At some point the cryptographic primitives in your code will need to access and use the actual value of the key. There's simply no way around that. In a simple analogy, you cannot compute
a + b if you don't know
The big question concerning secure software design thus boils down to how long sensitive information will persist in an unprotected state. Any sort of password caching is your enemy here, but even if neither the password nor the decrypted key are explicitly cached, they're still in memory at some point. Freezing a computer with liquid nitrogen can keep the memory content intact for a considerable amount of time, and forcing a swap-to-disk is another problem.
Good cryptographic programs should take care to overwrite the memory content as promptly as feasible and minimize the amount of time that sensitive information is retained in readable form. This requires careful analysis of which information is critical (e.g. the user's password input), and platform-specific knowledge of memory management (e.g. can you request non-pageable memory?).
It all depends on your threat model - which sort of attack do you need to protect against? If a rootkit monitors all your memory, you might be in trouble, though that rootkit would probably just read the user's password entry from the keyboard anyway.
This is a complicated issue, and there's extensive research into secure hardware design. In general, the more access an attacker has to your machine, the more likely it is that she'll be able to read sensitive data. Good design can only strive to minimize the surface of attack.