Deck 14: Designing Experiments

An experimental unit is an individual or group of individuals who have been assigned an experimental treatment independently of other individuals or groups.

A clinical trial is a study testing the effects of a new drug, operation, or other medical intervention.

To reduce bias, all study subjects should be arranged according to a parameter of interest, and then an alternating procedure (e.g., A, B, A, B, etc.) should be used to assign the participants to the groups.

The way that blocks are used in experiments is to assign individuals in a balanced manner to the blocks and then randomly assign each block to one of the treatments.

Control groups in clinical trials are always expected to show no change in the variable of interest over time.

A well-designed study will have only one control group.

Randomization should never be carried out by listing subjects and then choosing experimental units for each treatment by alternating back and forth along the sequence.

Assigning experimental units to each treatment alphabetically is bad practice.

Experiments with humans should be double-blind, but experiments with animals don't require blinding.

Reducing noise by making experimental conditions constant is always a good practice when designing experiments.

For a given total sample size, a balanced design will result in the highest statistical power.

Randomized block design uses three or more treatments.

When factors interact, that is because we see effects when factors are combined that are not predictable from when each factor is tested in isolation.

We use matching in observational studies to reduce, but not eliminate, bias and sampling error.

With matching, every individual in the treatment group is paired with a control individual having the same or closely similar value of the parameter of interest.

Estimating the required sample size for an experiment is often done to safeguard against undue harm to the study population.

Estimating the required sample size for an experiment is often done for practical economic reasons.

Doubling the sample size will tend to double the power of a statistical analysis.

If we do four statistical tests in situations where the null hypothesis is true and use an a = 0.05 threshold, there is an 18.5% chance we have made at least one Type I error.

If we do four statistical tests in situations where the null hypothesis is true and use an a = 0.05 threshold, there is a 21.5% chance we have made at least one Type I error.

Using the Bonferroni correction reduces our overall risk of Type I error but increases the risk of Type II error for factors that have minor and moderate effects.

Explain what blinding and double-blinding are and why they are important for clinical trials. Are they also needed for animal studies?

Compare and contrast "balancing" and "blocking" with respect to experimental design. What do they both do, and in which ways do they differ?

Using an example from everyday life, describe two factors that interact to have an effect on some kind of measurable quantity.

Compare and contrast "matching" and "adjusting" with respect to experimental design and data analysis. What do they both do, and in which ways do they differ?

When determining the required sample size for an experiment, there are two major concepts that were discussed. Describe each of these and distinguish between them. Also, describe several factors that limit sample size and explain why.

Recall that doing many statistical tests increases the overall chance of a Type I error. If we used an a = 0.05 threshold for each test and the null hypothesis is actually true for all the tests, how many tests would we need to do before our risk of making at least one Type I error reaches 50%? Show all the steps in your calculation and remember that logarithms can be useful for solving equations with exponents.

Recall that doing many statistical tests increases the overall chance of a Type I error. Consider a situation in which we test 1,200 genes for their influence on a measured factor. If we use an a = 0.05 threshold for each test and obtain 83 significant results, how would we interpret this, and what would the next step be? Be sure to make a quantitative statement about these results in reference to the technical phrase "false discovery rate" in your answer.

Consider a study in which we wish to see whether the lengths of fish are related to the size of the lake in which they live. Unfortunately, the amount of dissolved nitrogen in the water from farm runoff is also thought to influence fish size. Imagine we are provided with the data shown in the table and wish to perform a matched design study where we compare the sizes of the fish in the largest four lakes to those in the smallest four lakes.
​
​
(a) Which fish should be in each of the two observation groups, and how should they be matched?
(b) After matching, what is the mean and standard error of the differences in the sizes of the fish?
(c) Based on your values in part (b), does there seem to be a difference in the mean size of the fish in the small and large lakes?

Consider a study in which we wish to see whether the lengths of fish are related to the size of the lake in which they live. Unfortunately, the amount of dissolved nitrogen in the water from farm runoff is also thought to influence fish size. Imagine we are provided with the data shown in the table and wish to perform a matched design study where we compare the sizes of the fish in the largest four lakes to those in the smallest four lakes.
​
​
(a) Which fish should be in each of the two observation groups and how should they be matched?
(b) After matching, what is the mean and standard error of the differences in the sizes of the fish?
(c) Based on your values in part (b), does there seem to be a difference in the mean size of the fish in the small and large lakes?