There are a couple approaches I've used before or currently use:
Sequential Version Number
Most that use this approach have a separate program that grabs a version number from the database, and then executes any statements associated with database versions higher than that number, finally updating the version number in the database.
So if the version is 37 and there are statements associated with version 1 through 38 in the upgrading application, it will skip 1 through 37 and execute statements to bring the database to version 38.
I've seen implementations that also allow for downgrade statements for each version to undo what the upgrade did, and this allows for taking a database from version 38 back down to version 37.
In my situation we had this database upgrading in the application itself and did not have downgrades. Therefore, changes were source-controlled because they were part of the application.
Directed Acyclic Graph
In a more recent project I came up with a different approach. I use classes that are nodes of a directed acyclic graph to encapsulate the statements to do specific upgrades to the database for each specific feature/bugfix/etc. Each node has an attribute to declare its unique name and the names of any nodes on which it was dependent. These attributes are also used to search the assembly for all upgrade nodes.
A default root node is given as the dependency node for any nodes without dependencies, and this node contains the statements to create the
migrationregister table that lists the names of nodes that have already been applied. After sorting all the nodes into a sequential list, they are executed in turn, skipping the ones that are already applied.
This is all contained in a separate application from the main application, and they are source-controlled in the same repository so that when a developer finishes work on a feature and the database changes associated with it, they are committed together in the same changeset. If you pull the changes for the feature, you also pull the database changes. Also, the main application simply needs a list of the expected node names. Any extra or missing, and it knows the database does not match.
I chose this approach because the project often has parallel development by multiple developers, with each developer sometimes having more than 1 thing in development (branchy development, sometimes very branch). Juggling database version numbers was quite the pain. If everybody started with version 37 and "Alice" starts on something and uses version 38 so it will change her database, and "Bob" also starts on work that has to change the database and also uses version 38, someone will need to change eventually. So let's say Bob finishes and pushes to the server. Now Alice, when she pulls Bob's changeset, has to change the version for statements to 39 and set her database version back to 37 so that Bob's changes will get executed, but then hers execute again.
But when all that happens when Alice pulls Bob's changeset is that there's simply a new migration node and another line in the list of node names to check against, things just work.
We use Mercurial (distributed) rather than SVN (client-server), so that's part of why this approach works so well for us.