![[magnesium0]](magnesium0.bmp)
Sensitivity to prior distributions:application to Magnesium
meta-analysis
model
{
# j indexes alternative prior distributions
for (j in 1:6) {
mu[j] ~ dunif(-10, 10)
OR[j] <- exp(mu[j])
# k indexes study number
for (k in 1:8) {
theta[j, k] ~ dnorm(mu[j], inv.tau.sqrd[j])
rtx[j, k] ~ dbin(pt[j, k], nt[k])
rtx[j, k] <- rt[k]
rcx[j, k] ~ dbin(pc[j, k], nc[k])
rcx[j, k] <- rc[k]
logit(pt[j, k]) <- theta[j, k] + phi[j, k]
phi[j, k] <- logit(pc[j, k])
pc[j, k] ~ dunif(0, 1)
}
}
# k again indexes study number
for (k in 1:8) {
# log-odds ratios:
y[k] <- log(((rt[k] + 0.5) / (nt[k] - rt[k] + 0.5)) / ((rc[k] + 0.5) / (nc[k] - rc[k] + 0.5)))
# variances & precisions:
sigma.sqrd[k] <- 1 / (rt[k] + 0.5) + 1 / (nt[k] - rt[k] + 0.5) + 1 / (rc[k] + 0.5) +
1 / (nc[k] - rc[k] + 0.5)
prec.sqrd[k] <- 1 / sigma.sqrd[k]
}
s0.sqrd <- 1 / mean(prec.sqrd[1:8])
# Prior 1: Gamma(0.001, 0.001) on inv.tau.sqrd
inv.tau.sqrd[1] ~ dgamma(0.001, 0.001)
tau.sqrd[1] <- 1 / inv.tau.sqrd[1]
tau[1] <- sqrt(tau.sqrd[1])
# Prior 2: Uniform(0, 50) on tau.sqrd
tau.sqrd[2] ~ dunif(0, 50)
tau[2] <- sqrt(tau.sqrd[2])
inv.tau.sqrd[2] <- 1 / tau.sqrd[2]
# Prior 3: Uniform(0, 50) on tau
tau[3] ~ dunif(0, 50)
tau.sqrd[3] <- tau[3] * tau[3]
inv.tau.sqrd[3] <- 1 / tau.sqrd[3]
# Prior 4: Uniform shrinkage on tau.sqrd
B0 ~ dunif(0, 1)
tau.sqrd[4] <- s0.sqrd * (1 - B0) / B0
tau[4] <- sqrt(tau.sqrd[4])
inv.tau.sqrd[4] <- 1 / tau.sqrd[4]
# Prior 5: Dumouchel on tau
D0 ~ dunif(0, 1)
tau[5] <- sqrt(s0.sqrd) * (1 - D0) / D0
tau.sqrd[5] <- tau[5] * tau[5]
inv.tau.sqrd[5] <- 1 / tau.sqrd[5]
# Prior 6: Half-Normal on tau.sqrd
p0 <- phi(0.75) / s0.sqrd
tau.sqrd[6] ~ dnorm(0, p0)C(0, )
tau[6] <- sqrt(tau.sqrd[6])
inv.tau.sqrd[6] <- 1 / tau.sqrd[6]
}
Data ( click to open )
Inits for chain 1 Inits for chain 2 ( click to open )
Results for 6 different prior distributions on the random-effects variance:
![[magnesium1]](magnesium1.bmp)
![[magnesium2]](magnesium2.bmp)
![[magnesium3]](magnesium3.bmp)