I would use a modern block cipher (like AES, Twofish, Serpent) with CTR cipher mode. The answer from erickson mentioned something in that direction already. I try to elaborate here a bit on that.
While the cipher modes primary objective(*) is to protect you from statistical analysis of your cryptoblocks (for example preventing consecutive identical blocks producing identical cryptoblocks) you can also use CTR for transmitting a data chunk shorter than the cipher block size.
All of the block ciphers mentioned above have a block size of 128 bit. Just pad your message at the end with the extra 96 bits, for example with zeros (does not matter). Encode the message in CTR mode. You need to supply an IV block (initialization vector). You do not need to keep its value secret. However, for secure applications a new one should be randomly chosen for each transmission. Given your restriction to 32 bit codes I assume you have a low security scenario with transmittable data restricted to 32 bit, so you might stick with a fixed IV value. Just crop the result to 32 bit and transmit it.
For decoding, pad it again with 96 bits of any value, apply a regular decoding using CTR mode with above mentioned IV value and crop the value back to 32 bit. You are done!
In Python-like pseudocode (sorry, I am not into .net) that would be simply
# encode for plain_msg of length 32, key and iv
padded_plain_msg = plain_msg + *96
padded_crypted_msg = encrypt(padded_plain_msg, key, mode=CTR, iv=iv)
crypted_msg = padded_crypted_msg[0:32]
# decode for crypted_msg of length 32, key and iv
padded_crypted_msg = crypted_msg + *96
padded_decrypted_msg = encrypt(padded_crypted_msg, key, mode=CTR, iv=iv)
decrypted_msg = padded_decrypted_msg[0:32]
This is working because the CTR mode does not apply the cipher directly to the message but to a running counter (CTR: CounTeR) and xors the result with the message:
# CTR mode pseudocode on msg_blocks, msg_blocks, ..., msg_blocks[n-1]
# to crypted_block, crypted_block, ..., crypted_block[n]
for i in range(n): # i = 0, 1, ..., n-1:
# one implementation variant--there are others counter sequences, e. g.
# appending half-block sized iv & a half-block chunk containing i
crypted_block[i] = encrypt(iv+i, key) ^ msg_blocks[i]
Note that if you use a fixed IV value, you essentially have a 32 bit cipher (like you requested) and that is always attackable if the opponent gathers enough encrypted data. As James K Polk already pointed out you never want to use block ciphers of less than 64 bit if you care about security.
(*) Except for ECB (electronic code book) mode, which is a fancy way to say you apply the encoding on each block without any dependencies