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Cancer Stem Cells: Some statistical issues What you would like to do: Identify ways to design...
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Transcript of Cancer Stem Cells: Some statistical issues What you would like to do: Identify ways to design...
Cancer Stem Cells:Some statistical issues What you would like to do:
Identify ways to design studies with increased statistical “power” in clinical trials of targeted therapies
Develop statistically meaningful biologic response criteria
First things first: Current in vivo assays/measures have
limitations How well is the biology understood?
Measuring Response Relapse-free survival, Overall survival
Pros: these are the “gold-standards” Problems: takes too long, too costly
Biomarkers (“correlative” outcomes) Pros: feasible in the short-term Cons:
can be costly might have many to measure might not know all the relevant markers might not know how they all “fit together”
If Biomarkers are used as “surrogates” for response, then they need to be TRUE surrogates.
“Correlative” outcome is not good enough
“True” Surrogate Marker Defining Characteristic:
a marker must predict clinical outcome, in addition to predicting the effect of treatment on clinical outcome
Operational Definition establish an association between marker & clinical
outcome establish an association between marker, treatment &
clinical outcome, in which marker mediates relationship between clinical outcome and treatment
Surrogate Markers
marker
Clinical outcome
treatmentClinical outcome
1) establish an association between marker & clinical outcome.
2) establish an association between marker, treatment & clinical outcome, in which marker completely mediates relationship between clinical outcome and treatment.
marker
NOT Surrogate Markers
marker
treatmentClinical outcome
treatment marker
Clinical outcome
Alternative Approach:Bayesian Networks Bayesian networks are complex diagrams that organize data
They map out cause-and-effect relationships among key variables They encode them with numbers that represent the extent to
which one variable is likely to affect another. Use “network inference algorithms” to predict causal
models of molecular networks from correlational data. These systems can automatically generate optimal
predictions or decisions even when key pieces of information are missing.
How to do this? HYPOTHESIZE BIOLOGICAL MODEL Collect data on hypothesized markers in the
pathway/biologic model. Collect data serially, over a time course that fits with
biologic model.
Example of Bayesian Network
Yu, J., Smith, V., Wang, P., Hartemink, A., & Jarvis, E. (2002) “Using Bayesian Network Inference Algorithms to Recover Molecular Genetic Regulatory Networks.” International Conference on Systems Biology 2002 (ICSB02), December 2002.
Ongoing Optimization of Assays Ideally, assays are “perfect” before clinical trial opens In reality, many of our assays are still pretty rough Can incorporate assay “sub-studies” within clinical trial RELIABILITY
How reproducible are the results? Two samples taken from the same patient on the
same day One sample analyzed twice using the same method?
Subjectivity? Inter-rater and Intra-rater agreement In what ways can ‘error’ come into the procedure? Provides understanding of measurement error in
practice Benefit: Quantification of the ‘believability’ of the
results Drawback: what will reviewers think?