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Sains Malaysiana 47(10)(2018):
2557–2563 http://dx.doi.org/10.17576/jsm-2018-4710-32
Evaluating Physical and Biological Characteristics of Glutaraldehyde (GA)Cross-Linked Nano-Biocomposite Bone Scaffold (Penilaian Pencirian
Fizikal dan
Biologi Perancah Tulang Nano Biokomposit Dipindah Silang dengan Glutaraldehid (GA)) HEMABARATHY
BHARATHAM*,
SITI
FATHIAH
MASRE,
LEO
HWEE
XIEN
& NURNADIAH AHMAD Program
of Biomedical Science, School of Diagnostic and Applied Health
Science, Faculty of Health Sciences, Universiti
Kebangsaan Malaysia, Jalan
Raja Abdul Aziz, 50300 Kuala Lumpur, Federal Territory, Malaysia Diserahkan: 28
Februari 2018/Diterima: 28 Jun 2018 ABSTRACT In vivo stability of biomaterial-based
bone scaffolds often present a significant
drawback in the development of materials for tissue engineering
purpose. Previously developed nanobiocomposite
bone scaffold using alginate and nano
cockle shell powder has shown ideal characteristics. However,
it showed high degradation rate and reduced stability in an
in vivo setting. In this study, we aim to observe the
effect of cross-linking glutaraldehyde (GA)
in three different concentrations of 0.5%, 1% and 2% during
the fabrication process as a potential factor in increasing
scaffold stability. Microstructure observations of scaffolds
using scanning electron microscope (SEM)
showed all scaffolds crossed linked with GA and control had an ideal pore
size ranging from 166.8-203.5 μm.
Increase in porosity compared to the control scaffolds was observed
in scaffolds cross-linked with 2% GA which also presented better structural
integrity as scored through semi-quantitative methods. Tested
pH values during the degradation period showed that scaffolds
from all groups remained within the range of 7.73-8.76. In
vitro studies using osteoblast showed no significant changes
in cell viability but a significant increase in ALP enzyme levels in scaffold cross-linked with 2% GA.
The calcium content released from all scaffold showed significant
differences within and between the groups. It can be concluded
that the use of GA
in the preparation stage of the scaffold did not
affect the growth and proliferation of osteoblast and use of
2% GA showed
improved scaffold structural integrity and porosity. Keywords: Bone scaffold;
glutaraldehyde; nanobiocomposite;
osteoblast ABSTRAK Kestabilan in vivo perancah
tulang berasas
biobahan merupakan salah satu kelemahan
yang ketara dalam
fabrikasi bahan untuk tujuan kejuruteraan
tisu. Perancah tulang nanobiokomposit yang telah dibangunkan terlebih dahulu menggunakan alginat dan serbuk nano
cengkerang kerang
menunjukkan ciri-ciri ideal sebagai bahan pengganti
tulang. Walau
bagaimanapun, perancah tersebut menunjukkan kadar degradasi
yang tinggi dan
pengurangan dalam kestabilan
struktur
dalam keadaan in vivo. Kajian ini
bertujuan untuk
memperhatikan kesan penggunaan glutaraldehid (GA)
sebagai bahan
pindah silang dalam
kepekatan 0.5%, 1% dan
2% terhadap perancah yang dibentuk. Kajian mikrostruktur menggunakan mikroskopi elektron imbasan (SEM) menunjukkan
kesemua perancah
tulang kajian GA dan kawalan mempunyai
saiz liang
antara 166.8-203.5 μm
yang bersesuaian untuk
tujuan penggunaan. Peningkatan keliangan berbanding perancah kawalan diperhatikan untuk perancah yang dipindah silang dengan 2% GA yang
turut menunjukkan
peningkatan dalam kestabilan struktur melalui kaedah pemarkahan semi kuantitatif.
Nilai
pH yang diukur sepanjang
tempoh kajian degradasi
menunjukkan julat
pH berada antara 7.73-8.76 untuk semua kumpulan
kajian dan
kawalan. Kajian in vitro
menggunakan osteoblas
tidak menunjukkan
sebarang perubahan signifikan kepada keviabelansel
tetapi terdapat
peningkatan dalam aktiviti enzim ALP untuk perancah yang dipindah silang dengan 2% GA.
Perbezaan signifikan pembebasan kalsium juga diperhatikan antara dan dalam semua
kumpulan kajian
dan kawalan. Secara keseluruhan,
didapati penggunaan
GA
dalam pembentukan perancah tidak memberikan kesan terhadap percambahan dan pertumbuhan osteoblas pada perancah tulang dan peningkatan dalam integriti struktur dan keliangan
perancah diperhatikan
dengan penggunaan GA pada kepekatan 2%. Kata kunci: Glutaraldehid;
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