Shock response of minerals is an essential clue for understanding of deformation properties of rocks during natural impact events in the history of Earth and planets. Shock-compression experiments are the primary method for simulating such deformation process. Shock recovery experiments using a single-stage propellant were conducted for single crystal and powdered rutile to investigate the effect of heating related to porosity on the shock-induced deformation microstructures. X-ray diffraction (XRD) and transmission electron microscopy (TEM) analyses of the shocked single crystal rutile revealed that a high-density of stacking fault occurred on the (101) plane. The defect suggests that the dominant slip system in the plastic deformation of the crystal is {101}<01>. A part of the crystal is intergrown with the α-PbO₂ structure in a topotaxial relationship: [010]_Rt // [001]_α-PbO2. Based on topological analysis, the single crystal rutile would have transformed to the α-PbO₂ structure via the calcium-fluoride structure concomitantly with shear deformation. Meanwhile, the shocked powdered rutile consists mainly of particles with pervasive entangled dislocations and recrystallized particles, where the α-PbO₂ structure did not occur at all. Considering the absence of stacking faults, a possible dominant slip system in the shocked powdered rutile is {110}[001].