Droplet manipulation holds importance across various domains, including microfluidics, bioassays, water harvesting, and transportation. Drawing inspiration from nature, specifically the superhydrophobic surface of lotus leaves and the patterned surface of desert beetles, this research explores the creation of bionic magnetic superhydrophobic and patterned surfaces with programmable manipulation of droplets, including transport, mixing, and single-droplet multiplex dispersion. The surfaces are prepared using a straightforward laser selective etching technique, during which droplets easily bounce off the laser-etched surface, exhibiting low adhesion, whereas they adhere firmly to non-etched areas. The introduction of a magnetic field induces surface deformation, facilitating droplet transport under unbalanced forces on the bionic surface. Further, the feasibility of using patterned surfaces as platforms for chemical microreactions is confirmed through chemical reactions. This study offers insights into the development of functional surfaces and highlights their potential applications in rapid, high-throughput detection.