RRC ID 18742
著者 Nakamura M, Nagai A, Tanaka Y, Sekijima Y, Yamashita K.
タイトル Polarized hydroxyapatite promotes spread and motility of osteoblastic cells.
ジャーナル J Biomed Mater Res A
Abstract Osteoblast adhesion to surfaces of implant substrates is recognized as playing a fundamental role in the process of osteoconduction. The purpose of this study was to evaluate the in vitro adhesion of osteoblasts cultured on polarized hydroxyapatite (HA), which provides two kinds of surfaces; negatively charged HA (N-HA) and positively charged HA (P-HA). Those surfaces have been proved to enhance the osteobonding capabilities. Osteoblastic cells were seeded onto normal and polarized HA; adhesion and motility of each was observed. Polarization did not affect the percentage of the spread cells against all the adhered cells, but had a significant effect on the spreading of each cell as shown by the measured elongation of the adhered cells by fluorescence observation. The elongation of each cell was especially enhanced on the N-HA and P-HA, when compared with normal HA (O-HA). In addition, the polarization affected cell motility shown by wound healing. Motility analysis showed that the same number of cells started to migrate toward the wound areas on each type of surface. However, the migration of each cell type towards the wound area was accelerated on the N-HA and P-HA. The charges induced on the HA surface accelerated the cytoskeleton reorganization of the adhered cells. The acceleration was appeared as cell shape, actin filament pattern such as stress fiber formation, and prolongation of cell motility distance.
巻・号 92(2)
ページ 783-90
公開日 2010-2-1
DOI 10.1002/jbm.a.32404
PMID 19274714
MeSH 3T3 Cells Animals Biocompatible Materials / pharmacology* Bone Regeneration / drug effects Cell Adhesion / drug effects Cell Movement / drug effects Cell Proliferation / drug effects Cytoskeleton / drug effects Cytoskeleton / ultrastructure Durapatite / pharmacology* Fluorescent Dyes Mice Osteoblasts / drug effects* Surface Properties
IF 3.525
引用数 49
WOS 分野 ENGINEERING, BIOMEDICAL MATERIALS SCIENCE, BIOMATERIALS
リソース情報
ヒト・動物細胞 MC3T3-E1(RCB1126)