Novel apatite fiber scaffolds can promote three-dimensional proliferation of osteoblasts in rodent bone regeneration models.

Hikaru Morisue; Morio Matsumoto; Kazuhiro Chiba; Hideo Matsumoto; Yoshiaki Toyama; Mamoru Aizawa; Nobuyuki Kanzawa; Takahiro J. Fujimi; Hiroshi Uchida; Isao Okada

doi:10.1002/jbm.a.32147

Novel apatite fiber scaffolds can promote three-dimensional proliferation of osteoblasts in rodent bone regeneration models.

Hikaru Morisue, Morio Matsumoto, Kazuhiro Chiba, Hideo Matsumoto, Yoshiaki Toyama, Mamoru Aizawa, Nobuyuki Kanzawa, Takahiro J. Fujimi, Hiroshi Uchida, Isao Okada

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

We have successfully synthesized hydroxyapatite fibers via a homogenous precipitation method. Using these hydroxyapatite fibers, we have produced the apatite fiber scaffolds (AFS) with well-controlled pore sizes (porosity above 95%). The AFS is relatively simple to synthesize, and its porosity and pore size are controllable. The usefulness of AFS as a scaffold for bone regeneration was evaluated by (1) seeding and culturing cells in the AFS in vitro, (2) implanting the AFS seeded with cells inside the subcutaneous tissue of mice. The AFS had biocompatibility to support cell adhesion, proliferation, and differentiation. Ectopic bone formation could be formed in the AFS at 12 weeks after implantation into the subcutaneous tissue. Because of its high interpore connection, pore diameters, and porosity, it was believed that AFS was an effective scaffold that provided a three-dimensional cell culture environment. In both in vitro and in vivo environments, the more porous AFS was more advantageous in cell proliferation, cell adhesion, proliferating capacity, robust cell differentiation, ultimately inducing bone ingrowth inside the scaffolds.

Original language	English
Pages (from-to)	811-818
Number of pages	8
Journal	Journal of biomedical materials research. Part A
Volume	90
Issue number	3
DOIs	https://doi.org/10.1002/jbm.a.32147
Publication status	Published - 2009
Externally published	Yes

ASJC Scopus subject areas

Ceramics and Composites
Biomaterials
Biomedical Engineering
Metals and Alloys

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abstract = "We have successfully synthesized hydroxyapatite fibers via a homogenous precipitation method. Using these hydroxyapatite fibers, we have produced the apatite fiber scaffolds (AFS) with well-controlled pore sizes (porosity above 95%). The AFS is relatively simple to synthesize, and its porosity and pore size are controllable. The usefulness of AFS as a scaffold for bone regeneration was evaluated by (1) seeding and culturing cells in the AFS in vitro, (2) implanting the AFS seeded with cells inside the subcutaneous tissue of mice. The AFS had biocompatibility to support cell adhesion, proliferation, and differentiation. Ectopic bone formation could be formed in the AFS at 12 weeks after implantation into the subcutaneous tissue. Because of its high interpore connection, pore diameters, and porosity, it was believed that AFS was an effective scaffold that provided a three-dimensional cell culture environment. In both in vitro and in vivo environments, the more porous AFS was more advantageous in cell proliferation, cell adhesion, proliferating capacity, robust cell differentiation, ultimately inducing bone ingrowth inside the scaffolds.",

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AU - Morisue, Hikaru

AU - Matsumoto, Morio

AU - Chiba, Kazuhiro

AU - Matsumoto, Hideo

AU - Toyama, Yoshiaki

AU - Aizawa, Mamoru

AU - Kanzawa, Nobuyuki

AU - Fujimi, Takahiro J.

AU - Uchida, Hiroshi

AU - Okada, Isao

PY - 2009

Y1 - 2009

N2 - We have successfully synthesized hydroxyapatite fibers via a homogenous precipitation method. Using these hydroxyapatite fibers, we have produced the apatite fiber scaffolds (AFS) with well-controlled pore sizes (porosity above 95%). The AFS is relatively simple to synthesize, and its porosity and pore size are controllable. The usefulness of AFS as a scaffold for bone regeneration was evaluated by (1) seeding and culturing cells in the AFS in vitro, (2) implanting the AFS seeded with cells inside the subcutaneous tissue of mice. The AFS had biocompatibility to support cell adhesion, proliferation, and differentiation. Ectopic bone formation could be formed in the AFS at 12 weeks after implantation into the subcutaneous tissue. Because of its high interpore connection, pore diameters, and porosity, it was believed that AFS was an effective scaffold that provided a three-dimensional cell culture environment. In both in vitro and in vivo environments, the more porous AFS was more advantageous in cell proliferation, cell adhesion, proliferating capacity, robust cell differentiation, ultimately inducing bone ingrowth inside the scaffolds.

AB - We have successfully synthesized hydroxyapatite fibers via a homogenous precipitation method. Using these hydroxyapatite fibers, we have produced the apatite fiber scaffolds (AFS) with well-controlled pore sizes (porosity above 95%). The AFS is relatively simple to synthesize, and its porosity and pore size are controllable. The usefulness of AFS as a scaffold for bone regeneration was evaluated by (1) seeding and culturing cells in the AFS in vitro, (2) implanting the AFS seeded with cells inside the subcutaneous tissue of mice. The AFS had biocompatibility to support cell adhesion, proliferation, and differentiation. Ectopic bone formation could be formed in the AFS at 12 weeks after implantation into the subcutaneous tissue. Because of its high interpore connection, pore diameters, and porosity, it was believed that AFS was an effective scaffold that provided a three-dimensional cell culture environment. In both in vitro and in vivo environments, the more porous AFS was more advantageous in cell proliferation, cell adhesion, proliferating capacity, robust cell differentiation, ultimately inducing bone ingrowth inside the scaffolds.

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Novel apatite fiber scaffolds can promote three-dimensional proliferation of osteoblasts in rodent bone regeneration models.

Abstract

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