You are trying to generate empiric p-values, corrected for the multiple comparisons you are making because of the multiple columns in your data. First, let's simulate an example data set:

```
# Simulate data
n.row = 100
n.col = 10
set.seed(12345)
group = factor(sample(2, n.row, replace=T))
data = data.frame(matrix(rnorm(n.row*n.col), nrow=n.row))
```

Calculate the Wilcoxon test for each column, but we will replicate this many times while permuting the class membership of the observations. This gives us an empiric null distribution of this test statistic.

```
# Re-calculate columnwise test statisitics many times while permuting class labels
perms = replicate(500, apply(data[sample(nrow(data)), ], 2, function(x) wilcox.test(x[group==1], x[group==2], exact=F, alternative="two.sided", correct=T)$stat))
```

Calculate the null distribution of the *maximum* test statistic by collapsing across the multiple comparisons.

```
# For each permuted replication, calculate the max test statistic across the multiple comparisons
perms.max = apply(perms, 2, max)
```

By simply sorting the results, we can now determine the p=0.05 critical value.

```
# Identify critical value
crit = sort(perms.max)[round((1-0.05)*length(perms.max))]
```

We can also plot our distribution along with the critical value.

```
# Plot
dev.new(width=4, height=4)
hist(perms.max)
abline(v=crit, col='red')
```

Finally, comparing a real test statistic to this distribution will give you an empiric p-value, corrected for multiple comparisons by controlling the family-wise error to p<0.05. For example, let's pretend a real test stat was 1600. We could then calculate the p-value like:

```
> length(which(perms.max>1600))/length(perms.max)
[1] 0.074
```

rows), and not the columns. See my edited answer below for your solution. Good luck! – John Colby Nov 12 '11 at 21:31