Ribbon collision is a process that can rapidly disturb the symmetry of subduction zones. Previous studies have demonstrated how ribbon collision causes rotation at the surface and contortion in the slab, but have focused on the surface kinematics. We use three-dimensional mechanical models to investigate how the dynamic evolution of ribbon collision perturbs the strain and stress field at the surface, the deformation style in the slab and the force balance in intra-plate regions. In our numerical simulations, we vary the angle between the trench and the ribbon to explore the slab response to ribbons colliding at different orientations. Our numerical simulations show that ribbon collision causes significant heterogeneity of stress, strain rate and vorticity in both the overriding and subducting plates surface and the slab. Slab deformation shows compartmentalization into low and high strain-rate regions around a high vorticity zone, with strain-rate variations of up to an order of magnitude occurring in the along-strike and down-dip directions. In the context of our idealised oceanic-continental subduction system, the simulations show that intra-plate stresses are affected to a similar degree by buoyancy contrasts (i.e. gravitational potential energy variations), slab-pull and ribbon collision. This partitioning allows for significant heterogeneity in the intra-plate stress regime. This work highlights how the rapid changes in strain-rate within the slab, caused by ribbon collision, can explain the seismicity gaps observed in collisional margins, which are often interpreted as slab-tears.