getSimulationEnrichmentSurvival: Get Simulation Enrichment Survival
In rpact: Confirmatory Adaptive Clinical Trial Design and Analysis

View source: R/f_simulation_enrichment_survival.R

getSimulationEnrichmentSurvival

R Documentation

Get Simulation Enrichment Survival

Description

Returns the simulated power, stopping and selection probabilities, conditional power, and expected sample size for testing hazard ratios in an enrichment design testing situation. In contrast to getSimulationSurvival() (where survival times are simulated), normally distributed logrank test statistics are simulated.

Usage

getSimulationEnrichmentSurvival(
  design = NULL,
  ...,
  effectList = NULL,
  intersectionTest = c("Simes", "SpiessensDebois", "Bonferroni", "Sidak"),
  stratifiedAnalysis = TRUE,
  directionUpper = TRUE,
  adaptations = NA,
  typeOfSelection = c("best", "rBest", "epsilon", "all", "userDefined"),
  effectMeasure = c("effectEstimate", "testStatistic"),
  successCriterion = c("all", "atLeastOne"),
  epsilonValue = NA_real_,
  rValue = NA_real_,
  threshold = -Inf,
  plannedEvents = NA_real_,
  allocationRatioPlanned = NA_real_,
  minNumberOfEventsPerStage = NA_real_,
  maxNumberOfEventsPerStage = NA_real_,
  conditionalPower = NA_real_,
  thetaH1 = NA_real_,
  maxNumberOfIterations = 1000L,
  seed = NA_real_,
  calcEventsFunction = NULL,
  selectPopulationsFunction = NULL,
  showStatistics = FALSE
)

Arguments

`design`	The trial design. If no trial design is specified, a fixed sample size design is used. In this case, Type I error rate `alpha`, Type II error rate `beta`, `twoSidedPower`, and `sided` can be directly entered as argument where necessary.
`...`	Ensures that all arguments (starting from the "...") are to be named and that a warning will be displayed if unknown arguments are passed.
`effectList`	List of subsets, prevalences, and effect sizes with columns and number of rows reflecting the different situations to consider (see examples).
`intersectionTest`	Defines the multiple test for the intersection hypotheses in the closed system of hypotheses. Four options are available in enrichment designs: `"SpiessensDebois"`, `"Bonferroni"`, `"Simes"`, and `"Sidak"`, default is `"Simes"`.
`stratifiedAnalysis`	Logical. For enrichment designs, typically a stratified analysis should be chosen. For testing rates, also a non-stratified analysis based on overall data can be performed. For survival data, only a stratified analysis is possible (see Brannath et al., 2009), default is `TRUE`.
`directionUpper`	Logical. Specifies the direction of the alternative, only applicable for one-sided testing; default is `TRUE` which means that larger values of the test statistics yield smaller p-values.
`adaptations`	A logical vector of length `kMax - 1` indicating whether or not an adaptation takes place at interim k, default is `rep(TRUE, kMax - 1)`.
`typeOfSelection`	The way the treatment arms or populations are selected at interim. Five options are available: `"best"`, `"rbest"`, `"epsilon"`, `"all"`, and `"userDefined"`, default is `"best"`. For `"rbest"` (select the `rValue` best treatment arms/populations), the parameter `rValue` has to be specified, for `"epsilon"` (select treatment arm/population not worse than epsilon compared to the best), the parameter `epsilonValue` has to be specified. If `"userDefined"` is selected, `"selectArmsFunction"` or `"selectPopulationsFunction"` has to be specified.
`effectMeasure`	Criterion for treatment arm/population selection, either based on test statistic (`"testStatistic"`) or effect estimate (difference for means and rates or ratio for survival) (`"effectEstimate"`), default is `"effectEstimate"`.
`successCriterion`	Defines when the study is stopped for efficacy at interim. Two options are available: `"all"` stops the trial if the efficacy criterion is fulfilled for all selected treatment arms/populations, `"atLeastOne"` stops if at least one of the selected treatment arms/populations is shown to be superior to control at interim, default is `"all"`.
`epsilonValue`	For `typeOfSelection = "epsilon"` (select treatment arm / population not worse than epsilon compared to the best), the parameter `epsilonValue` has to be specified. Must be a numeric of length 1.
`rValue`	For `typeOfSelection = "rbest"` (select the `rValue` best treatment arms / populations), the parameter `rValue` has to be specified.
`threshold`	Selection criterion: treatment arm / population is selected only if `effectMeasure` exceeds `threshold`, default is `-Inf`. `threshold` can also be a vector of length `activeArms` referring to a separate threshold condition over the treatment arms.
`plannedEvents`	`plannedEvents` is a numeric vector of length `kMax` (the number of stages of the design) that determines the number of cumulated (overall) events in survival designs when the interim stages are planned. For two treatment arms, it is the number of events for both treatment arms. For multi-arm designs, `plannedEvents` refers to the overall number of events for the selected arms plus control.
`allocationRatioPlanned`	The planned allocation ratio `n1 / n2` for a two treatment groups design, default is `1`. For multi-arm designs, it is the allocation ratio relating the active arm(s) to the control. For simulating means and rates for a two treatment groups design, it can be a vector of length kMax, the number of stages. It can be a vector of length kMax, too, for multi-arm and enrichment designs. In these cases, a change of allocating subjects to treatment groups over the stages can be assessed.
`minNumberOfEventsPerStage`	When performing a data driven sample size recalculation, the numeric vector `minNumberOfEventsPerStage` with length kMax determines the minimum number of events per stage (i.e., not cumulated), the first element is not taken into account.
`maxNumberOfEventsPerStage`	When performing a data driven sample size recalculation, the numeric vector `maxNumberOfEventsPerStage` with length kMax determines the maximum number of events per stage (i.e., not cumulated), the first element is not taken into account.
`conditionalPower`	If `conditionalPower` together with `minNumberOfSubjectsPerStage` and `maxNumberOfSubjectsPerStage` (or `minNumberOfEventsPerStage` and `maxNumberOfEventsPerStage` for survival designs) is specified, a sample size recalculation based on the specified conditional power is performed. It is defined as the power for the subsequent stage given the current data. By default, the conditional power will be calculated under the observed effect size. Optionally, you can also specify `thetaH1` and `stDevH1` (for simulating means), `pi1H1` and `pi2H1` (for simulating rates), or `thetaH1` (for simulating hazard ratios) as parameters under which it is calculated and the sample size recalculation is performed.
`thetaH1`	If specified, the value of the alternative under which the conditional power or sample size recalculation calculation is performed. Must be a numeric of length 1.
`maxNumberOfIterations`	The number of simulation iterations, default is `1000`. Must be a positive integer of length 1.
`seed`	The seed to reproduce the simulation, default is a random seed.
`calcEventsFunction`	Optionally, a function can be entered that defines the way of performing the sample size recalculation. By default, event number recalculation is performed with conditional power and specified `minNumberOfEventsPerStage` and `maxNumberOfEventsPerStage` (see details and examples).
`selectPopulationsFunction`	Optionally, a function can be entered that defines the way of how populations are selected. This function is allowed to depend on `effectVector` with length `populations` and `stage` (see examples).
`showStatistics`	Logical. If `TRUE`, summary statistics of the simulated data are displayed for the `print` command, otherwise the output is suppressed, default is `FALSE`.

Details

At given design the function simulates the power, stopping probabilities, selection probabilities, and expected event number at given number of events, parameter configuration, and population selection rule in the enrichment situation. An allocation ratio can be specified referring to the ratio of number of subjects in the active treatment group as compared to the control group.

The definition of thetaH1 makes only sense if kMax > 1 and if conditionalPower, minNumberOfEventsPerStage, and maxNumberOfEventsPerStage (or calcEventsFunction) are defined.

calcEventsFunction
This function returns the number of events at given conditional power and conditional critical value for specified testing situation. The function might depend on the variables stage, selectedPopulations, plannedEvents, directionUpper, allocationRatioPlanned, minNumberOfEventsPerStage, maxNumberOfEventsPerStage, conditionalPower, conditionalCriticalValue, and overallEffects. The function has to contain the three-dots argument '...' (see examples).

Value

Returns a SimulationResults object. The following generics (R generic functions) are available for this object:

names() to obtain the field names,
print() to print the object,
summary() to display a summary of the object,
plot() to plot the object,
as.data.frame() to coerce the object to a data.frame,
as.matrix() to coerce the object to a matrix.

How to get help for generic functions

Click on the link of a generic in the list above to go directly to the help documentation of the rpact specific implementation of the generic. Note that you can use the R function methods to get all the methods of a generic and to identify the object specific name of it, e.g., use methods("plot") to get all the methods for the plot generic. There you can find, e.g., plot.AnalysisResults and obtain the specific help documentation linked above by typing ?plot.AnalysisResults.

Examples

## Not run: 
# Assess a population selection strategy with one subset population and
# a survival endpoint. The considered situations are defined through the 
# event rates yielding a range of hazard ratios in the subsets. Design 
# with O'Brien and Fleming alpha spending and a reassessment of event 
# number in the first interim based on conditional power and assumed 
# hazard ratio using weighted inverse normal combination test.  
    
subGroups <- c("S", "R")
prevalences <- c(0.40, 0.60)
 
p2 <- c(0.3, 0.4)
range1 <- p2[1] + seq(0, 0.3, 0.05)

p1 <- c()
for (x1 in range1) {
    p1 <- c(p1, x1, p2[2] + 0.1)
}		
hazardRatios <- log(matrix(1 - p1, byrow = TRUE, ncol = 2)) /
    matrix(log(1 - p2), byrow = TRUE, ncol = 2,
    nrow = length(range1))

effectList <- list(subGroups=subGroups, prevalences=prevalences,
    hazardRatios = hazardRatios)

design <- getDesignInverseNormal(informationRates = c(0.3, 0.7, 1),
    typeOfDesign = "asOF")

simResultsPE <- getSimulationEnrichmentSurvival(design, 
    plannedEvents = c(40, 90, 120),
    effectList = effectList,
    typeOfSelection = "rbest", rValue = 2,
    conditionalPower = 0.8, minNumberOfEventsPerStage = c(NA, 50, 30),
    maxNumberOfEventsPerStage = c(NA, 150, 30), thetaH1 = 4 / 3,
    maxNumberOfIterations = 100)
print(simResultsPE)

## End(Not run)

rpact documentation built on July 9, 2023, 6:30 p.m.