Even if you could directly access hardware registers, wrapping code around the decision to use a register instead of memory is that much slower.
To get performance you need to design for performance up front.
A few examples.
Prepare an x86 VM by setting up all the traps to catch the code leaving its virtual memory space. Execute the code directly, dont emulate, branch to it and run. When the code reaches out of its memory/i/o space to talk to a device, etc, trap that and emulate that device or whatever it was reaching for then return control back to the program. If the code is processor bound it will run really fast, if I/O bound then slow but not as slow as emulating each instruction.
Static binary translation. Disassemble and translate the code before running, for example an instruction 0x34,0x2E would turn into ascii in a .c file:
al ^= 0x2E;
Ideally performing tons of dead code removal (if the next instruction modifies the flags as well then dont modify them here, etc). And letting the optimizer in the compiler do the rest. You can get a performance gain this way over an emulator, how good of a performance gain depends on how well you can optimize the code. Being a new program it runs on the hardware, registers memory and all, so the processor bound code is slower than a VM, in some cases you dont have to deal with the processor doing exceptions to trap memory/io because you have simulated the memory accesses in the code, but that still has a cost and calls a simulated device anyway so no savings there.
Dynamic translation, similar to sbt but you do this at runtime, I have heard this done for example when simulating x86 code on some other processor say a dec alpha, the code is slowly changed into native alpha instructions from x86 instructions so the next time around it executes the alpha instruction directly instead of emulating the x86 instruction. Each time through the code the program executes faster.
Or maybe just redesign your emulator to be more efficient from an execution standpoint. Look at the emulated processors in MAME for example, the readability and maintainability of the code has been sacrificed for performance. When written that was important, today with multi-core gigahertz processors you dont have to work so hard to emulate a 1.5ghz 6502 or 3ghz z80. Something as simple as looking the next opcode up in a table and deciding not to emulate some or all of the flag calculation for an instruction can give you a noticeable boost.
Bottom line, if you are interested in using the x86 hardware registers, Ax, BX, etc to emulate AX, BX, etc registers when running a program, the only efficient way to do that is to actually execute the instruction, and not execute and trap as in single stepping a debugger, but execute long strings of instructions while preventing them from leaving the VM space. There are different ways to do this, and performance results will vary, and that doesnt mean it will be faster than a performance efficient emulator. This limits you to matching the processor to the program. Emulating the registers with efficient code and a really good compiler (good optimizer) will give you reasonable performance and portability in that you dont have to match the hardware to the program being run.