The two-dimensional electron gas (2DEG) formed at oxide interfaces, such as LaAlO₃/SrTiO₃ (STO) and AlO_x/STO, has attracted much attention for their extremely large spin-to-charge conversion efficiencies λ_IEE up to ~60 nm due to the large Rashba spin-orbit interaction. However, these insulating layers on STO prevent the propagation of a spin current injected from an adjacent ferromagnetic layer. Moreover, the mechanism of the spin-current flow in these insulating layers is still unexplored. Here, using a strongly correlated polar-metal LaTiO_3+δ (LTO) interlayer and the 2DEG formed at the LTO/STO interface in an all-epitaxial heterostructure, we demonstrate giant λ_IEE up to ~190 nm. The obtained λ_IEE is the highest value among those reported for all materials including metals, semiconductors, and topological systems so far. This highly efficient spin transport/conversion highlights the new hidden inherent possibilities of oxide interfaces for spin-orbitronics applications.