In vitro artificial skin engineering by decellularized placental scaffold for secondary skin problems of meningomyelocele

•The closure of the deep opening with a three-dimensional dull structure creates a significant potential for treatment, since the risk of infection will be removed, and the damage repaired.•The well-kept placental ECM scaffold was cytocompatible, supportive of mesenchymal cell types.•This study pres...

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Bibliographic Details
Published in:Journal of clinical neuroscience 2019-01, Vol.59, p.291-297
Main Authors: Somuncu, Özge Sezin, Coşkun, Yeşim, Ballica, Başak, Temiz, Ahmet Furkan, Somuncu, Doruk
Format: Article
Language:English
Subjects:
Acellular Dermis
Animals
Extracellular Matrix
Female
Fetal Stem Cells - cytology
Humans
Immunohistochemistry
Meningomyelocele - pathology
Meningomyelocele - surgery
Placenta - cytology
Pregnancy
Skin Transplantation - methods
Skin, Artificial
Tissue Engineering - methods
Tissue Scaffolds
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Summary:•The closure of the deep opening with a three-dimensional dull structure creates a significant potential for treatment, since the risk of infection will be removed, and the damage repaired.•The well-kept placental ECM scaffold was cytocompatible, supportive of mesenchymal cell types.•This study presents one of the first steps for effective decellularization and three-dimensional reconstruction of skin-like structure.•Characterization experiments proved that the decellularized skin preserved a normal skin 3D construction and vasculature along with significant ECM arrangements. Meningomyelocele (MMC) is a condition that is originated by the fusion defect of the neural tube. It is a congenital anomaly and can be characterized by spinal cord defects and impaired skin integrity. It is very important to close the skin openings via three-dimensional artificial skin like construction for preventing infection and maintaining the healthy skin structure. Therefore, we aim to generate artificial skin like structures formed by the own cells of donor for treating the MMC-related skin disorder. In this study, waste placental tissues were collected and decellularization process was applied. Decellularized and normal placental tissues were compared by immunohistochemistry (IHC). Donor’s own placental stem cells were seeded onto biological scaffold and were differentiated into skin related cell types. Finally, gene expressions were evaluated, and the structural integrity were analyzed with IHC. Tube formation assay was also performed for examining the angiogenesis formation of the tissue in order to evaluate the possibility of a healthy organ development. Characterization experiments proved that the decellularized skin preserved a normal skin 3D construction and vasculature along with significant ECM arrangements. The well-kept placental ECM scaffold was cytocompatible, supportive of mesenchymal cell types. Native organ related scaffold is expected to carry a huge influence in skin tissue engineering via delivering a niche for skin-based cells and even for stem/progenitor cells. Regarding to the data obtained from this study, in vivo investigation the skin-like structure in animal models is thought to be the next step as a future prospect. This study is a reference investigation for skin engineering based on placental stem cells and biological scaffolds.
ISSN:0967-5868
1532-2653
DOI:10.1016/j.jocn.2018.10.044