of the test.
Truth
Conclusion H1 H0
H1 1 – β αH0 β 1 – α
The Size of a Clinical Trial
Setting three determines the fourth: For the chosen level of significance (α), a clinically
meaningful difference (δ) can be detected with a minimally acceptable power (1 – β) with n subjects.
Depending on the nature of the outcome, the same applies: For the chosen level of significance (α), an outcome can be estimated within a specified margin of error (ME) with n subjects.
Example: Detecting a Difference
The Anturane Reinfarction Trial Research Group (1978) describe the design of a randomized double-blind trial comparing anturan and placebo in patients after a myocardial infarction.What is the main purpose of the trial?What is the principal measure of patient outcome?How will the data be analyzed to detect a treatment
difference?What type of results does one anticipate with standard
treatment?How small a treatment difference is it important to detect
and with what degree of uncertainty?
Example: Detecting a Difference
Primary objective: To see if anturan is of value in preventing mortality after a myocardial infarction.
Primary outcome: Treatment failure is indicated by death within one year of first treatment (0/1).
Data analysis: Comparison of percentages of patients dying within first year on anturan (π1) versus placebo (π2) using a χ2 test at the α = 0.05 level of significance.
Example: Detecting a Difference
Expected results under placebo: One would expect about 10% of patients to die within a year (i.e., π2 = .1).
Difference to detect (δ): It is clinically interesting to be able to determine if anturan can halve the mortality—i.e., 5% of patients die within a year—and we would like to be 90% sure that we detect this difference as statistically significant.
Example: Detecting a Difference
We have:H0: π1 = π2 versus H1: π1 π2 (two-sided test) α = 0.051 – β = 0.90δ = π2 – π1 = 0.05
The estimate of power for this test is a function of sample size:
2 2
1 1 1 2 2 2 1 1 1 2 2 2
1z SE z SE
P z P zp q n p q n p q n p q n
n = 583 patients per group is required
Example: Detecting a Difference
-zα/2 zα/2
Fail to reject H0
Conclude no difference
Reject H0
Conclude differenceReject H0
Conclude difference
α/2 α/21 - α
β 1 - β
Power and Sample Size
n is roughly inversely proportional to δ2; for fixed α and β, halving the difference in rates requiring detection results in a fourfold increase in sample size.
n depends on the choice of β such that an increase in power from 0.5 to 0.95 requires around 3 times the number of patients.
Reducing α from 0.05 to 0.01 results in an increase in sample size of around 40% when β is around 10%.
Using a one-sided test reduces the required sample size.
Example: Detecting a Difference
Primary objective: To see if treatment A increases outcome W.
Primary outcome: The primary outcome, W, is continuous.
Data analysis: Comparison of mean response of patients on treatment A (μ1) versus placebo (μ2) using a two-sided t-test at the α = 0.05 level of significance.
Example: Detecting a Difference
Expected results under placebo: One would expect a mean response of 10 (i.e., μ2 = 10).
Difference to detect (δ): It is clinically interesting to be able to determine if treatment A can increase response by 10%—i.e., we would like to see a mean response of 11 (10 + 1) in patients getting treatment A and we would like to be 80% sure that we detect this difference as statistically significant.
Example: Detecting a Difference
We have:H0: μ1 = μ2 versus H1: μ1 μ2 (two-sided test) α = 0.051 – β = 0.80δ = 1
For continuous outcomes we need to determine what difference would be clinically meaningful, but specified in the form of an effect size which takes into account the variability of the data.
Example: Detecting a Difference
Effect size is the difference in the means divided by the standard deviation, usually of the control or comparison group, or the pooled standard deviation of the two groups
where
1 2d
2 21 2
1 2n n
Example: Detecting a Difference
-zα/2 zα/2
Fail to reject H0
Conclude no difference
Reject H0
Conclude differenceReject H0
Conclude difference
α/2 α/21 - α
β 1 - β
Example: Detecting a Difference
Power Calculations an interesting interactive web-based tool to show the relationship between power and the sample size, variability, and difference to detect.
A decrease in the variability of the data results in an increase in power for a given sample size.
An increase in the effect size results in a decrease in the required sample size to achieve a given power.
Increasing α results in an increase in the required sample size to achieve a given power.
Prognostic Factors
It is reasonable and sometimes essential to collect information of personal characteristics and past history at baseline when enrolling patient’s onto a clinical trial.
These variables allow us to determine how generalizable the results are.
Prognostic Factors
Prognostic factors known to be related to the desired outcome of the clinical trial must be collected and in some cases randomization should be stratified upon these variables.
Many baseline characteristics may not be known to be related to outcome, but may be associated with outcome for a given trial.
Comparable Treatment Groups
All baseline prognostic and descriptive factors of interest should be summarized between the treatment groups to insure that they are comparable between treatments. It is generally recommended that these be descriptive comparisons only, not inferential
Note: Just because a factor is balanced does not mean it will not affect outcome and vice versa.
Subgroup Analysis
Does response differ for differing types of patients? This is a natural question to ask.
To answer this question one should test to see if the factor that determines type of patient interacts with treatment.
Separate significance tests for different subgroups do not provide direct evidence of whether a prognostic factor affects the treatment difference: a test for interaction is much more valid.
Tests for interactions may also be designed a priori.
Multiplicity of Data
Multiple Treatments – the number of possible treatment comparisons increases rapidly with the number of treatments. (Newman-Keuls, Tukey’s HSD or other adjustment should be designed)
Multiple end-points – there may be multiple ways to evaluate how a patient responds. (Bonferroni adjustment, Multivariate test, combined score, or reduce number of primary end-points)
Multiplicity of Data
Repeated Measurements – patient’s progress may be recorded at several fixed time points after the start of treatment. One should aim for a single summary measure for each patient outcome so that only one significance test is necessary.
Subgroup Analyses – patients may be grouped into subgroups and each subgroup may be analyzed separately.
Interim Analyses – repeated interim analyses may be performed after accumulating data while the trial is in progress.
Summary
Statistics plays a key role in pre-clinical and clinical research
Statistics helps us determine how ‘confident’ we should be in the results of a study
Confidence in a study is based on (1) the size of the study, (2) its safeguards against biases (complexity), (3) how it was actually undertaken
Statistical support is available and should be sought out as early as possible in the process of designing a study
Next Time . . .
Basic Descriptive and Inferential MethodsHypothesis Testing
P-valuesConfidence IntervalsInterpretation
Examples