tscc: Power calculation for two-stage case-control design

Description

This function gives power estimates for two-stage case-control design for genetic association.

The false positive rates are calculated as follows,

$$P(|z1|>C1)P(|z2|>C2,sign(z1)=sign(z2))$$ and $$P(|z1|>C1)P(|zj|>Cj||z1|>C1)$$ for replication-based and joint analyses, respectively; where C1, C2, and Cj are threshoulds at stages 1, 2 replication and joint analysis,

$$ z1 = z(p1,p2,n1,n2,pi.samples)$$ $$z2 = z(p1,p2,n1,n2,1-pi.samples)$$ $$zj = sqrt(pi.samples)*z1+sqrt(1-pi.samples)*z2$$

Usage

tscc(model,GRR,p1,n1,n2,M,alpha.genome,pi.samples,pi.markers,K)

Arguments

model

any in c("multiplicative","additive","dominant","recessive")

GRR

genotype relative risk

the estimated risk allele frequency in cases

total number of cases

total number of controls

total number of markers

alpha.genome

false positive rate at genome level

pi.samples

sample% to be genotyped at stage 1

pi.markers

markers% to be selected (also used as the false positive rate at stage 1)

the population prevalence

Value

The returned value is a list containing a copy of the input plus output as follows,

model

any in c("multiplicative","additive","dominant","recessive")

GRR

genotype relative risk

the estimated risk allele frequency in cases

pprime

expected risk allele frequency in cases

expected risk allele frequency in controls

total number of cases

total number of controls

total number of markers

alpha.genome

false positive rate at genome level

pi.samples

sample% to be genotyped at stage 1

pi.markers

markers% to be selected (also used as the false positive rate at stage 1)

the population prevalence

threshoulds for no stage, stage 1, stage 2, joint analysis

power

power corresponding to C

References

Skol AD, Scott LJ, Abecasis GR, Boehkne M (2006). Joint analysis in more efficient than replication-based aalysis for two-stage genome-wide association studies. Nature Genetics 38:209-213

Examples

Run this code

# NOT RUN {
K <- 0.1
p1 <- 0.4
n1 <- 1000
n2 <- 1000 
M <- 300000
alpha.genome <- 0.05
GRR <- 1.4
p1 <- 0.4
pi.samples <- 0.2
pi.markers <- 0.1

options(echo=FALSE)
cat("sample%,marker%,GRR,(thresholds x 4)(power estimates x 4)\n")
for(GRR in c(1.3,1.35,1.40)) {
   cat("\n")
   for(pi.samples in c(1.0,0.5,0.4,0.3,0.2)) {
      if(pi.samples==1.0) s <- 1.0
      else s <- c(0.1,0.05,0.01)
      for(pi.markers in s)
      {
        x <- tscc("multiplicative",GRR,p1,n1,n2,M,alpha.genome,
                  pi.samples,pi.markers,K)
        l <- c(pi.samples,pi.markers,GRR,x$C,x$power)
        l <- sprintf("%.2f %.2f %.2f, %.2f %.2f %.2f %.2f, %.2f %.2f %.2f %.2f",
                     l[1],l[2],l[3],l[4],l[5],l[6],l[7],l[8],l[9],l[10],l[11])
        cat(l,"\n")
      }
      cat("\n")
   }
}
options(echo=TRUE)
# }

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