Due to the limited repair capabilities of cartilage and regeneration of large traumatic bone defects, tissue-engineered therapies for cartilage or bone repair are the alternative strategy to harvested tissues for the conventional transplantation. The use of biomimetic biomaterials with bioactive surfaces has been considered for the application of cartilage and bone tissue engineering. We hope that the dopamine-deposited biomaterials can promote cell proliferation, function, and be good candidates for cartilage and bone tissue engineering. We use a method to coat the dopamine on various films or scaffolds including PU, PCL, PLGA and PLLA by simple immersion in the alkaline dopamine solution (pH= 8.5). The time required for dopamine modification on various polymer surfaces were only from few seconds to several minutes. Chondrocytes and osteoblasts were cultured on the surfaces with different dopamine coating times. Only few seconds to minutes was sufficient for the coating time of dopamine modification on various surfaces compared with unmodified surfaces to significantly facilitate the cell adhesion and proliferation for both chondrocytes and osteoblasts under serum medium condition. The dopamine-deposited 3-D PU scaffolds are able to augment not only chondrocytes proliferation but also synthesis of extracellular matrix including the GAGs deposition and collagen secretion. Furthermore, it was displayed that the dopamine-deposited PCL films are able to promote not only osteoblasts proliferation but also the matrix mineralization although the dopamine does not improve the ALP activity on PCL films. Through this research, a simple and efficient strategy to produce the dopamine-modified biomaterials with bioactive surfaces can enhance both chondrocytes and osteoblasts for cell adhesion, proliferation and function. Hence, dopamine may be the good candidate for the application of cartilage and bone tissue engineering. Key words: dopamine; biomaterials; cartilage tissue engineering; bone tissue engineering