The polarity of the embryo is seen in the forming of embryonic and abembryonalic poles. This is obvious when observing a blastocyst where an inner cell mass (ICM) has formed. This is concentrated at one pole in the interior of the hollow sphere and is made from blastomeres.

This polarity was already set up in the fertilized oocyte. Its cytoskeleton is substantially involved with this phenomenon since the cytoskeleton is anchored at the oolemma. If the observation conditions are favorable, it is possible to distinguish between a somewhat smoother and a somewhat rougher surface on the fertilized oocyte. These two differing surfaces reflect the polarity of the future embryo.

The division of the zygote into the two-cell stage happens precisely so that one of the cells being formed is oriented to one pole and the other to the other one. The division always takes place so the polar bodies end up lying in the cleavage crease. This is not surprising since the cytoskeleton and the mitotic spindle function together to expel the polar bodies.

Once the polarity, as reflected in the two cells, has been set up, it remains in existence so that one also finds it again in the morula stage. Here an imaginary equatorial plane, created by the polar bodies, also separates the embryonic from the abembryonic poles.