Stats, Trial Design, Interpretation

Question 1

Internal validity

Answer 1

 How is the study structured?

 Is it a “good” study?

 Study design issues

Question 2

External Validity

Answer 2

 Does the study apply to my situation?

 Is it applicable to the patients I see?

 Is it practical?

 Generalizability

Question 3

Types of Study Design -5

Answer 3

 Descriptive

 Observational
 Case control
 Follow-up
 Cross-sectional

 Experimental

Question 4

Types of Study Design - descriptive -3

Answer 4

No comparative group– no intervention

ex. case study, case series, survey, education intervention with no comparator

can be large (ie. 30,000 high dose theophylline)

Question 5

Types of Study Design - observational (epidemiological) (think watchful scientist)

Answer 5

Comparative group; no intervention

1. case control: based on outcome
2. follow-up: based on risk factors
3. cross-sectional: hybrid of the two

Question 6

Types of Study Design - experimental -7

Answer 6

Comparative group

 Patients selected

 Consent

 Investigator allocates

 Intervention

 Measurements

 Assess outcome

Question 7

Types of Study Design - experimental - Parallel vs Crossover - PARALLEL DEF-4

Answer 7

 Each patient receives one therapy

 Two concurrent groups

 Interpatient variability

NEED MORE PTS

Question 8

Types of Study Design - experimental - Parallel vs Crossover - CROSSOVER DEF-5

Answer 8

 Each patient receives one therapy then another

 Randomized to sequence (everyone gets both drugs)

 Tx A -> outcome -> Washout (5 half-lifes) ->Tx B -> outcome

 Position effect (statistics)

FEWER PATIENTS NEEDED

Question 9

Types of Study Design - experimental - ADVANTAGES -4

Answer 9

 Control more variables, can blind

 Decrease sources of bias

 Ascertain cause and effect (can not say that in other trials)

 “Cadillac” of study designs

Question 10

Analyzing Methods Section - FLUFF

Answer 10

 Types of bias

 Often use flowcharting to follow a patient through the study

Question 11

Selection Bias -5

use Table 1

Answer 11

 Was bias introduced in how the patients were selected?

 Is the study population adequately defined?

 Inclusion and exclusion criteria

 Treatment groups comparable

 See “Table 1” of study

Question 12

Classification Bias def -2

Answer 12

Refers to how classifications made (bias can be made in recruiting pts, often defs in supplementary material, definitions can be extensive)

 ex. Postmenopausal, Receptor positive, Outcomes—disease-free—survival event

Question 13

Preventing Classification Bias -3

Answer 13

 Use structured definitions

 Use “reliable,” “complete” sources of information

-is EHR good source of info

Question 14

Allocation Bias def -2

use Table 1

Answer 14

 Was bias introduced when patients assigned to their groups? - very hard to assess because studies often just say “pts were randomized”

 Was it truly random? use Table 1 to see if equal

Question 15

Randomization method -1

Answer 15

 Permutated blocks (for every 4 pts, assign 2 to a group -> this allows study to stop in middle if needed)
 Keeping even numbers of patients in the groups throughout the conduct of the study (to allow better stats)
 Stratified according to participating center
 Chemotherapy planned to be given before, during or not at all

Question 16

Compliance Bias def -3

Answer 16

 How was compliance assessed?

 Not ALWAYS specifically addressed in study - this makes it HARD to assess

 ie. Semiannual visits for first 5 years

Question 17

Attrition Bias def -3

Answer 17

 Drop-outs and why (acct for all pts)

• ie. may just drop out (withdraw consent) or be ineligible following medical review

 If more patients drop out of one group vs another, does this introduce bias or influence the results?

Question 18

Interventions def -3

Answer 18

 Comparable

 Blinding
Double-blind: Neither investigator nor patient knows patient allocation
 Single-blind: Either patient or investigator does not know

 Competing interventions (that would influence results)

Question 19

Observer and Measurement bias -5

prevent with blinding

Answer 19

 How are outcomes measured?

 Is it appropriate?

 Patient or observer influences

 Sufficient observation (challenging, need many yrs for oncology)

 Is it clinically meaningful?

Question 20

Confounding Bias -4

all studies susceptible

Answer 20

 Attributing the outcome to a risk factor not related to the outcome (wrongly attributing outcome)

 Can control for many variables in the analysis

 Often difficult to prevent

 Look at exclusion criteria

Question 21

Preventing Other Problems - Is the study powered to be meaningful? -3

Answer 21

 Study enough patients

 Discuss with statistical power

 Usually discussed when sample size calculations presented in methods

Question 22

Analyzing Results

Answer 22

 Add numbers to flow chart (assess attrition)

 Follow the numbers

 Attrition

 Present results for EVERYTHING mentioned in methods

 Statistics

Question 23

What Data To Include - Intention to treat

Answer 23

All patients randomized included in analysis

Considered the most conservative analysis

Question 24

What Data To Include - Modified intention to treat

Answer 24

all patients randomized AND received at least one dose of therapy

Question 25

What Data To Include - Per protocol

Answer 25

Only those patients who completed the study per protocol (ie, pt’s dropped if ADR and stopped tx)

For many studies useful to have both an intention to treat method and a per protocol

Question 26

Statistical Analysis -Descriptive -3

Answer 26

 measure of central tendency

mean, median, mode, etc.

 spread of the data

Question 27

Statistical Analysis -Inferential 1

Answer 27

Null hypothesis =No difference exists

Question 28

Non-inferiority Trials -3 &&&

new in last 10 years

hard

Answer 28

 Use a different hypothesis: The two treatments are not non-inferior to each other (tough because double negatives) (think the treatments are same)

 P values mean different things—if less than 0.05, means they are non-inferior

 Can’t claim superiority with these trials but can do a non-inferiority analysis then a superiority analysis

Question 29

Non-inferiority Trials -Why? -4

Answer 29

 Unethical to do a placebo controlled trial

 Treatment expected to be similar to standard treatment (Therapeutic non-inferiority to active control)

 Treatment assumed to be better than placebo

 Treatment likely to have other advantages (safety, cost, convenience . . .)

Question 30

Non-inferiority Trials -set up -3

no clue here

Answer 30

 Set a “marginal difference”

 Uses alternative hypothesis

 Set confidence interval threshold

-actually need more pts for this type of trial

Question 31

study types - superiority vs equivalence vs non-inferior def -3

Answer 31

 Superiority trials (Is new therapy significantly better or worse?)

 Equivalence trials “neither any better or any worse” (Establish equivalence range. Is it in the range to be similar?) (to see if 2 drugs are pharmaceutically equivalent)

 Non-inferiority “not much worse than the active comparator” (Is new therapy no worse than control?)

Question 32

Statistical Tests - Nominal: yes or no - def and examples

Answer 32

 Categorical

 Response rate (patients responded or not)

 Adverse events or not

 Alive or dead

 Pregnant or not

 Race

Question 33

Statistical Tests - Nominal Data “Traps” -2

Answer 33

 Percentages
 Seem like on a continuous scale
 Think of the data origin
 Did the patient have a response or not?
 Response is yes-no
 Presented as % patients with response

 Multiple groups or categories
 Still assess if yes or no they belong to each group
 No ranking

Question 34

Statistical Tests - Nominal Data Tests -4

Answer 34

 Chi-Square (lots of rules)
 N>40
 20-40 use if expected frequency of cells >5

 Fishers exact (if N<30 use but can use for all nominal data)

 Related samples: McNemar (cross-over)

 3 or more independent groups: Chi-Square (also called Chi-Squared for independent groups)

Question 35

Statistical Tests - Ordinal Data def -6

Answer 35

 Ranked

 Likert scales (strongly agree to strongly disagree)

 Hierarchy

 Responses not mathematically equal

 ie. Years of HRT (none, 0-5 years, 5-10 years, greater than 10 years), Age of diagnosis (less than 50, 50-55, 55-65, older)

Question 36

Statistical Tests - Ordinal Data “Traps” -4

Answer 36

 Likert scale (1-5, strongly disagree-strongly agree)

 Calculate means

 Behaves like continuous data and presented as continuous—need to remember still ordinal data!!

 Useful to present median, mode, “top box” = positive responses like Likert 4 and 5 only

-USE MEDIAN NOT MEAN

Question 37

Statistical Tests - Ordinal Data Tests -4

Answer 37

 Mann Whitney U test (based on MEDIAN)

 Wilcoxon rank sum test

 Related samples (cross-over)
 Sign test
 Wilcoxon signed rank test

 Kruskal-Wallis ANOVA (for multiple groups)

Question 38

Statistical Tests - Continuous Data -Continuous “Traps” -2

Answer 38

 Data presented as % probably not continuous

 Are composite scales, etc, really continuous?— many times yes!
 Battery of ordinal scales
 Total (when all batteries combined together) behaves as continuous

Question 39

Statistical Tests - Continuous Data -def and examples

Answer 39

 Interval, ratio data

 Time to disease progression

 WBC, platelet count

 Serum creatinine

 age, weight

Question 40

Statistical Tests - Continuous Data: VAS -2

Answer 40

 Visual analog scales (VAS)
   Scale of 0-10, 0 being no pain, 10 being the worst pain imaginable (DO NOT DEFINE THE POINTS IN BETWEEN)
   Only anchors the ends 
   Administered verbally or in writing 
   Handled as continuous data

 Other pain scales: 0=no pain, 1=mild, 2=moderate, 3=severe
 Defines all points
 Handled as ordinal data

Question 41

Statistical Tests - Continuous Data Tests -5

Answer 41

 Parametric vs Non-parametric

 Mann-Whitney U (median)

 Student’s t-test (2 groups) (mean)
 Normal distribution (are both mean and median similar), equal variance (are std deviations the same)

 Related Data: paired t-test (cross-over)

 ANOVA (3 or more groups)

Question 42

Hypothesis Testing -4

Answer 42

 Start with null hypothesis

 Superiority trial: There is no difference

 Equivalence: The groups are not equivalent

 Non-inferority: The therapy is not non-inferior to the other therapy

Question 43

Types of Error—Superiority

columns across are truths

rows are experiment

Answer 43

1. Type I or alpha error (alpha, p value) TOP RIGHT OF BOX = experiment shows “difference exists” WHEN IN FACT truth is “no difference”. alpha is set up front as 0.05, P VALUE DETERMINED AFTER STUDY AND IS NEW ALPHA AND TELLS IF SIG
2. Type II or beta error (beta) BOTTOM LEFT OF BOX= experiment shows “no difference exists” WHEN IN FACT truth is “difference”. beta is set up front. 0.2 is good, some do lower UNFORTUNATELY NO EQUIVALENT P VALUE TO FIGURE WHERE WE REALLY FELL

Question 44

Types of Error—Superiority

columns across are truths

rows are experiment

Answer 44

1. Type I or alpha error (alpha, p value) TOP RIGHT OF BOX = experiment shows “difference exists” WHEN IN FACT truth is “no difference”. alpha is set up front as 0.05, P VALUE DETERMINED AFTER STUDY AND IS NEW ALPHA AND TELLS IF SIG
2. Type II or beta error (beta) BOTTOM LEFT OF BOX= experiment shows “no difference exists” WHEN IN FACT truth is “difference”. beta is set up front when doing sample size. 0.2 is good, some do lower UNFORTUNATELY NO EQUIVALENT P VALUE TO FIGURE WHERE WE REALLY FELL

Question 45

Power and Sample Size -5

picked at the begining

Answer 45

 Power = 1 - beta

 Determined by alpha (p value) and beta values desired

 Estimated response rate

 Difference believed to be valuable

 Front-end concept!!

Question 46

Sample Size Calculations using power

Answer 46

slide 80 &&&

Question 47

Expressing Risk - three types and data used -3

Answer 47

 Expressed as odds ratio, relative risk or hazard ratio

 Used for nominal data ONLY!!!

 Use a 2x2 table—helpful for organizing data in
study

Question 48

Odds Ratio def and trial use -3

ESTIMATE OF RISK

Answer 48

Based on prevalence

No denominator, making assumptions

Case Control, cross-sectional

Question 49

Relative Risk def and trial use -4

Answer 49

Based on incidence

Denominator

Association between exposure and disease over time

Follow-up, experimental

Question 50

Incidence -2

PREVALENCE IS WITHOUT UNIT OF TIME

Answer 50

 (Number of persons developing dx/ total at risk) per unit of time

 Direct estimate of probability or risk

Question 51

Relative Risk rationale and calculation -5

Answer 51

 Expression of risk for follow-up studies (also experimental trials)

 Accounts for denominator information

 Calculation: RR = (a/a+b) / (c/c+d)

 The proportion between the two!!

 Usually presented with a confidence interval

Question 52

Interpreting Risk (by outcome) -4

Answer 52

 1 = no difference between the groups

 2-5 = mild association

 5-10 = moderate association

 > 10 = strong association

Question 53

Relative Risk Reduction -3

RELATIVE BENEFIT INCREASE

Answer 53

 The most “optimistic” way to present risk

ie.
 Calculated 1-RR = 1-0.82= 0.18= 18%
 Letrozole decreased the risk of a disease free survival event by 18%

Question 54

Absolute Risk Reduction -3

ABSOLUTE BENEFIT INCREASE

Answer 54

 Takes into account the actual values of the numbers rather than just the proportion

 Are we talking events that occur 1 in 10 or 1 in 1000?!!

ie.
 Calculated (A/A+B)- (C/C+D) =8.8%-10.7% = 1.9% (absolute value) -NOTE INCIDENCE DIFF

Question 55

Number Needed to Treat (NNT) calculation and use-3

VERY IMPT -KNOW

Answer 55

 Inverse of ARR
 Be sure to convert percentages to decimals

 Way to make numbers more practical and meaningful

 Concept is “Number Needed to Harm” (NNH) for adverse events

-ALWAYS ROUND TO NEAREST WHOLE PERSON

Question 56

Survival Analysis -5 &&&

BASICALLY RELATIVE RISK AMPED UP

EX. BREAST CANCER AND HORMONE EVENTS JUMPED AFTER 5 YRS - THINGS CHANGE OVER TIME

Answer 56

 Takes into account the timing of events

 Weighted relative risk over the entire study

 Result is Hazard Ratio (HR)

 Data presented in Kaplan—Meier curves

 Cox proportional hazards regression the most common for multivariate analyses; log rank test for differences in survival

Question 57

example need for survival analysis - 2

Answer 57

 Takes into account that you had many patients for the first two years, and not as many in the last 3 years

 Same number of events in end, but different denominators over time

Question 58

Censoring def -1 and examples -4 -slide 101&&&when is arm favored??

Answer 58

 Accounting for missing or incomplete data
 Study ends before patient has an event
 Patient is lost to follow-up
 Patient withdraws due to an adverse event
 Patients voluntarily crossed over to other tx (ie. letrazole)

Question 59

IPCW: Inverse Probability of Censoring Weighted analysis DEF -1

Answer 59

Modeling technique to account for bias introduced in censoring

Question 60

Censoring vs ITT issues -3

Answer 60

 ITT: Tamoxifen looks better than it may be (patients that crossed over to letrozole included =pt likely had better outcomes)

 Censored: Only disease free patients allowed to cross-over. High risk patients left in tamoxifen group.=pts likely had worse outcomes

-USE IPCW analysis to account for adjust for these biases

Question 61

RR vs HR &&&slide 103 clarify

Answer 61

 Relative risk can easily be calculated from numbers presented in the study

 Hazard ratio is the same concept but is the weighted relative risk over time
 Adjusts for change over time
 Adjusts for “repeated measures”
 Adjusts for different “slopes” of the line

Question 62

P-Value def -3

Answer 62

 Probability results due to chance alone

 Determine level of significance (alpha value)
prior to conducting the study

 By custom, p < 0.05 is considered “statistically significant”

Question 63

Statistical Pearls as related to p value -4

Answer 63

 The size of the p value has nothing to do with the importance of the result (ONLY YOU DETERMINE THIS, ie. p=0.001 for bp med which measured 2mmHG diff)

 Do not confuse statistical significance with clinical significance

 Results that are not statistically significant MAY still be important

Statistics do not determine what is important, statistics determine how certain we are.

Question 64

Confidence Interval -5

Answer 64

 95% CI (If study was repeated 100 times, 95% of the time the result would likely fall in this range)

 Provides a “range” to result (Inferences on the population) (DO NOT CONFUSE CI WITH STD DEV, which only tell you about variation in study)

 Calculation based on Standard Error of Mean (SEM

 CI can be applied to any type data
 IMPT TO Determine value that represents no difference

 When used with OR, RR or HR
 No difference value = 1 (If CI doesn’t include 1, then statistically significant)

Question 65

Other Statistical Issues: Repeated Measures - Cox model - 3

Answer 65

 If made multiple measurements over time, then need to correct for it using a statistical test that takes into account repeated measures

 ie. Evaluated every 6 months

 Cox model accounts for this

Question 66

Other Statistical Issues: Bonferroni Effect -3 &&&clarify slide 113

NOT CLEAR

Answer 66

 If look at enough things, something will be statistically significant just by chance alone

 If didn’t make correction and should have, multiply the p value by number of comparisons.

 2009 states adverse drug reaction (ADR) analysis not adjusted for multiple comparisons

Question 67

WHEN IS IT POSSIBLE TO MAKE A BETA ERROR?

Answer 67

When p value is >0.5 because you are saying there is NO DIFFERENCE BETWEEN THE GROUPS.

Question 68

Duration of Studies

Answer 68

 Were patients studied for sufficient duration?

 Do the results change over time?

 Are the same things being compared at each time point? &&&

Question 69

Subgroup Analysis key points -4

Answer 69

 Allocation no longer applies (NOT RANDOM)

 Sample size calculations don’t hold for
subgroups (POWER NOT APPLIED)

 As more subgroups evaluated, more opportunity for finding a significant result when one does not exist

 Results can be overstated and misleading

Question 70

Interpreting Forest Plots 
when used? -2
what does bar mean? -1
what does box mean? -2
do shorter bars usually have larger boxes?

Answer 70

 Used with subgroup analysis and meta-analyses

 Bar = confidence interval

 Box
 Location = HR
 Size = number of people in analyses

 Usually shorter bars have larger boxes = smaller
confidence interval as increase sample = more confident of result

Question 71

Meta-Analysis

Answer 71

 Combine results from many studies

 Reanalyze

 Decrease beta

 Specific criteria for selection and classification of studies (selection bias refers to how studies selected!!)

 Studies should have similar methodologies

 Compounds problems observed in the individual studies

Question 72

Effect Size slide128-130&&&never heard of this

NOT COVERED IN VIDEO

Answer 72

 Way to standardize the effect

 Used for continuous data with normal
distribution

 Calculated by dividing the difference of means by standard deviation

 Use table from website to interpret and make more practical

Question 73

Reporting Data key concepts &&&clarify

Answer 73

 How reported affects significance placed on data

 Watch graphs!! (CAN BE MISLEADING)

 Changing numbers to %

 Collapsing data in categories

 % change from baseline

Question 74

Case-control Studies def -3

Answer 74

 Identify cases with the disease of interest (outcome)

 Identify controls without the outcome

 Look back in time (from present to past) to assess the risk factors

Question 75

Retrospective study. . . .key concepts -3

Answer 75

 Often confusing terminology

 Study design: another name for case control

 Refer to the time frame of the study

Question 76

Application of Case- Control -4
what to apply to?
“rare” yes or no?
expensive?

Answer 76

 Applied to new diseases or outbreaks

 Can study “rare” diseases

 Evaluate multiple risk factors

 Relatively easy and less expensive

Question 77

Weakness of Case - Control, aka types of bias -4

Answer 77

 Selection bias

 Classification bias

 Information bias&&&

 Confounding bias&&&

Question 78

Cross - Sectional study def -4

Answer 78

 Identify a study population (from present going forward)

 First Classify based on outcome

 Second separate outcomes to Classify based on risk factor

 Predict prevalence

Question 79

Cross - Sectional Problems / weaknesses -4

Answer 79

 Chicken and the egg

 Confounding bias &&&

 Selection bias

 Classification bias

Question 80

Follow-up Studies def -5

Answer 80

 Identify a study population (from present to future)

 Exclude individuals with the outcome of interest

 THEN those without outcome of interest -> Classify based on risk factor

 Follow over time

 Assess outcome

Question 81

Follow-up study features -4

why best?

Answer 81

 Strongest study design

 Strongest causal link

 Denominator; predict incidence

 Can usually address information bias &&&

Question 82

Follow-up bias / weakness -4

Answer 82

 Hawthorne effect &&&

 Surveillance bias

 Change over time

 Attrition bias &&&

Question 83

Issues in Oncology Studies -6

Answer 83

 Duration of therapy and evaluation

 Results represented

 Endpoints selected

 Combination therapy

 Doses, regimens, routes

 Balancing cost and clinical outcomes

Question 84

basics of statistical tests -3

Answer 84

type of data (nominal, ordinal, continuous)

number of groups

independent (parallel) OR related (cross-over) groups