The analogous IBM circuit representation for the quantum scheme

Question

I am trying to implement a quantum scheme of sharing a secret via EPR states. Here is my initial state of 6 qubits begin{equation}   |psirangle=left(dfrac{|0rangle_1|0rangle_2+ |1rangle_1|1rangle_2}{sqrt{2}}right) left(dfrac{|0rangle_3|0rangle_4+ |1rangle_3|1rangle_4}{sqrt{2}}right)left(dfrac{|0rangle_5|0rangle_6+ |1rangle_5|1rangle_6}{sqrt{2}}right)end{equation},

The qubits $(1,4)$ belong to $P_1$, $(2,6)$ to $P_2$, $(3,5)$ to $P_3$.
An operator is applied to qubit $1$ say the Pauli $Z$ gate, to get begin{equation}|psirangle left(dfrac{|0rangle_1|0rangle_2-|1rangle_1|1rangle_2}{sqrt{2}}right) left(dfrac{|0rangle_3|0rangle_4+ |1rangle_3|1rangle_4}{sqrt{2}}right)left(dfrac{|0rangle_5|0rangle_6+ |1rangle_5|1rangle_6}{sqrt{2}}right)end{equation}. Now after each party measures his qubits the operator is revealed.
For instance say if $P_1$ measures  $|alpha^+rangle_{14}$, and $P_2$ and $P_3$ measure $|beta^-rangle_{26}$ and $|beta^+rangle_{35}$ respectively, they write their state as after swapping as
begin{equation}
  |alpha^-rangle_{12}|alpha^+rangle_{34} |alpha^+rangle_{56}
    end{equation}, now they know the initial state of the qubits $(1,2)$, hence they deduce the operator as $Z$.

I have tried hard, but how to make the circuit for this scheme on an IBM-QE or for that matter any hardware.

The circuit provided is my try.

The part before the first barrier is where the initial state is prepared with the operator $mathbb{Z}$, (this the operator that the parties have to find out by combing their measurements).

$(2,6)$ undergoes a Bell Basis measurement with the C-NOT and hadamard.

This makes $(1,5)$ entangled, represented by the C-NOT between (1,5) (a kind of reverse C-NOT- I don't know why i did this reverse, just out of intuition).

$(3,5)$ undergoes a Bell Basis measurement with the C-NOT and Hadamard.

This makes $(1,4)$ entangled, represented by the reverse C-NOT between (1,4) (again intuition).

Then the Bell basis measurement on $(1,4)$ with the C-NOT and Hadamard.

But, i am still not knowing how to proceed, the theoretical calculations say that the final state should be
begin{equation}
    |alpha^-rangle_{12}|alpha^+rangle_{34}|alpha^+rangle_{56}
    end{equation} so that they apply the $Z$ on the first qubit to get
begin{equation}|psirangle=left(dfrac{|0rangle_1|0rangle_2+ |1rangle_1|1rangle_2}{sqrt{2}}right) left(dfrac{|0rangle_3|0rangle_4+ |1rangle_3|1rangle_4}{sqrt{2}}right)left(dfrac{|0rangle_5|0rangle_6+ |1rangle_5|1rangle_6}{sqrt{2}}right)end{equation}
Can't somebody atleast hint at where to start from?
Do i have to use conditional statements , because that is what the theory says, but how does one use these statements? I know for instance that the state 0000 on the 2,6 ,3,5 qubits will correspond to an identity operator on the 1st qubit and similarly we do these for others but does one code this on a simulator

The analogous IBM circuit representation for the quantum scheme

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