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References (40)
-
Yosei Oi, Mikio Ota, Shigeki Yamamoto, Y. Shibukawa, S. Yamada (2009)
Beta-tricalcium phosphate and basic fibroblast growth factor combination enhances periodontal regeneration in intrabony defects in dogs.Dental materials journal, 28 2
-
N. Kondo, A. Ogose, K. Tokunaga, H. Umezu, K. Arai, N. Kudo, M. Hoshino, H. Inoue, H. Irie, Koichi Kuroda, H. Mera, N. Endo (2006)
Osteoinduction with highly purified beta-tricalcium phosphate in dog dorsal muscles and the proliferation of osteoclasts before heterotopic bone formation.Biomaterials, 27 25
-
B. Boilly, A. Vercoutter‐Edouart, H. Hondermarck, V. Nurcombe, X. Bourhis (2000)
FGF signals for cell proliferation and migration through different pathways.Cytokine & growth factor reviews, 11 4
-
E. Tsuruga, H. Takita, H. Itoh, Y. Wakisaka, Y. Kuboki (1997)
Pore size of porous hydroxyapatite as the cell-substratum controls BMP-induced osteogenesis.Journal of biochemistry, 121 2
-
Woven trabecular bone formation was stimulated by FGF2-loading. Abbreviations: NB, new bone. Scale bars represent 1 mm -
Some new bone formation was evident and the scaffold was frequently compressed. B) Higher magnification of the framed area in (A) -
A. Stavropoulos, P. Windisch, Dóra Szendröi-Kiss, Rosta Peter, I. Gera, A. Sculean (2010)
Clinical and histologic evaluation of granular Beta-tricalcium phosphate for the treatment of human intrabony periodontal defects: a report on five cases.Journal of periodontology, 81 2
-
V. Karageorgiou, D. Kaplan (2005)
Porosity of 3D biomaterial scaffolds and osteogenesis.Biomaterials, 26 27
-
Ulrich Tigges, Elizabeth Hyer, J. Scharf, W. Stallcup (2008)
FGF2-dependent neovascularization of subcutaneous Matrigel plugs is initiated by bone marrow-derived pericytes and macrophages, 135
-
A. Singer, R. Clark (1999)
Cutaneous wound healing.The New England journal of medicine, 341 10
-
Asako Ibara, H. Miyaji, Bunshi Fugetsu, Erika Nishida, H. Takita, Saori Tanaka, T. Sugaya, M. Kawanami (2013)
Osteoconductivity and biodegradability of collagen scaffold coated with nano-β-TCP and fibroblast growth factor 2Journal of Nanomaterials, 2013
-
S. Dorozhkin (2008)
Calcium orthophosphate cements for biomedical applicationJournal of Materials Science, 43
-
Tabatabaei Qomi, N. Kalhor, H. Fazaeli (2014)
The Design of Scaffolds for Use in Tissue Engineering -
S. Takayama, S. Murakami, Y. Shimabukuro, M. Kitamura, H. Okada (2001)
Periodontal Regeneration by FGF-2 (bFGF) in Primate ModelsJournal of Dental Research, 80
-
F. Causa, P. Netti, L. Ambrosio, G. Ciapetti, N. Baldini, S. Pagani, D. Martini, A. Giunti (2006)
Poly-epsilon-caprolactone/hydroxyapatite composites for bone regeneration: in vitro characterization and human osteoblast response.Journal of biomedical materials research. Part A, 76 1
-
Histological findings on cranial bone at 10 days. A) β-TCP scaffold. B) Higher magnification of the framed area in (A). C) PLGA/β-TCP scaffold. D) Higher magnification of the framed area in (C) -
Hellen Zheng, Yajun Bai, M. Shih, C. Hoffmann, F. Peters, C. Waldner, W. Hübner (2014)
Effect of a β-TCP collagen composite bone substitute on healing of drilled bone voids in the distal femoral condyle of rabbits.Journal of biomedical materials research. Part B, Applied biomaterials, 102 2
-
O. Gauthier, J. Bouler, E. Aguado, P. Pilet, G. Daculsi (1998)
Macroporous biphasic calcium phosphate ceramics: influence of macropore diameter and macroporosity percentage on bone ingrowth.Biomaterials, 19 1-3
-
R. Gaasbeek, H. Toonen, R. Heerwaarden, P. Buma (2005)
Mechanism of bone incorporation of beta-TCP bone substitute in open wedge tibial osteotomy in patients.Biomaterials, 26 33
-
T. Park (1995)
Degradation of poly(lactic-co-glycolic acid) microspheres: effect of copolymer composition.Biomaterials, 16 15
-
M. Chazono, Takaaki Tanaka, H. Komaki, K. Fujii (2004)
Bone formation and bioresorption after implantation of injectable beta-tricalcium phosphate granules-hyaluronate complex in rabbit bone defects.Journal of biomedical materials research. Part A, 70 4
-
Bone formation was rarely observed following implantation of β-TCP and PLGA/β-TCP scaffold. E) -
Shinji Miyamoto, K. Shinmyouzu, I. Miyamoto, K. Takeshita, Toshihisa Terada, Tetsu Takahashi (2013)
Histomorphometric and immunohistochemical analysis of human maxillary sinus-floor augmentation using porous β-tricalcium phosphate for dental implant treatment.Clinical oral implants research, 24 Suppl A100
-
H. Miyaji, Hiroyuki Yokoyama, Yuta Kosen, H. Nishimura, Kazuyasu Nakane, Saori Tanaka, Kaori Otani, Kana Inoue, Asako Ibara, Izumi Kanayama, Takashi Yoshida, Kosuke Ogawa, Erika Nishida, M. Kawanami (2013)
Bone augmentation in rat by highly porous β-TCP scaffolds with different open-cell sizes in combination with fibroblast growth factor-2Journal of oral tissue engineering, 10
-
Huipin Yuan, C. Blitterswijk, K. Groot, J. Bruijn (2006)
Cross-species comparison of ectopic bone formation in biphasic calcium phosphate (BCP) and hydroxyapatite (HA) scaffolds.Tissue engineering, 12 6
-
A. Yeo, C. Cheok, S. Teoh, Z Zhang, D. Buser, D. Bosshardt (2012)
Lateral ridge augmentation using a PCL-TCP scaffold in a clinically relevant but challenging micropig model.Clinical oral implants research, 23 12
-
R. Jansen, T. Kuppevelt, W. Daamen, A. Kuijpers-Jagtman, J. Hoff (2009)
FGF-2-loaded collagen scaffolds attract cells and blood vessels in rat oral mucosa.Journal of oral pathology & medicine : official publication of the International Association of Oral Pathologists and the American Academy of Oral Pathology, 38 8
-
Shoufeng Yang, K. Leong, Z. Du, C. Chua (2001)
The design of scaffolds for use in tissue engineering. Part I. Traditional factors.Tissue engineering, 7 6
-
P. Kasten, I. Beyen, P. Niemeyer, R. Luginbühl, M. Bohner, W. Richter (2008)
Porosity and pore size of beta-tricalcium phosphate scaffold can influence protein production and osteogenic differentiation of human mesenchymal stem cells: an in vitro and in vivo study.Acta biomaterialia, 4 6
-
M. Saito, H. Shimizu, M. Beppu, M. Takagi (2000)
The role of β-tricalcium phosphate in vascularized periosteumJournal of Orthopaedic Science, 5
-
M. Chazono, Takaaki Tanaka, S. Kitasato, Takahiro Kikuchi, K. Marumo (2008)
Electron microscopic study on bone formation and bioresorption after implantation of β-tricalcium phosphate in rabbit modelsJournal of Orthopaedic Science, 13
-
K. Uhrich, S. Cannizzaro, R. Langer, K. Shakesheff (1999)
Polymeric systems for controlled drug release.Chemical reviews, 99 11
-
茶薗 昌明 (2005)
Bone formation and bioresorption after implantation of injectable β-tricalcium phosphate granules-hyaluronate complex in rabbit bone defects -
R. Schnettler, V. Alt, E. Dingeldein, Hans-Joachim Pfefferle, O. Kilian, C. Meyer, C. Heiss, S. Wenisch (2003)
Bone ingrowth in bFGF-coated hydroxyapatite ceramic implants.Biomaterials, 24 25
-
C. Patrick, P. Chauvin, J. Hobley, G. Reece (1999)
Preadipocyte seeded PLGA scaffolds for adipose tissue engineering.Tissue engineering, 5 2
-
Blood vessels were observed at peripheral areas of the implant. J) Control group. There was little evidence of bone augmentation. Abbreviations: NB, new bone. Scale bars represent 1 mm -
Y. Ishii, Takahisa Fujita, N. Okubo, Mikio Ota, S. Yamada, A. Saito (2013)
Effect of basic fibroblast growth factor (FGF-2) in combination with beta tricalcium phosphate on root coverage in dog.Acta odontologica Scandinavica, 71 2
-
T. Roy, J. Simon, John Ricci, E. Rekow, Van Thompson, J. Parsons (2003)
Performance of degradable composite bone repair products made via three-dimensional fabrication techniques.Journal of biomedical materials research. Part A, 66 2
-
Y. Yun, Jong-Eun Won, Eunyi Jeon, SuJin Lee, W. Kang, Hye-Lim Jo, Jun-Hyeog Jang, U. Shin, H. Kim (2010)
Fibroblast Growth Factors: Biology, Function, and Application for Tissue RegenerationJournal of Tissue Engineering, 2010
-
N. Kobayashi, H. Miyaji, T. Sugaya, M. Kawanami (2010)
Bone Augmentation by Implantation of an FGF2-loaded Collagen Gel-sponge Composite ScaffoldJournal of oral tissue engineering, 8
- Publisher
- Wiley
- Copyright
- Copyright © 2015 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd
- ISSN
- 0022-3484
- eISSN
- 1600-0765
- DOI
- 10.1111/jre.12206
- pmid
- 24966062
- Publisher site
- See Article on Publisher Site
Abstract
Background and Objective Beta‐tricalcium phosphate (β‐TCP), a bio‐absorbable ceramic, facilitates bone conductivity. We constructed a highly porous three‐dimensional scaffold, using β‐TCP, for bone tissue engineering and coated it with co‐poly lactic acid/glycolic acid (PLGA) to improve the mechanical strength and biological performance. The aim of this study was to examine the effect of implantation of the PLGA/β‐TCP scaffold loaded with fibroblast growth factor‐2 (FGF‐2) on bone augmentation. Material and Methods The β‐TCP scaffold was fabricated by the replica method using polyurethane foam, then coated with PLGA. The PLGA/β‐TCP scaffold was characterized by scanning electron miscroscopy (SEM), transmission electron microscopy (TEM), X‐ray diffraction, compressive testing, cell culture and a subcutaneous implant test. Subsequently, a bone‐forming test was performed using 52 rats. The β‐TCP scaffold, PLGA‐coated scaffold, and β‐TCP and PLGA‐coated scaffolds loaded with FGF‐2, were implanted into rat cranial bone. Histological observations were made at 10 and 35 d postsurgery. Results SEM and TEM observations showed a thin PLGA layer on the β‐TCP particles after coating. High porosity (> 90%) of the scaffold was exhibited after PLGA coating, and the compressive strength of the PLGA/β‐TCP scaffold was six‐fold greater than that of the noncoated scaffold. Good biocompatibility of the PLGA/β‐TCP scaffold was found in the culture and implant tests. Histological samples obtained following implantation of PLGA/β‐TCP scaffold loaded with FGF‐2 showed significant bone augmentation. Conclusion The PLGA coating improved the mechanical strength of β‐TCP scaffolds while maintaining high porosity and tissue compatibility. PLGA/β‐TCP scaffolds, in combination with FGF‐2, are bioeffective for bone augmentation.
Journal
Journal of Periodontal Research – Wiley
Published: Jan 1, 2015
Keywords: ; ; ;