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Sains Malaysiana 52(10)(2023): 2919-2930
http://doi.org/10.17576/jsm-2023-5210-14
Kesan Penambahan Nanohidroksiapatit ke dalam Simen Ionomer Kaca terhadap Morfologi dan Sifat Biologi Bahan
(Effects of Incorporating Nanohydroxyapatite into Glass Ionomer Cement towards the
Morphology and Biological Properties of the Material)
RISHNNIA MURUGAN1, NUR NAJMI
MOHAMAD ANUAR1, NURRUL SHAQINAH NASRUDDIN2 &
FARINAWATI YAZID3,*
1Program
Sains Bioperubatan, Pusat Pengajian Toksikologi & Risiko Kesihatan, Fakulti
Sains Kesihatan, Universiti Kebangsaan Malaysia, 50300 Kuala Lumpur, Malaysia
2Jabatan Diagnostik Kraniofasial dan Biosains, Fakulti Pergigian,
Universiti Kebangsaan Malaysia, 50300 Kuala Lumpur, Malaysia
3Jabatan Kesihatan Pergigian Keluarga, Fakulti Pergigian,
Universiti Kebangsaan Malaysia, 50300 Kuala Lumpur, Malaysia
Diserahkan: 12 Jun 2023/Diterima:
10 Oktober 2023
Abstrak
Simen kaca ionomer merupakan bahan pemulih yang
digunakan secara meluas dalam bidang pergigian. Namun, ia mempunyai beberapa kelemahan yang mengehadkan penggunaannya sebagai bahan restoratif. Nanohidroksiapatit (nHA) adalah bahan tambahan yang digunakan dalam simen kaca ionomer bagi mengatasi
kelemahannya. Penyelidikan ini
bertujuan untuk mengkaji kesan penambahan nHA
ke dalam simen kaca ionomer terhadap morfologi dan sifat biologi bahan melalui pemerhatian mikroskop imbasan elektron (SEM), ujian kesitotoksikan dan antibakteria.
Bagi kesitotoksikan nHA terhadap sel MC3T3-E1, sebanyak empat peratus kepekatan nHA yang berbeza digunakan dalam asai MTT iaitu 0%, 3%, 4% dan 5% selama 24 dan 48 jam. Hasilnya, kesemua kepekatan nHA yang
digunakan tidak menunjukkan kesan sitotoksik terhadap sel MC3T3-E1 dengan 4%
nHA merekodkan keviabelan sel yang tinggi pada 24 dan 48 jam. Ujian
antibakteria terhadap bakteria Streptococcus mutans dilakukan dengan ujian cakera
difusi bagi tempoh 24 jam menunjukkan bahawa sampel yang ditambah dengan 4% nHA mempunyai sifat antibakteria yang lebih baik dengan
merekodkan saiz zon perencatan yang besar berbanding dengan sampel simen kaca
ionomer sahaja. Berdasarkan pemerhatian
morfologi SEM, rekahan dan zarah nHA
yang berbentuk bulat dapat dilihat pada simen yang ditambah dengan 4% nHA. Bagi analisis Serakan Tenaga Sinar-X (EDX), penambahan 4% nHA meningkatkan peratusan unsur atom kalsium, aluminium, silikon, fosforus dan fluorin. Penggabungan 4% nHA ke dalam simen kaca ionomer menyerlahkan morfologi simen dan meningkatkan sifat biologinya, justeru,
ia sesuai digunakan sebagai bahan tambahan dalam simen kaca ionomer.
Kata kunci: Antibakteria; kesitotoksikan;
morfologi; nanohidroksiapatit; simen kaca ionomer
Abstract
Glass ionomer cement (GIC) is
widely used in clinical dentistry as a restorative material. However, GIC possesses some weakness that limits its
usage. Nanohydroxyapatite (nHA)
is an additive used in GIC to improve its properties. This study aims to determine the effects
of incorporating nHA into GIC on the morphology and biological properties of the material through scanning electron microscopy (SEM), cytotoxicity and
antibacterial. For the cytotoxicity
of nHA towards MC3T3-E1 cells, four different
concentrations of nHA were used in the MTT assay,
namely 0%, 3%, 4% and 5% for 24 and 48 h. Based on the results, all the concentrations of nHA used did not show cytotoxic effects on cells in which GIC with 4% nHA showed the highest viability at both 24 and 48 h. The antibacterial property of 4% nHA incorporated GIC against Streptococcus mutans bacteria was determined using a disk diffusion test for 24 h showing that GIC with a 4% nHA sample had greater antibacterial properties with a bigger inhibition zone size compared to GIC
only sample. The SEM morphology analysis showed higher number of cracks and spherical nHA particles on the surface of GIC with 4% nHA sample. In Energy Dispersive X-ray analysis, GIC with
4% nHA samples showed an increased atomic percentage
of elements calcium, aluminium,
silicone, fluorine and phosphorus compared to GIC only sample. The incorporation of 4% nHA into GIC has enhanced
the cement morphology and biological properties, thus it is suitable to be used
as an additive in GIC.
Keywords: Antibacterial; cytotoxicity; glass ionomer
cement; morphology nanohydroxyapatite
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*Pengarang untuk surat-menyurat; email:
drfarinawati@ukm.edu.my
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