# Getting unadjusted values from model fit in R

I want to have a table with adjusted and unadjusted (crude) values. It seems like a common problem but I can't figure out how to do it without re-running the regression for each variable.

Here's how I get the adjusted values:

``````library("survival")
library("timereg")
data(sTRACE)

# Basic cox regression
surv <- with(sTRACE, Surv(time/365,status==9))
fit1 <- coxph(surv~age+sex+diabetes+chf+vf, data=sTRACE)
x <- cbind(exp(coef(fit1)), exp(confint(fit1)))
test <- apply(x, 1, FUN=function(x){
x <- round(x, 1)
txt <- paste(x[1], " (95% CI ", min(x[2:3]), "-", max(x[2:3]), ")", sep="")
return(txt)
})
test
``````

The test variable is now a vector:

``````> test
age                    sex               diabetes
"1.1 (95% CI 1.1-1.1)" "1.4 (95% CI 1.1-1.9)"   "1.5 (95% CI 1-2.2)"
chf                     vf
"2.1 (95% CI 1.6-2.8)" "2.3 (95% CI 1.4-3.8)"
``````

I woul like to add this to a 2-dimensional matrix where one column is the unadjusted value something like this:

``````                       Adjusted             Unadjusted
age "1.1 (95% CI 1.1-1.1)" "1.1 (95% CI 1.1-1.1)"
``````

Where the unadjusted value is created like this:

``````fit2 <- coxph(surv~age, data=sTRACE)
x <- cbind(exp(coef(fit2)), exp(confint(fit2)))
test <- apply(x, 1, FUN=function(x){
x <- round(x, 1)
txt <- paste(x[1], " (95% CI ", min(x[2:3]), "-", max(x[2:3]), ")", sep="")
return(txt)
})
test
``````

This could possibly be done by the update() function but I imagine there should be some automated process since this is common practice

### UPDATE

After some thinking and with some inspiration from the answer I wrote this function:

``````print_adjusted_and_unadjusted <- function(fit, digits=2){
# Just a prettifier for the output an alternative could be:
# paste(round(x[,1],1), " (95% CI ", min(round(x[,2:3])), "-", max(round(x[,2:3])), ")", sep="")
get_coef_and_ci <- function(fit){
# Just to make sure that it gives 1.0 and
# not 1 if digits = 1, in cases where a
# adding another decimal that is used
# since everyone is so hyped about p-val < 0.05
ret <- round(as.double(x), digits)
if (x == 1){
ret <- round(x, digits+1)
if (ret == 1){
ret <- paste("1.", paste(rep("0", digits), collapse=""), sep="")
}
}else if(nchar(as.character(x)) < digits + 2){
add_zeros <- digits + 2 - nchar(as.character(x))
ret <- paste(x, paste(rep("0", add_zeros), collapse=""), sep="")
}
return(ret)
}

# Get coefficients and conf. interval
my_coefficients <- coef(fit)
ci <- confint(fit)

# Use the exp() if logit or cox regression
if ("coxph" %in% class(fit) ||
("glm" %in% class(fit) &&
my_coefficients <- exp(my_coefficients)
ci <- exp(ci)
}

if (length(my_coefficients) > 1){
my_coefficients <- tapply(my_coefficients, 1:length(my_coefficients), FUN = add_zero_to_var)
}else{
}

ci <- apply(ci, 1, FUN=function(x){
ci <- round(x, digits)
for(i in 1:2){
}
return(paste(ci[1], "-", ci[2], sep=""))
})
ret_val <- cbind(my_coefficients, ci)
colnames(ret_val) <- c("", "2.5% - 97.5%")
rownames(ret_val) <- names(coef(fit))
return(ret_val)
}

# Extract all the term names
all.terms <- terms(fit)
var_names <- attr(all.terms, 'term.labels')

# Skip variables consisting of
# functions such as spline, strata variables
regex_for_unwanted_vars <- "^(strat[a]{0,1}|ns|rcs|bs|pspline)[(]"
skip_variables <- grep(regex_for_unwanted_vars, var_names)

# When using splines, rcs in cox regression this shows a little different

# Remove all the splines, rcs etc
remove_1 <- grep("(\'{1,}|[[][0-9]+[]]|[)][0-9]+)\$", rn)
remove_2 <- grep("^(strat[a]{0,1}|ns|rcs|bs)[(]", rn)
if ("cph" %in% class(fit)){
remove_3 <- grep("^rcs[(]", var_names)
}

for(variable in var_names[-skip_variables]){
interaction_variable <- length(grep(":", variable)) > 0

# If it's an interaction variable the
# interacting parts have to be included
if (interaction_variable){
variable <- paste(paste(unlist(strsplit(variable, ":")), sep="", collapse=" + "), variable, sep=" + ")
}

# Run the same fit but with only one variable
fit_only1 <- update(fit, paste(".~", variable))

# Get the coefficients processed with some advanced
# round part()
new_vars <- get_coef_and_ci(fit_only1)

# If interaction then we should only keep the
# interaction part - the other variables are
# always included by default and need therefore
# to be removed
if (interaction_variable){
new_vars <- new_vars[grep("[*:]", rownames(new_vars)),]
}

# Add them to the previous
}

# If regression contains (Intercept)
# this is meaningless for the comparison
}

return(both)
}
``````

It gives me a 4-dimentional array:

``````    Unadjusted 95% CI      Adjusted 95% CI
age "0.74"     "0.68-0.81" "0.69"   "0.62-0.76"
....
``````

I use this together with xtable (or latex() in Hmisc):

``````xtable(print_adjusted_and_unadjusted(fit.oa.base.model), align="lrcrc")
``````

I've tested it on lm(), cph() and coxph() and it seems to work.

Thanks for your help and hope that this code comes to use for more than just me.

-
What does 'add this [vector] to a two dimensional vector' actually mean? What is in all the rows and columns of the 2d vector? –  Spacedman Nov 23 '11 at 10:38
Sorry - ment matrix. –  Max Gordon Nov 25 '11 at 13:23

First of all, given the x you achieve from your `cbind`, you don't need `apply`but can simply use vectorized code:

``````test<-paste(round(x[,1],1), " (95% CI ", min(round(x[,2:3])), "-", max(round(x[,2:3])), ")", sep="")
``````

This should yield the same result.

Now, if you want to run over some different variables, you will have to build your formula as a character (note: I'm assuming test is the result of the full model here, as per your code, so I can use the names):

``````unadjusted<-sapply(names(test), function(curname){
curfrm<-paste("surv", curname, sep="~")
curfit<-coxph(as.formula(curfrm), data=sTRACE)
curx <- cbind(exp(coef(fit1)), exp(confint(fit1)))
paste(round(curx[,1],1), " (95% CI ", min(round(curx[,2:3])), "-", max(round(curx[,2:3])), ")", sep="")
})
``````

Now you can just cbind `test` en `unadjusted` for your desired effect.

-
Thank you for your answer. I used part of it as inspiration and made it a little more complicated... as I always seem to do :-) –  Max Gordon Nov 25 '11 at 13:22