Find the area of the $AMND$ quadrilateral;
Solution 1:
Hint :
Establish that $MN:BC:AD=2:3:4$ . Then from similar triangles, it follows that $$[EMN] : [EBC] : [EAD] = 2^2:3^2:4^2$$ $$\Rightarrow \frac{[AMND]}{[ABCD]}=\frac{4^2-2^2}{4^2-3^2}$$
Solution 2:
$\triangle AOD \sim \triangle COBC$. So $BC:AD = 3:4$, as area of $\triangle AOD$ and $\triangle BOC$ are in ratio $16:9$. If altitude from $O$ to $AD$ is $h$, altitude from $O$ to $BC$ is $\frac{3h}{4}$. If altitude from $E$ to $AD$ is $h_1$, the altitude to $BC$ is $(h_1 - \frac{7h}{4})$ and
$ \displaystyle \frac{h_1 - 7h/4}{h_1} = \frac 3 4 \implies h_1 = 7 h$
As base of both triangle $\triangle AOD$ and $\triangle EAD$ is same, $S_{\triangle EAD} = 7 \cdot S_{\triangle AOD} = 16 \cdot 7$
Now use the relationship between area of $AMND$ and $\triangle EAD$ you obtained.