As an excellent illustration of architectural alloy designs, multilayered structures, which incorporates highstrength and high-ductility alloys in their layered composition, can accomplish unusual combinations of strength and ductility. This is possible because the continuous microstructure consisting of a single phase without a phase boundary in each layer results in a uniform distribution of strain. However, the multilayered structure shows anisotropic mechanical properties due to discontinuity from the phase boundary in the perpendicular direction (z-direction). In this work, an alloy system with a 3D continuous microstructure with two distinct steels was manufactured using laser-based directed energy deposition. The alternately deposited lines of two distinct alloys, along with the rotated consecutive layers, contribute to creating a woven-like structure. This architectural structure features continuous microstructures in multiple directions. Successfully manufactured both multilayered and woven-like systems demonstrated advanced yield strength and uniform elongation compared to each constituting alloy in the xy plane. In the z-direction, however, only the woven-like system exhibited improved properties as in the xy plane; the multilayered system did not. This isotropy in the mechanical properties of a woven-like system results from a 3D continuous microstructure in the z-direction. The strain analyses confirmed the deformation of the brittle body-centered cubic phase and partitioning to the ductile phase which are key mechanisms of mechanical property enhancement with continuous microstructure.