You cant process more requests than you have CPU cores. "fast" scalable solutions involve setting up thread pools, where the number of active (not blocked on IO) threads == the number of CPU cores. So creating 100 threads because you want to service 100 msmq requests is not good design.
Windows has a thread pooling mechanism called IO Completion Ports.
Using IO Completion ports does push the design to a single process as, in a multi process design, each process would have its own IO Completion Port thread pool that it would manage independently and hence you could get a lot more threads contending for CPU cores.
The "core" idea of an IO Completion Port is that its a kernel mode queue - you can manually post events to the queue, or get asynchronous IO completions posted to it automatically by associating file (file, socket, pipe) handles with the port.
On the other side, the IO Completion Port mechanism automatically dequeues events onto waiting worker threads - but it does NOT dequeue jobs if it detects that the current "active" threads in the thread pool >= the number of CPU cores.
Using IO Completion Ports can potentially increase the scalability of a service a lot, usually however the gain is a lot smaller than expected as other factors quickly come into play when all the CPU cores are contending for the services other resource.
If your services are developed in c++, you might find that serialized access to the heap is a big performance minus - although Windows version 6.1 seems to have implemented a low contention heap so this might be less of an issue.
To summarize - theoretically your biggest performance gains would be from a design using thread pools managed in a single process. But you are heavily dependent on the libraries you are using to not serialize access to critical resources which can quickly loose you all the theoretical performance gains.
If you do have library code serializing your nicely threadpooled service (as in the case of c++ object creation&destruction being serialized because of heap contention) then you need to change your use of the library / switch to a low contention version of the library or just scale out to multiple processes.
The only way to know is to write test cases that stress the server in various ways and measure the results.