Biomimetic hydroxyapatite micro-tube tissue scaffold

E. C. Kolos; A. J. Ruys; R. Rohanizadeh; M. M. Muir; G. J. Roger

Biomimetic hydroxyapatite micro-tube tissue scaffold

E. C. Kolos, A. J. Ruys, R. Rohanizadeh, M. M. Muir, G. J. Roger

Western Sydney University

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

4 Citations (Scopus)

Abstract

The aim of this study was to fabricate a micro-tube scaffold using a biomimetic method (immersion in Simulated Body Fluid, SBF) to coat apatite on cotton fibres. The cotton fibres were first pre-treated using a phosphorylation technique and then apatite crystals were deposited on the fibres by immersing in SBF. Micro-tubes were then formed by burning out the cotton fibres at various temperatures between 950-1250Â°C. The scaffolds were fabricated by compaction of the micro-tubes in a mould. The compacted micro-tubes were then sintered at various temperatures between 900-1200Â°C. The biocompatibility and the effects of the surface morphology of scaffolds on cell coverage and proliferation were determined using osteoblast cell culture. The results showed that these scaddolds were biocompatible and able to support cell growth. Future, studies include animal studies for biomimetic tissue scaffold as a bone filler substitute material.

Original language	English
Pages (from-to)	643-646
Number of pages	4
Journal	Key Engineering Materials
Volume	284-286
Publication status	Published - 2005

Keywords

biomimetics
fibers
hydroxyapatite
osteoblasts
tissue scaffolds

Cite this

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title = "Biomimetic hydroxyapatite micro-tube tissue scaffold",

abstract = "The aim of this study was to fabricate a micro-tube scaffold using a biomimetic method (immersion in Simulated Body Fluid, SBF) to coat apatite on cotton fibres. The cotton fibres were first pre-treated using a phosphorylation technique and then apatite crystals were deposited on the fibres by immersing in SBF. Micro-tubes were then formed by burning out the cotton fibres at various temperatures between 950-1250{\^A}°C. The scaffolds were fabricated by compaction of the micro-tubes in a mould. The compacted micro-tubes were then sintered at various temperatures between 900-1200{\^A}°C. The biocompatibility and the effects of the surface morphology of scaffolds on cell coverage and proliferation were determined using osteoblast cell culture. The results showed that these scaddolds were biocompatible and able to support cell growth. Future, studies include animal studies for biomimetic tissue scaffold as a bone filler substitute material.",

keywords = "biomimetics, fibers, hydroxyapatite, osteoblasts, tissue scaffolds",

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language = "English",

volume = "284-286",

pages = "643--646",

journal = "Key Engineering Materials",

issn = "1013-9826",

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TY - JOUR

T1 - Biomimetic hydroxyapatite micro-tube tissue scaffold

AU - Kolos, E. C.

AU - Ruys, A. J.

AU - Rohanizadeh, R.

AU - Muir, M. M.

AU - Roger, G. J.

PY - 2005

Y1 - 2005

N2 - The aim of this study was to fabricate a micro-tube scaffold using a biomimetic method (immersion in Simulated Body Fluid, SBF) to coat apatite on cotton fibres. The cotton fibres were first pre-treated using a phosphorylation technique and then apatite crystals were deposited on the fibres by immersing in SBF. Micro-tubes were then formed by burning out the cotton fibres at various temperatures between 950-1250Â°C. The scaffolds were fabricated by compaction of the micro-tubes in a mould. The compacted micro-tubes were then sintered at various temperatures between 900-1200Â°C. The biocompatibility and the effects of the surface morphology of scaffolds on cell coverage and proliferation were determined using osteoblast cell culture. The results showed that these scaddolds were biocompatible and able to support cell growth. Future, studies include animal studies for biomimetic tissue scaffold as a bone filler substitute material.

AB - The aim of this study was to fabricate a micro-tube scaffold using a biomimetic method (immersion in Simulated Body Fluid, SBF) to coat apatite on cotton fibres. The cotton fibres were first pre-treated using a phosphorylation technique and then apatite crystals were deposited on the fibres by immersing in SBF. Micro-tubes were then formed by burning out the cotton fibres at various temperatures between 950-1250Â°C. The scaffolds were fabricated by compaction of the micro-tubes in a mould. The compacted micro-tubes were then sintered at various temperatures between 900-1200Â°C. The biocompatibility and the effects of the surface morphology of scaffolds on cell coverage and proliferation were determined using osteoblast cell culture. The results showed that these scaddolds were biocompatible and able to support cell growth. Future, studies include animal studies for biomimetic tissue scaffold as a bone filler substitute material.

KW - biomimetics

KW - fibers

KW - hydroxyapatite

KW - osteoblasts

KW - tissue scaffolds

UR - http://handle.westernsydney.edu.au:8081/1959.7/uws:46059

M3 - Article

SN - 1013-9826

VL - 284-286

SP - 643

EP - 646

JO - Key Engineering Materials

JF - Key Engineering Materials

ER -

Biomimetic hydroxyapatite micro-tube tissue scaffold

Abstract

Keywords

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