You do not include the most important fact about the attacker: who is the attacker? The analysis depends heavily on the answer to this question.
If the attacker is the user then you are done. There's nothing whatsoever you can do if the attacker owns the machine. They own the machine. You don't even know if they're running Windows or not for heaven's sake. They could have written their own operating system and their own CLR. Even if there was a security system in the CLR, you can't rely on it because the attacker might be attacking your code from a custom environment. It is impossible for code to keep secrets from a determined user.
In that case all you can do is (1) lower the benefit of the attacker deriving the secret and (2) raise the cost. Once the cost of the attack exceeds the benefit of a successful attack, a rational attacker will give up.
Better though in this case to do neither. Do not put secrets on a user machine if you don't trust the user. Keep the secrets on a machine that you own.
If the attacker is writing hostile code and then tricking the user into running the code, then you have a shot at it. If the user grants full trust to the hostile code then the hostile code is fully trusted and we're in the same situation as before; the hostile code is fully trusted and therefore is every bit as powerful as the user; that's what "full trust" means.
If the hostile code is partially trusted then in order for it to be allowed to read private members via Reflection, it's got to be granted Skip Visibility Checks permission.
Alternatively, it could be granted Restricted Skip Visibility Checks; an assembly which is granted RSV is allowed to look at the private data of any assembly that was granted equal or less rights.