Optimization of UC-MSCs cold-chain storage by minimizing temperature fluctuations using an automatic cryopreservation system.

The effective long-term cryopreservation of human mesenchymal stem cells is an essential prerequisite step and represents a critical approach for their sustained supply in basic research, regenerative medicine, and tissue engineering applications. Off-the-shelf availability of human umbilical cord-derived mesenchymal stromal cells (UC-MSCs) for regenerative medicine application requires the development of nontoxic, safe, and efficient protocols for cryopreservation. In the long-term low-temperature storage process of cells, traditional manual storage has a great impact on cell activity, recovery, and function due to repeated exposure of cells to room temperature. To minimize the effect of fluctuation in ambient temperature on stored cells, we designed an automatic cryopreservation system that handles cells under controlled temperatures. In this work, UC-MSCs were utilized to investigate and compare the influence of manual and automatic cryopreservation approaches. To simulate the manual process, the UC-MSCs were transferred back and forth repeatedly (up to 400 times) between the liquid nitrogen (LN2) tank (-150 °C) and room temperature by a robotic arm. Similarly, the UC-MSCs from the same batch were collected and transferred repeatedly between two storage units by the automatic cryopreservation system, where the cells were maintained below-150 °C throughout the cold chain process. Viability, percent recovery, adherence capability, cell proliferation, and multilineage differentiation ability were assessed for UC-MSCs. Compared to the manual approach, UC-MSCs handled by the automatic system demonstrated higher viability, percent recovery, and cell proliferation, as well as improved adherence to culture plate with greater potential in multilineage differentiation after 400 temperature cycles. The described entire cold chain system may provide a powerful tool to develop safe, reliable and efficient protocols for manufacturing and banking of UC-MSCs, improving their off-the-shelf availability for regenerative medicine applications.

Muscadine grape skin extract inhibits prostate cancer cells by inducing cell-cycle arrest, and decreasing migration through heat shock protein 40.

Previously we demonstrated that muscadine grape skin extract (MSKE), a natural product, significantly inhibited androgen-responsive prostate cancer cell growth by inducing apoptosis through the targeting of survival pathways. However, the therapeutic effect of MSKE on more aggressive androgen-independent prostate cancer remains unknown. This study examined the effects of MSKE treatment in metastatic prostate cancer using complementary PC-3 cells and xenograft model. MSKE significantly inhibited PC-3 human prostate cancer cell tumor growth in vitro and in vivo. The growth-inhibitory effect of MSKE appeared to be through the induction of cell-cycle arrest. This induction was accompanied by a reduction in the protein expression of Hsp40 and cell-cycle regulation proteins, cyclin D1 and NF-kBp65. In addition, MSKE induced p21 expression independent of wild-type p53 induced protein expression. Moreover, we demonstrate that MSKE significantly inhibited cell migration in PC-3 prostate cancer cells. Overall, these results demonstrate that MSKE inhibits prostate tumor growth and migration, and induces cell-cycle arrest by targeting Hsp40 and proteins involved in cell-cycle regulation and proliferation. This suggests that MSKE may also be explored either as a neo-adjuvant or therapeutic for castration resistant prostate cancer.