TY - JOUR
T1 - Adipose-derived stem cells seeded on acellular dermal matrix grafts enhance wound healing in a murine model of a full-thickness defect
AU - Huang, Sheng-Ping
AU - Hsu, Chia-Chun
AU - Chang, Shun-Cheng
AU - Wang, Chih-Hsin
AU - Deng, Shou-Cheng
AU - Dai, Niann-Tzyy
AU - Chen, Tim-Mo
AU - Chan, James-Yi-Hsin
AU - Chen, Shyi-Gen
AU - Huang, Shih-Ming
N1 - 被引用次數:32
Export Date: 21 March 2016
CODEN: APCSD
通訊地址: Chen, S.-G.; Division of Plastic and Reconstructive Surgery, Tri-Service General Hospital, National Defense Medical Center, 325, Sec. 2, Cheng-Kung Rd, Taipei 114, Taiwan; 電子郵件: [email protected]
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Chai, J.K., Liang, L.M., Yang, H.M., Preparation of laser microspore porcine acellular dermal matrix for skin graft: An experimental study (2007) Burns., 33, pp. 719-725; Ma, B., Zimmermann, T., Rohde, M., Use of Autostitch for automatic stitching of microscope images (2007) Micron., 38, pp. 492-499; Schaffler, A., Buchler, C., Concise review: Adipose tissue-derived stromal cellsVbasic and clinical implications for novel cell-based therapies (2007) Stem Cells., 25, pp. 818-827; Giddings, J.C., Shall, L., Enhanced release of von Willebrand factor by human endothelial cells in culture in the presence of phorbol myristate acetate and interleukin 1 (1987) Thromb Res., 47, pp. 259-267; Doring, A., Wild, M., Vestweber, D., E-and P-selectin are not required for the development of experimental autoimmune encephalomyelitis in C57BL/6 and SJL mice (2007) J Immunol., 179, pp. 8470-8479; Clark, R.A., Ghosh, K., Tonnesen, M.G., Tissue engineering for cutaneous wounds (2007) J Invest Dermatol., 127, pp. 1018-1029; Nie, C., Yang, D., Morris, S.F., Local delivery of adipose-derived stem cells via acellular dermal matrix as a scaffold: A new promising strategy to accelerate wound healing (2009) Med Hypotheses., 72, pp. 679-682; Wang, X., Willenbring, H., Akkari, Y., Cell fusion is the principal source of bone-marrow-derived hepatocytes (2003) Nature., 422, pp. 897-901; Zhang, S., Wang, D., Estrov, Z., Both cell fusion and transdifferentiation account for the transformation of human peripheral blood CD34-positive cells into cardiomyocytes in vivo (2004) Circulation., 110, pp. 3803-3807; Aurich, H., Sgodda, M., Kaltwasser, P., Hepatocyte differentiation of mes-enchymal stem cells from human adipose tissue in vitro promotes hepatic integration in vivo (2009) Gut., 58, pp. 570-581; Bai, X., Yan, Y., Song, Y.H., Both cultured and freshly isolated adipose tissue-derived stem cells enhance cardiac function after acute myocardial infarction (2010) Eur Heart J., 31, pp. 489-501; Altman, A.M., Matthias, N., Yan, Y., Dermal matrix as a carrier for in vivo delivery of human adipose-derived stem cells (2008) Biomaterials., 29, pp. 1431-1442; Cherubino, M., Rubin, J.P., Miljkovic, N., Adipose-derived stem cells for wound healing applications (2011) Ann Plast Surg., 66, pp. 210-215; Nambu, M., Kishimoto, S., Nakamura, S., Accelerated wound healing in healing-impaired db/db mice by autologous adipose tissue-derived stro-mal cells combined with atelocollagen matrix (2009) Ann Plast Surg., 62, pp. 317-321; Altman, A.M., Yan, Y., Matthias, N., IFATS collection: Human adipose-derived stem cells seeded on a silk fibroin-chitosan scaffold enhance wound repair in a murine soft tissue injury model (2009) Stem Cells., 27, pp. 250-258; Nambu, M., Ishihara, M., Nakamura, S., Enhanced healing of mitomycin C-treated wounds in rats using inbred adipose tissue-derived stromal cells within an atelocollagen matrix (2007) Wound Repair Regen., 15, pp. 505-510; Blanton, M.W., Hadad, I., Johnstone, B.H., Adipose stromal cells and platelet-rich plasma therapies synergistically increase revascularization during wound healing (2009) Plast Reconstr Surg., 123, pp. 56SY64S; 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PY - 2012
Y1 - 2012
N2 - INTRODUCTION: The promotion of wound healing using dermal substitutes has become increasingly widespread, but the outcomes of substitute-assisted healing remain functionally deficient. Adipose-derived stem cells (ASCs) have been investigated widely in regenerative medicine and tissue engineering, and they have the potential to enhance wound healing. In this study, we focused on investigating the effects and mechanism of ASCs combined with an acellular dermal matrix (ADM) to treat full-thickness cutaneous wounds in a murine model. METHODS: The ADM was prepared from the dorsal skin of nude mice by decellularization by treatment with trypsin followed by Triton X-100. The human ASCs were isolated and cultured from abdominal lipoaspirate. We created a rounded, 8-mm, full-thickness cutaneous wound in nude mice and divided the mice into the following 4 groups: silicon sheet cover only, silicon sheet with spreading ASCs, ADM only, and ASCs seeded on ADM. The granulation thickness was evaluated by histology after 7 days. Further comparisons between the ADM only and ASC-seeded ADM groups were undertaken by assessing the reepithelialization ratio and blood vessel density at postoperative days 9 and 14. Statistical analyses were conducted using Student 2-tailed t test. Immunofluorescent histology and ASC labeling were also performed to identify possible mechanisms. RESULTS: The ADM was successfully prepared, and the cytometry analysis and differentiation assay provided the characterization of the human ASCs. A marked improvement in granulation thickness was detected in the ADM-ASC group in comparison with other 3 groups. A significantly increased rate of reepithelialization in the ADM-ASC group (80 ± 6%) compared to the ADM only group (60 ± 7%) was noted on postoperative day 9. The blood vessel density was evidently increased in the ADM-ASC group (7.79 ± 0.40 vessels per field) compared to the ADM only group (5.66 ± 0.23 vessels) on day 14. Cell tracking experiments demonstrated that labeled ASCs were colocalized with staining for VEGF or endothelial cell maker vWF after the transplantation of ADM-ASCs on postoperative day 14. CONCLUSIONS: Adipose-derived stem cells seeded on an ADM can enhance wound healing, promote angiogenesis, and contribute to newly formed vasculature, and VEGF-expressing ASCs can be detected after transplantation. This model could be used to improve the other clinical applications of ASCs and to decipher the detailed mechanism by which ASCs interact with wound tissue. Copyright © 2012 by Lippincott Williams & Wilkins.
AB - INTRODUCTION: The promotion of wound healing using dermal substitutes has become increasingly widespread, but the outcomes of substitute-assisted healing remain functionally deficient. Adipose-derived stem cells (ASCs) have been investigated widely in regenerative medicine and tissue engineering, and they have the potential to enhance wound healing. In this study, we focused on investigating the effects and mechanism of ASCs combined with an acellular dermal matrix (ADM) to treat full-thickness cutaneous wounds in a murine model. METHODS: The ADM was prepared from the dorsal skin of nude mice by decellularization by treatment with trypsin followed by Triton X-100. The human ASCs were isolated and cultured from abdominal lipoaspirate. We created a rounded, 8-mm, full-thickness cutaneous wound in nude mice and divided the mice into the following 4 groups: silicon sheet cover only, silicon sheet with spreading ASCs, ADM only, and ASCs seeded on ADM. The granulation thickness was evaluated by histology after 7 days. Further comparisons between the ADM only and ASC-seeded ADM groups were undertaken by assessing the reepithelialization ratio and blood vessel density at postoperative days 9 and 14. Statistical analyses were conducted using Student 2-tailed t test. Immunofluorescent histology and ASC labeling were also performed to identify possible mechanisms. RESULTS: The ADM was successfully prepared, and the cytometry analysis and differentiation assay provided the characterization of the human ASCs. A marked improvement in granulation thickness was detected in the ADM-ASC group in comparison with other 3 groups. A significantly increased rate of reepithelialization in the ADM-ASC group (80 ± 6%) compared to the ADM only group (60 ± 7%) was noted on postoperative day 9. The blood vessel density was evidently increased in the ADM-ASC group (7.79 ± 0.40 vessels per field) compared to the ADM only group (5.66 ± 0.23 vessels) on day 14. Cell tracking experiments demonstrated that labeled ASCs were colocalized with staining for VEGF or endothelial cell maker vWF after the transplantation of ADM-ASCs on postoperative day 14. CONCLUSIONS: Adipose-derived stem cells seeded on an ADM can enhance wound healing, promote angiogenesis, and contribute to newly formed vasculature, and VEGF-expressing ASCs can be detected after transplantation. This model could be used to improve the other clinical applications of ASCs and to decipher the detailed mechanism by which ASCs interact with wound tissue. Copyright © 2012 by Lippincott Williams & Wilkins.
KW - acellular dermal matrix (ADM)
KW - adipose-derived stem cells (ASCs)
KW - wound healing
KW - acellular dermal matrix
KW - adipocyte
KW - adipose tissue
KW - adult
KW - animal
KW - article
KW - artificial skin
KW - cartilage cell
KW - cell culture
KW - cell differentiation
KW - cytology
KW - female
KW - fluorescent antibody technique
KW - human
KW - injury
KW - mouse
KW - nude mouse
KW - osteoblast
KW - pathology
KW - skin
KW - skin transplantation
KW - stem cell transplantation
KW - tissue engineering
KW - vascularization
KW - Acellular Dermis
KW - Adipocytes
KW - Adipose Tissue
KW - Adult
KW - Animals
KW - Cell Differentiation
KW - Cells, Cultured
KW - Chondrocytes
KW - Female
KW - Fluorescent Antibody Technique
KW - Humans
KW - Mice
KW - Mice, Nude
KW - Osteoblasts
KW - Skin
KW - Skin Transplantation
KW - Skin, Artificial
KW - Stem Cell Transplantation
KW - Tissue Engineering
KW - Wound Healing
U2 - 10.1097/SAP.0b013e318273f909
DO - 10.1097/SAP.0b013e318273f909
M3 - Article
SN - 0148-7043
VL - 69
SP - 656
EP - 662
JO - Annals of Plastic Surgery
JF - Annals of Plastic Surgery
IS - 6
ER -
