Vitiligo is characterized by destruction of melanocytes in the epidermis. In this study, we develop a chitosan-based melanocyte patch transplant for vitiligo treatment. In the development of melanocyte patch, a unique phenomenon of human melanocytes is revealed: formation of multicellular spheroids on chitosan surface. We characterize the attachment and growth of human melanocytes as well as the conditions for melanocyte spheroid formation on chitosan surface. Melanocytes have good attachment to chitosan and chitosan is able to support the growth and phenotype expression of melanocytes. Melanocytes spontaneously aggregate and grow into multicellular spheroids when cells are seeded above a critical seeding density. We further demonstrate that spheroid formation requires intact actin and microtubule networks and serum-derived factors are not essential for this process. By use of time-lapse microscopy, we find that, in comparison with melanocytes on tissue culture polystyrene plates, melanocytes migrate faster on chitosan. With increasing seeding densities which enable frequent intercellular contact, cells translocate and aggregate into spheroids. By disrupting surface E-cadherin with monoclonal antibody, melanocyte spheroid formation is inhibited. Moreover, cells within the spheroids are still proliferative when initial spheroids are formed. Hence, active migration on biomaterials and abundant cell surface adhesion molecules that hold cells together are indispensable for melanocyte spheroid formation. Cell proliferation within the spheroids also contributes to the enlargement of spheroids. Functionally, more than 95% of the cells in the spheroids are viable and the cells within the spheroids produce melanin in the cytoplasm. After being seeded on collagen I coated surface, spheroids disintegrate gradually and melanocytes grow back to a physiological dendritic morphology. To simulate the stringent conditions that melanocytes may encounter during transplantation, cells are tested in a serum and growth factor deprived condition which usually compromises melanocyte viability quickly. Surprisingly, compared with the survival of monolayered melanocytes, cell survival of melanocyte spheroids is much enhanced. Hence, culturing melanocytes into spheroids on chitosan surface can provide melanocytes a survival advantage. Our results suggest that chitosan-based melanocyte spheroid patch may increase the engraftment rates during melanocyte transplantation. In addition, the interaction of melanocytes with chitosan can serve as a model for investigation of the self-assembly process of cells in biomedical researches.