Literature DB >> 22526493

Dedifferentiated fat cells differentiate into osteoblasts in titanium fiber mesh.

Naotaka Kishimoto1, Yoshihiro Momota, Yoshiya Hashimoto, Kayoko Ando, Takeshi Omasa, Junichiro Kotani.   

Abstract

Mature adipocyte-derived dedifferentiated fat (DFAT) cells rapidly differentiate into osteoblasts under three-dimensional culture conditions. However, it has not been demonstrated that DFAT cells can differentiate into osteoblasts in a rigid scaffold consisting of titanium fiber mesh (TFM). We examined the proliferation and osteogenic differentiation ability of DFAT cells using TFM as a scaffold. DFAT cells derived from rabbit subcutaneous fat were seeded into TFM and cultured in osteogenic medium containing dexamethasone, L-ascorbic acid 2-phosphate and β-glycerophosphate for 14 days. In scanning electron microscopy (SEM) analysis, well-spread cells covered the titanium fibers on day 3, and appeared to increase in number from day 3 to 7. Numerous globular accretions were found and almost completely covered the fibers on day 14. Cell proliferation, as measured by DNA content in the TFM, was significantly higher on day 7 compared with that of day 1. Osteocalcin and calcium content in the TFM were significantly higher on day 14 compared to those of days 1, 3, and 7, indicating DFAT cells differentiated into osteoblasts. We theorize that globular accretions observed in SEM analysis may be calcified matrix resulting from osteocalcin secreted by osteoblasts binding calcium contained in fetal bovine serum. In this study, we demonstrated that DFAT cells differentiate into osteoblasts and deposit mineralized matrices in TFM. Therefore, the combination of DFAT cells and TFM may be an attractive option for bone tissue engineering.

Entities:  

Year:  2012        PMID: 22526493      PMCID: PMC3536869          DOI: 10.1007/s10616-012-9456-z

Source DB:  PubMed          Journal:  Cytotechnology        ISSN: 0920-9069            Impact factor:   2.058


  23 in total

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Authors:  Juliette van den Dolder; Paul H M Spauwen; John A Jansen
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Authors:  J A Jansen; A F von Recum; J P van der Waerden; K de Groot
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4.  Bone formation in transforming growth factor beta-I-loaded titanium fiber mesh implants.

Authors:  Johan W M Vehof; Marcus T U Haus; Anja E de Ruijter; Paul H M Spauwen; John A Jansen
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5.  Mature adipocyte-derived dedifferentiated fat cells exhibit multilineage potential.

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Journal:  J Cell Physiol       Date:  2008-04       Impact factor: 6.384

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8.  In vivo osteogenic potential of human adipose-derived stem cells/poly lactide-co-glycolic acid constructs for bone regeneration in a rat critical-sized calvarial defect model.

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9.  Flow perfusion culture of marrow stromal osteoblasts in titanium fiber mesh.

Authors:  Juliette van den Dolder; Gregory N Bancroft; Vassilios I Sikavitsas; Paul H M Spauwen; John A Jansen; Antonios G Mikos
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10.  Spatial distribution of mineralized bone matrix produced by marrow mesenchymal stem cells in self-assembling peptide hydrogel scaffold.

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  11 in total

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Authors:  Shengjuan Wei; Min Du; Zhihua Jiang; Marcio S Duarte; Melinda Fernyhough-Culver; Elke Albrecht; Katja Will; Linsen Zan; Gary J Hausman; Elham M Youssef Elabd; Werner G Bergen; Urmila Basu; Michael V Dodson
Journal:  Adipocyte       Date:  2013-04-16       Impact factor: 4.534

2.  Transplantation of Mature Adipocyte-Derived Dedifferentiated Fat Cells Facilitates Periodontal Tissue Regeneration of Class II Furcation Defects in Miniature Pigs.

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Journal:  Materials (Basel)       Date:  2022-02-10       Impact factor: 3.623

3.  The utility of human dedifferentiated fat cells in bone tissue engineering in vitro.

Authors:  Fumito Sakamoto; Yoshiya Hashimoto; Naotaka Kishimoto; Yoshitomo Honda; Naoyuki Matsumoto
Journal:  Cytotechnology       Date:  2013-12-05       Impact factor: 2.058

4.  Phenotypic and Functional Properties of Porcine Dedifferentiated Fat Cells during the Long-Term Culture In Vitro.

Authors:  Xuewu Peng; Tongxing Song; Xiaoming Hu; Yuanfei Zhou; Hongkui Wei; Jian Peng; Siwen Jiang
Journal:  Biomed Res Int       Date:  2015-05-18       Impact factor: 3.411

5.  Dedifferentiated adipocyte-derived progeny cells (DFAT cells): Potential stem cells of adipose tissue.

Authors:  Shengjuan Wei; Linsen Zan; Gary J Hausman; Theodore P Rasmussen; Werner G Bergen; Michael V Dodson
Journal:  Adipocyte       Date:  2013-07-23       Impact factor: 4.534

Review 6.  Buccal Fat Pad as a Potential Source of Stem Cells for Bone Regeneration: A Literature Review.

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7.  Comparing the Osteogenic Potential and Bone Regeneration Capacities of Dedifferentiated Fat Cells and Adipose-Derived Stem Cells In Vitro and In Vivo: Application of DFAT Cells Isolated by a Mesh Method.

Authors:  Kiyofumi Takabatake; Masakazu Matsubara; Eiki Yamachika; Yuki Fujita; Yuki Arimura; Kazuki Nakatsuji; Keisuke Nakano; Histoshi Nagatsuka; Seiji Iida
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8.  Gadus morhua Eggs Sialoglycoprotein Prevent Estrogen Deficiency-Induced High Bone Turnover by Controlling OPG/RANKL/TRAF6 Pathway and Serum Metabolism.

Authors:  Meihui Zhao; Fengfeng Mei; Jinfeng Lu; Qingying Xiang; Guanghua Xia; Xueying Zhang; Zhongyuan Liu; Chenghui Zhang; Xuanri Shen; Qiuping Zhong
Journal:  Front Nutr       Date:  2022-04-12

9.  Application of Green Tea Catechin for Inducing the Osteogenic Differentiation of Human Dedifferentiated Fat Cells in Vitro.

Authors:  Koji Kaida; Yoshitomo Honda; Yoshiya Hashimoto; Masahiro Tanaka; Shunsuke Baba
Journal:  Int J Mol Sci       Date:  2015-11-25       Impact factor: 5.923

10.  The osteoblastic differentiation ability of human dedifferentiated fat cells is higher than that of adipose stem cells from the buccal fat pad.

Authors:  Naotaka Kishimoto; Yoshihiro Momota; Yoshiya Hashimoto; Shinichi Tatsumi; Kayoko Ando; Takeshi Omasa; Junichiro Kotani
Journal:  Clin Oral Investig       Date:  2013-12-21       Impact factor: 3.573
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