Why do we refer the cross section ratios to muons?

To first order, muon pair production:

$$ e^+ + e^- rightarrow mu^+ + mu^- $$

only proceeds via the $s$-channel. That is, the electron position pair annihilate into a virtual photon or Z-boson, which then decays to the final state.

Meanwhile:

$$ e^+ + e^- rightarrow e^+ + e^- $$

has both an $s$ and $t$ channel amplitude, making comparison with $qbar q$ processes less clear. In the $t$-channel, the particles scatter by exchanging a photon. Colloquially, one would say the detected particles are the same ones from the colliding beam, but that's a bit deceptive, since all electrons (positrons) are identical. Identical particles means the $s$ and $t$ amplitudes interfere, further complicating comparison with:

$$ e^+ + e^- rightarrow q + bar q $$

Neglecting QCD effect, $R$ should be independent of $sqrt s$ (kinematically), and only depend on the number of quarks available in the final state giving the total collision (threshold effects):

$$ R_{QED} = frac{sum_q{e^2_q}}{e^2_{mu}}$$

where $q$ runs over quark flavors and $e_q$ ($e_{mu}$) are the quark (muon) charges.