Statistics

Question 1

Formula for standard error of the mean (SEM)?

Answer 1

SEM = SD / square root on (n)

SD - standard deviation
n = sample size

SEM gets smaller as sample size (n) increases

Question 2

Definition of power of a study?

Answer 2

Power = 1 - the probability of type II error
The probability that a statistically significant difference will be detected
Probability of (correctly) rejecting the null hypothesis when it is false OR
Probability of confirming the alternative hypothesis when the alternative hypothesis is true
Power can be increased by increasing the sample size

Question 3

Examples of observational studies

Answer 3

Cohort study
Case-control study
Cross-sectional study
Case series

Question 4

Studies organised in level of evidence they provide.

Answer 4

Systematic reviews  
RCTs
Cohort studies
Case-control studies
Cross-sectional studies
Case series

Question 5

Prospective cohort study

Answer 5

Sample recruited from population in the present, relevant predictors are measured, cohort is followed overtime to measure outcomes
Usual outcome measure is relative risk

Pro: more control over what is measured and how; can measure confounders
Con: expensive; wait until outcome occurs; rare outcome = need more participants

Question 6

Retrospective cohort study

Answer 6

Cohort assembled after an outcome has occurred using stored data

Pro: cheaper, faster
Con: data quality limited

Question 7

Case-control study

Answer 7

Start off with people with the disease and ask about exposure
Usual outcome measure is odds ratio

Pro: efficient for rare diseases and outbreaks
Con: hard to find matched controls; recall bias; confounding

Question 8

Cross-sectional study

Answer 8

Random sample of a population in a point in time.

Descriptive: prevalence of a disease or exposure

Analytic: examine relationship between between different things e.g. obesity and arthritis

Can provide evidence of association but not about causality (hard to determine what came first)

Question 9

Best study design for an intervention question?

Answer 9

Best primary study: RCT

Highest level of evidence: systematic review of RCTs

Question 10

Best study design for question of harm or prognosis?

Answer 10

Prospective cohort study
Individual prospective cohort study
Retrospective cohort study
Case-control study

Question 11

Best study type for questions of diagnostic test accuracy

Answer 11

Cross-sectional analytic study where the 2 tests are performed on the study participants

Question 12

Best primary study type for prevalence of disease?

Answer 12

Cross-sectional descriptive study

Burden of disease

Question 13

Best primary study type for incidence of disease?

Answer 13

Cohort study

Specified period of time; looks at cause of disease

Question 14

Relative risk

Answer 14

The risk of something occurring relative to the chance of it occurring under different circumstances

= (incidence in exposed)/(incidence in unexposed)
i.e. use division

RR <1: treatment is beneficial
RR >1: treatment is harmful
RR = 1: treatment has no effect

Used in RCTs and cohort studies - need to know incidence

Question 15

Absolute Risk Reduction

Answer 15

= (incidence of disease in exposed) - (incidence of disease in unexposed)
i.e. Use subtraction

Must remain aware if exposure has increased or decreased the risk

Question 16

Number needed to treat

Answer 16

Number of people that need to be treated in order to prevent one negative outcome

NNT = 1 / (risk difference)

Question 17

Odds Ratio

Answer 17

= (odds of exposure to the risk factor of interest in the cases) / (odds of exposure to the risk factor of interest in controls)
Used in case control studies

OR 0.6 = the exposed group is 40% less likely to develop specific outcomes compared to the control group

OR 1.5 = risk increased by 50%

Question 18

P value

Answer 18

Probability that the observed results of the study are due to chance rather than an actual effect

IF p<0.05, the probability of getting the results by chance alone is 5% (i.e. statistically significant)

Question 19

Confidence intervals

Answer 19

Provides us with a range within which we would expect the true effect to lie

Wide CI = poor precision
Narrow CI = good precision

IF using RR

Question 20

Random error

Answer 20

Chance
Gives results either side of the true answer with the mean of all results being close to the true answer

Narrow confidence interval = less random error

Question 21

Systematic error

Answer 21

Bias

Differ in one direction from the truth

Question 22

Internal validity

Answer 22

How likely it is that the results are are correct for the sample of participants being studied.

Selection bias impacts the internal validity of a study

Question 23

External validity

Answer 23

How likely it is that the results will hold true for other settings
= generalisability of the study

Question 24

State 2 principles of a confounder

Answer 24

1. has to be associated both with the risk factor of choice and the outcome
2. fits into the causal pathway between the risk factor and the outcome (i.e. intervening variable)

Biases the results

Question 25

Effect modification

Answer 25

Where the risk factor or intervention acts differently in one group compared to another

E.g. UV exposure, increased risk of melanoma and skin type

Question 26

Loss to follow up

Answer 26

Losses before randomisation: affect the generalisability of our study

Losses after randomisation: relate to risk of bias

Question 27

Intention to treat analysis

Answer 27

Means that we analyse people in the groups that they were originally randomised to, regardless of what actually happens during the study

Pro: preserves the effect of randomisation
Con: dilutes power

Question 28

Composite endpoints

Answer 28

Rather than looking at several outcomes separately a study will combine several outcomes into the one composite measure that is used as the outcome

Why are they used?

• smaller sample size required to show effect
• allows assessment of ‘net’ effect of intervention

Why does it matter?

• Outcomes of high clinical importance can be grouped with those of minor importance
• Overestimate benefit of intervention

Question 29

What is a funnel plot?

Answer 29

Special graph produced to assess likelihood of publication bias; must have >10 studies
Point estimate of the effect (e.g. RR or OR) plotted against a measure of the study’s size or precision
True value down centre
- smaller studies = larger scatter
- larger studies = closer to the true value

Question 30

Sensitivity

Answer 30

Portion of those WITH the disease who have a positive test (i.e. true positive)

Sensitivity = TP / (TP + FN)

SnNout
When a highly sensitive test (Sn)
Is Negative (N)
the disease is ruled out (out)

If you want to avoid false negatives choose a test with high sensitivity (negative result in a sensitive test = confident patient doesn’t have disease)

Question 31

Specificity

Answer 31

The proportion of those without the disease who have a negative test (i.e. true negative)

Specificity = TN / (TN + FP)

SpPin
When a highly specificities test (Sp)
Is Positive (P)
The disease is ruled in (in)

If you want to avoid false positives choose a test with high specificity

Question 32

Positive predictive value

Answer 32

Probability of disease in those who test positive

= (TP) / (TP + FP)

Higher prevalence = higher PPV, lower NPV
Lower prevalence = lower PPV, higher NPV

Question 33

Negative predictive value

Answer 33

Probability of no disease in those who test negative

= TN / (TN + FN)

Higher prevalence = higher PPV, lower NPV
Lower prevalence = lower PPV, higher NPV

NPV / PPV depend upon the prevalence of the characteristic in a given population

Question 34

Positive likelihood ratio

Answer 34

= (probability of a +ve test in those with the disease) / ( probability of a +ve test in those without disease)

i.e. sensitivity / 1-specificity

Larger PLR = greater likelihood of disease
PLR > 10 will be useful in ruling in disease
PLR = 1 indicates a useless test

Question 35

Negative likelihood ratio

Answer 35

= (probability of -ve test in those with disease) / (probability of -be test in those without disease

i.e. (1-sensitivity) / specificity

Smaller NLR = lower likelihood of disease
NLR <0.1 will be useful in ruling out disease
NLR = 1 indicates a useless test

Question 36

Bias in screening

Answer 36

Lead time bias - apparent longer survival in screen detected cases as identified at earlier point in disease

Length time bias - slowly progressive disease more likely to be picked up by screening

Question 37

Level of evidence

Answer 37

Ia- evidence from meta-analysis of RCTs
Ib - evidence from at least one RCT
IIa - evidence from at least one well designed controlled trial that is not randomised
IIb - evidence from at least one well designed experimental trial
III - evidence from case, correlation and comparative studies
IV - evidence from a panel of experts

Grade A - based on evidence from at least 1 RCT
Grade B - based on evidence from non-RCT
Grade C - based on evidence from a panel of experts

Question 38

Post test probability

Answer 38

Pre test probability = prevalence
Post test probability = prevalence x LR

Post test probability after a +ve test = prevalence x PLR

Post test probability = (post-test odds)/(post test odds + 1)

Post test odds = (pre-test odds) x (likelihood ratio)

Question 39

Best estimate of prevalence?

Answer 39

Prevalence = incidence x duration

E.g. disease has annual incidence of 15 cases per 100,000. Mean survival after diagnosis is 5yrs.
Prevalence = (15 per 100,000) x 5 = 75 per 100,000

Question 40

Type 1 error

Answer 40

Rejecting the null hypothesis when it is in fact true OR
Accepting the alternative hypothesis when it is in fact false (i.e. a false positive result)

p value = probability of a type 1 error

Question 41

p value

Answer 41

Probability of a type 1 error OR
The probability of finding a difference when there is one
Significance is conventionally set at p < 0.5

Question 42

Type 2 Error

Answer 42

= power
Accepting the null hypothesis when it is false
Observing no difference when there is one
A false negative result
Rejecting an alternative hypothesis when it is true

Question 43

Power

Answer 43

= 1 - probability of Type 2 error
Likelihood of finding an effect when it is present
i.e. likelihood of avoiding false negatives

Question 44

Main modifiers of power

Answer 44

1. Size of effect
   - more difficult to detect small effects
2. Sample size
   - larger sample size = easier to detect effect
3. Desired significance
   - i.e. p<0.001 will conclude fewer positive than p<0.05
4. Standard deviation

Question 45

Multivariate analysis

Answer 45

Used to determine whether or not confounding is occurring due to other factors

Question 46

ROC curve

Answer 46

Y axis: true positive (sensitivity)
X axis: false positive (1-specificity)

Test with good performance swoops into the top L corner
Test close to a diagonal line is no better than chance at discriminating between those with and those without the disease

Question 47

Student’s T-test

Answer 47

Parametric (normally distributed)

Paired or unpaired

Question 48

Pearson’s product moment coefficient

Answer 48

Parametric

Correlation of 2 variables

Question 49

Mann-Whitney U Test

Answer 49

Non-parametric

Unpaired data

Question 50

Wilcoxon signed rank test

Answer 50

Non-parametric

Compares 2 sets of observations on a single sample

Question 51

Chi squared test

Answer 51

Non-parametric

Used to compare proportions or percentages

Question 52

Spearman, Kendall Rank

Answer 52

Non parametric

Correlation

Question 53

Paired vs unpaired data

Answer 53

Paired data: obtained from a single group of patients e.g. measurement before and after an intervention
Unpaired data: 2 different groups of patients e.e. Comparing response to different interventions in 2 groups

Question 54

Hazard Ratio

Answer 54

Similar to relative risk but used when risk is not constant in time.
Typically used when analysing survival over time
Reduction in risk of death or progression
HR of 0.84 = 16% reduction in risk