**TL;DR**: it's just the additional loss generated by the regularization function. Add that to the network's loss and **optimize over the sum of the two**.

As you correctly state, regularization methods are used to help an optimization method to generalize better.
A way to obtain this is to add a *regularization term* to the loss function. This term is a generic function, which modifies the "global" loss (as in, the **sum** of the **network loss** and the **regularization loss**) in order to drive the optimization algorithm in desired directions.

Let's say, for example, that for whatever reason I want to encourage solutions to the optimization that have weights as close to zero as possible. One approach, then, is to add to the loss produced by the network, a function of the network weights (for example, a scaled-down sum of all the absolute values of the weights). Since **the optimization algorithm minimizes the global loss**, my regularization term (which is high when the weights are far from zero) will push the optimization towards solutions tht have weights close to zero.