One of the most effective and safe therapeutic methods for treating vitiligo, mixed autologous keratinocytes (KCs) and melanocytes (MCs) cultures have been used for autologous cell transplantation. However, the present transplantation method is faced with a problem that may require a large amount of skin tissue and keratinocytes have limited culture potency. We have found previously that human adipose derived stromal cells (hASCs) from aspirated fat tissue could be used in place of KCs and sufficient amounts of hASCs for transplantation could be obtained by small amount of aspirated fat tissue. The present investigation was determined the effect of ASCs on ex vivo expansion MCs for transplantation. In addition, we examined for a preservation conditions of MCs which have reported low recovery rates and a slowdown in growth after cryopreservation. Various conditions including ASCs ratio, incubation period, and additive materials for MCs cultivation was determined to improve the expansion ability of MCs. The growth rate of MCs colony was elevated 6.85 folds compared the previous conditions. These MCs showed a specific expression of immature melanocyte protein, Trp-2, but did not express the mature melanocyte proteins and markers (c-kit, CD133, and etc.) of mesenchymal stem cells that represents in ASCs feeder. Results in cryopreservation experiments were determined a preservation medium for MCs showing an increased recovery rates after thawing. The characteristics of MCs after cryopreservation using a designed medium were indicated consistent morphology and immunophenotype. In conclusion, ASCs as a feeder could be used in place of keratinocytes for ex vivo expansion of MCs. For clinical trial for vitiligo patients, efficiency experiments in preclinical state should be followed.

Coculture of HSC with bone marrow-derived mesenchymal stem cells (BM-MSCs) is one of used methods to increase cell numbers before transplant to the patients. However, because of difficulties to purify HSCs after coculture with BM-MSCs, it needs to develop a method to overcome the problem. In the present study, we have examined whether a culture insert placed over a feeder layer might support the expansion of HSCs within the insert. cells isolated from the umbilical cord blood by using midiMACS were divided into three groups. A group of 1 cells were grown on a culture insert without feeder layer (Direct). The same number of HSCs was directly cocultured with BM-MSCs (Contact). The third group was placed onto an insert below which BM-MSCs were grown (Insert). To distinguish feeder cells from HSCs, BM-MSCs was pre-labeled fluorescently with PKH26 and 1 cells were seeded in the culture dishes. After culture for 13 days, the expansion factor (x) of HSCs that were grown without feeder layer (Direct) was In contrast, the number of HSCs directly cocultured with feeder layer was 59.6 0.5 and that of HSCs cultured onto an insert was The percentage of BM-MSCs cells remained being fluorescent was after culture. Immune-phenotypically large proportion of cultured cells were founded to be differentiated into myeloid/monocyte progenitor cells. The ability of BM-MSCs, fetal lung, cartilage and brain tissue cells to support ex vivo expansion of HSCs was also examined using the insert. After 11 days of coculture with each of these cells, the expansion factor of HSCs was 15.0, 39.0, 32.0 and 24.0, respectively. Based upon these observations, it is concluded that the coculture method using insert is very effective to support ex vivo expansion of HSCs and to eliminate the contamination of other cells used to coculture wth HSCs.