Skip to content
This repository has been archived by the owner on Jun 14, 2023. It is now read-only.
/ gsdmvn Public archive

The goal of gsdmvn is to enable group sequential trial design for time-to-event endpoints under non-proportional hazards assumptions.

License

Notifications You must be signed in to change notification settings

Merck/gsdmvn

Repository files navigation

gsdmvn

Status Lifecycle: superseded

gsdmvn is superseded: the functionality was included directly in the gsDesign2 package. We recommend using gsDesign2 instead.

Introduction

The goal of gsdmvn is to enable fixed or group sequential design under non-proportional hazards. Piecewise constant enrollment, failure rates and dropout rates for a stratified population are available to enable highly flexible enrollment, time-to-event and time-to-dropout assumptions. Substantial flexibility on top of what is in the gsDesign package is intended for selecting boundaries. While this work is in progress, substantial capabilities have been enabled. Comments on usability and features are encouraged as this is a development version of the package.

The goal of gsdmvn is to enable group sequential trial design for time-to-event endpoints under non-proportional hazards assumptions. The package is still maturing; as the package functions become more stable, they will likely be included in the gsDesign2 package.

Branch specification

  • The development branch includes all work under development.
  • The table_bound branch is branched from the development branch, and it targets to get the outputs of gd_design_ahr(), gs_power_ahr(),gs_desgin_wlr(), etc., into a well-organized form.
  • The update_futility_bound branch is branched from the development branch, and it targets to develop code so one can update the futility bound.

Installation

You can install gsdmvn with:

remotes::install_github("Merck/gsdmvn")

Specifying enrollment and failure rates

This is a basic example which shows you how to solve a common problem. We assume there is a 4 month delay in treatment effect. Specifically, we assume a hazard ratio of 1 for 4 months and 0.6 thereafter. For this example we assume an exponential failure rate and low exponential dropout rate. The enrollRates specification indicates an expected enrollment duration of 12 months with exponential inter-arrival times.

library(gsdmvn)
library(gsDesign)
library(gsDesign2)
library(dplyr)
library(knitr)

## basic example code

## Constant enrollment over 12 months
## rate will be adjusted later by gsDesignNPH to get sample size
enrollRates <- tibble::tibble(Stratum = "All", duration = 12, rate = 1)

## 12 month median exponential failure rate in control
## 4 month delay in effect with HR=0.6 after
## Low exponential dropout rate
medianSurv <- 12
failRates <- tibble::tibble(
  Stratum = "All",
  duration = c(4, Inf),
  failRate = log(2) / medianSurv,
  hr = c(1, .6),
  dropoutRate = .001
)

The resulting failure rate specification is the following table. As many rows and strata as needed can be specified to approximate whatever patterns you wish.

failRates %>% kable()
Stratum duration failRate hr dropoutRate
All 4 0.0577623 1.0 0.001
All Inf 0.0577623 0.6 0.001

Computing a fixed sample size design with 2.5% one-sided Type I error and 90% power. We specify a trial duration of 36 months with analysisTimes. Since there is a single analysis, we specify an upper p-value bound of 0.025 with upar = qnorm(0.975). There is no lower bound which is specified with lpar = -Inf.

design <-
  gs_design_ahr(enrollRates, failRates, upar = qnorm(.975), lpar = -Inf, IF = 1, analysisTimes = 36)

The input enrollment rates are scaled to achieve power:

design$enrollRates %>% kable()
Stratum duration rate
All 12 35.05288

The failure and dropout rates remain unchanged from what was input:

design$failRates %>% kable()
Stratum duration failRate hr dropoutRate
All 4 0.0577623 1.0 0.001
All Inf 0.0577623 0.6 0.001

Finally, the expected analysis time is in Time, sample size N, events required Events and bound Z are in design$bounds. Note that AHR is the average hazard ratio used to calculate the targeted event counts. The natural parameter (log(AHR)) is in theta and corresponding statistical information under the alternate hypothesis are in info and under the null hypothesis in info0.

design$bounds %>% kable()
Analysis Bound Time N Events Z Probability AHR theta info info0
1 Upper 36 420.6346 311.0028 1.959964 0.9 0.6917244 0.3685676 76.74383 77.75069

About

The goal of gsdmvn is to enable group sequential trial design for time-to-event endpoints under non-proportional hazards assumptions.

Resources

License

Stars

Watchers

Forks

Packages

No packages published