Abstract. Regenerative medicine is a new field based on the use of stem cells to generate biological substitutes and improve tissue functions, restoring damaged tissue with high proliferability and differentiability. It is of interest as a potential alternative to complicated tissue / organ transplantation. Recently, amnion-derived cells have been reported to have multipotent differentiation ability, and these cells have attracted attention as a cell source for cell-transplantation therapy. The amnion possesses considerable advantageous characteristics: the isolated cells can differentiate into all three germ layers; they have low immunogenicity and anti-inflammatory functions; and they do not require the sacrifice of human embryos for their isolation, thus avoiding the current controversies associated with the use of human embryonic stem cells. Moreover, we developed human amniotic cell-sheets using a novel culture surface coated with a noncytotoxic, temperature-responsive elastic protein-based polymer. We also generated a "hyperdry-amnion", which has already been applied clinically in the ophthalmological field. Compared to cryopreserved fresh amnion, "hyper-dry-amnion" is easy to handle and has started to bring good results to patients. These materials from the amnion are also expected to open a new field in tissue engineering. Thus, amnion, which had been discarded after parturition, has started to be appreciated as an attractive material in the field of regenerative medicine. In this review, the most recent and relevant clinical and experimental data about the use of amniotic membrane and cells derived from it are described.
Recently, cartilage diseases have been treated by auto- or allogenic chondrocyte transplantation. However, such treatments are limited by the necessity of having a large amount of cells for transplantation, the risk of rejection, and donor shortage. Since the human amnion is immune-privileged tissue suitable for allotransplantation, the potential of human amniotic mesenchymal cells (HAMc) to differentiate into chondrocytes was assessed. The expression of gene encoding transcription factors SOXs and bone morphogenetic proteins (BMPs) as well as BMP receptors were assessed. Chondrocyte phenotype was characterized by positive expression of the cartilage marker genes collagen type II and aggrecan by RT-PCR, collagen type II protein were analyzed by immunofluorescence analysis. HAMc expressed chondrocyte-related genes, including SOXs, BMPs, as well as BMP receptors. Collagen type II and aggrecan were detected after the induction of chondrogenesis with BMP-2. HAMc, transplanted into noncartilage tissue of mice with BMP-2, or implanted with collagen-scaffold into the defects generated in a rat's bone, underwent morphological changes with deposition of collagen type II. These results showed that HAMc have the potential to differentiate into chondrocytes in vitro and in vivo, suggesting that they have therapeutic potential for the treatment of damaged or diseased cartilage.
Preterm premature rupture of the membranes (PPROM) has been considered to be closely associated with chorioamnionitis. However, the detailed mechanism is not well understood. Alpha 1 antitrypsin (AAT) was reported to decrease in concentration in amniotic fluid obtained from patients with PPROM. However, the origin of AAT in amniotic fluid has not been clarified. In this study, we assessed the expression and localization of AAT in human amnion, as well as its biological activity in cases with PROM. Human amniotic epithelial (hAE) cells expressed AAT. After stimulation with oncostatin M (OSM), interleukin-6 (IL-6) or tumor necrotic factor alpha (TNF alpha), hAE cells increased the expression of AAT, while the expression of MMP9 was reduced by OSM and induced by TNF alpha. Oxidized AAT (inactivated form) was detected in the amnion with PPROM and TPROM, but not in specimens without PROM. Moreover, AAT activity was decreased in amnions from cases with PROM, regardless of gestational age. Thus, the results showed that AAT in the amnion may function as a protective shield at inflammatory sites, and not as it loses it inhibitory activity in cases with PROM, possibly by oxidation, suggesting that its imbalance contributes to PROM.
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