https://github.com/cran/epiR
Tip revision: efb6c9cc3524fb02f40ce41007345604dee61689 authored by Mark Stevenson on 18 August 2008, 15:21:03 UTC
version 0.9-9
version 0.9-9
Tip revision: efb6c9c
epi.mh.R
"epi.mh" <- function(ev.trt, n.trt, ev.ctrl, n.ctrl, names, method = "odds.ratio", conf.level = 0.95)
{
# Declarations:
k <- length(names)
a.i <- ev.trt
b.i <- n.trt - ev.trt
c.i <- ev.ctrl
d.i <- n.ctrl - ev.ctrl
n.1i <- n.trt
n.2i <- n.ctrl
N.i <- n.trt + n.ctrl
N <- 1 - ((1 - conf.level) / 2)
z <- qnorm(N, mean = 0, sd = 1)
R <- sum((a.i * d.i) / N.i)
S <- sum((b.i * c.i) / N.i)
E <- sum(((a.i + d.i) * a.i * d.i) / N.i^2)
F. <- sum(((a.i + d.i) * b.i * c.i) / N.i^2)
G <- sum(((b.i + c.i) * a.i * d.i) / N.i^2)
H <- sum(((b.i + c.i) * b.i * c.i) / N.i^2)
P <- sum(((n.1i * n.2i * (a.i + c.i)) - (a.i * c.i * N.i)) / N.i^2)
R <- sum((a.i * n.2i) / N.i)
S <- sum((c.i * n.1i) / N.i)
if(method == "odds.ratio")
{# Individual study odds ratios:
OR.i <- (a.i * d.i) / (b.i * c.i)
lnOR.i <- log(OR.i)
SE.lnOR.i <- sqrt(1/a.i + 1/b.i + 1/c.i + 1/d.i)
SE.OR.i <- exp(SE.lnOR.i)
lower.lnOR.i <- lnOR.i - (z * SE.lnOR.i)
upper.lnOR.i <- lnOR.i + (z * SE.lnOR.i)
lower.OR.i <- exp(lower.lnOR.i)
upper.OR.i <- exp(upper.lnOR.i)
# Weights:
w.i <- (b.i * c.i) / N.i
# w.i <- 1 / (1/a.i + 1/b.i + 1/c.i + 1/d.i)
w.iv.i <- 1 / (SE.lnOR.i)^2
# MH pooled odds ratios (relative effect measures combined in their natural scale):
# Need to use exact method - see Armitage and Berry for details.
OR.mh <- sum(w.i * OR.i) / sum(w.i)
lnOR.mh <- sum(w.i * log(OR.i)) / sum(w.i)
# OR.mh <- exp(lnOR.mh)
SE.lnOR.mh <- 1 / sqrt(sum(w.i))
SE.OR.mh <- exp(SE.lnOR.mh)
lower.lnOR.mh <- lnOR.mh - (z * SE.lnOR.mh)
upper.lnOR.mh <- lnOR.mh + (z * SE.lnOR.mh)
lower.OR.mh <- exp(lower.lnOR.mh)
upper.OR.mh <- exp(upper.lnOR.mh)
# Test of heterogeneity (based on inverse variance weights):
Q <- sum(w.iv.i * (lnOR.i - lnOR.mh)^2)
df <- k - 1
p.heterogeneity <- 1 - pchisq(Q, df)
# Higgins and Thompson (2002) H^2 and I^2 statistic:
Hsq <- Q / (k - 1)
lnHsq <- log(Hsq)
if(Q > k) {
lnHsq.se <- (1 * log(Q) - log(k - 1)) / (2 * sqrt(2 * Q) - sqrt((2 * (k - 3))))
}
if(Q <= k) {
lnHsq.se <- sqrt((1/(2 * (k - 2))) * (1 - (1 / (3 * (k - 2)^2))))
}
lnHsq.l <- lnHsq - (z * lnHsq.se)
lnHsq.u <- lnHsq + (z * lnHsq.se)
Hsq.l <- exp(lnHsq.l)
Hsq.u <- exp(lnHsq.u)
Isq <- ((Hsq - 1) / Hsq) * 100
Isq.l <- ((Hsq.l - 1) / Hsq.l) * 100
Isq.u <- ((Hsq.u - 1) / Hsq.u) * 100
# Test of effect:
effect.z <- abs(lnOR.mh / SE.lnOR.mh)
p.effect <- 1 - pnorm(effect.z, mean = 0, sd = 1)
# Results:
result.01 <- cbind(OR.i, SE.OR.i, lower.OR.i, upper.OR.i)
result.02 <- cbind(OR.mh, SE.OR.mh, lower.OR.mh, upper.OR.mh)
result.03 <- as.data.frame(rbind(result.01, result.02))
names(result.03) <- c("est", "se", "lower", "upper")
result.04 <- as.data.frame(cbind(c(names, "Pooled OR (MH)")))
names(result.04) <- c("names")
result.05 <- as.data.frame(cbind(result.04, result.03))
result.06 <- as.data.frame(cbind(w.i, w.iv.i))
names(result.06) <- c("raw", "inv.var")
result.07 <- as.data.frame(cbind(Hsq, Hsq.l, Hsq.u))
names(result.07) <- c("est", "lower", "upper")
result.08 <- as.data.frame(cbind(Isq, Isq.l, Isq.u))
names(result.08) <- c("est", "lower", "upper")
rval <- list(odds.ratio = result.05, weights = result.06,
heterogeneity = c(Q = Q, df = df, p.value = p.heterogeneity),
Hsq = result.07,
Isq = result.08,
effect = c(z = effect.z, p.value = p.effect))
}
else
if(method == "risk.ratio")
{# Individual study risk ratios:
RR.i <- (a.i / n.1i) / (c.i / n.2i)
lnRR.i <- log(RR.i)
SE.lnRR.i <- sqrt(1/a.i + 1/c.i - 1/n.1i - 1/n.2i)
SE.RR.i <- exp(SE.lnRR.i)
lower.lnRR.i <- lnRR.i - (z * SE.lnRR.i)
upper.lnRR.i <- lnRR.i + (z * SE.lnRR.i)
lower.RR.i <- exp(lower.lnRR.i)
upper.RR.i <- exp(upper.lnRR.i)
# Weights:
w.i <- (c.i * n.1i) / N.i
w.iv.i <- 1 / (SE.lnRR.i)^2
# MH pooled odds ratios (relative effect measures combined in their natural scale):
RR.mh <- sum(w.i * RR.i) / sum(w.i)
lnRR.mh <- log(RR.mh)
SE.lnRR.mh <- sqrt(P / (R * S))
SE.RR.mh <- exp(SE.lnRR.mh)
lower.lnRR.mh <- log(RR.mh) - (z * SE.lnRR.mh)
upper.lnRR.mh <- log(RR.mh) + (z * SE.lnRR.mh)
lower.RR.mh <- exp(lower.lnRR.mh)
upper.RR.mh <- exp(upper.lnRR.mh)
# Test of heterogeneity (based on inverse variance weights):
Q <- sum(w.iv.i * (lnRR.i - lnRR.mh)^2)
df <- k - 1
p.heterogeneity <- 1 - pchisq(Q, df)
# Higgins and Thompson (2002) H^2 and I^2 statistic:
Hsq <- Q / (k - 1)
lnHsq <- log(Hsq)
if(Q > k) {
lnHsq.se <- (1 * log(Q) - log(k - 1)) / (2 * sqrt(2 * Q) - sqrt((2 * (k - 3))))
}
if(Q <= k) {
lnHsq.se <- sqrt((1/(2 * (k - 2))) * (1 - (1 / (3 * (k - 2)^2))))
}
lnHsq.l <- lnHsq - (z * lnHsq.se)
lnHsq.u <- lnHsq + (z * lnHsq.se)
Hsq.l <- exp(lnHsq.l)
Hsq.u <- exp(lnHsq.u)
Isq <- ((Hsq - 1) / Hsq) * 100
Isq.l <- ((Hsq.l - 1) / Hsq.l) * 100
Isq.u <- ((Hsq.u - 1) / Hsq.u) * 100
# Test of effect:
effect.z <- abs(log(RR.mh) / SE.lnRR.mh)
p.effect <- 1 - pnorm(effect.z, mean=0, sd=1)
# Results:
result.01 <- cbind(RR.i, SE.RR.i, lower.RR.i, upper.RR.i)
result.02 <- cbind(RR.mh, SE.RR.mh, lower.RR.mh, upper.RR.mh)
result.03 <- as.data.frame(rbind(result.01, result.02))
names(result.03) <- c("est", "se", "lower", "upper")
result.04 <- as.data.frame(cbind(c(names, "Pooled RR (MH)")))
names(result.04) <- c("names")
result.05 <- as.data.frame(cbind(result.04, result.03))
result.06 <- as.data.frame(cbind(w.i, w.iv.i))
names(result.06) <- c("raw", "inv.var")
result.07 <- as.data.frame(cbind(Hsq, Hsq.l, Hsq.u))
names(result.07) <- c("est", "lower", "upper")
result.08 <- as.data.frame(cbind(Isq, Isq.l, Isq.u))
names(result.08) <- c("est", "lower", "upper")
rval <- list(risk.ratio = result.05, weights = result.06,
heterogeneity = c(Q = Q, df = df, p.value = p.heterogeneity),
Hsq = result.07,
Isq = result.08,
effect = c(z = effect.z, p.value = p.effect))
}
return(rval)
}