Sains Malaysiana 50(2)(2021): 395-407
http://dx.doi.org/10.17576/jsm-2021-5002-11
Physiochemical
and in vitro Cytotoxicity Properties
of Biocompatible Palm Fatty Acid-Based Polyesters
(Sifat Fizikokimia dan Kesitotoksikan in
vitro Poliester Bioserasi Berasaskan Asid Lemak Sawit)
YVONNE TZE QZIAN
LING1,2, YIING JYE YAP3, YI XIN HENG1,2, SIANG
YIN LEE2*, RHUN YIAN KOH4, DESMOND TECK CHYE ANG1,
CHIN HUA CHIA5 & SENG NEON GAN1
1Department of Chemistry, Faculty of
Science, University of Malaya, Jalan Universiti, 50603 Kuala Lumpur, Federal
Territory, Malaysia
2Latex Science and Technology Unit (USTL), Technology
and Engineering Division (BTK), RRIM Sungai Buloh Research Station, Malaysian Rubber Board (MRB), 47000 Sungai Buloh, Selangor Darul Ehsan, Malaysia
3Jeffrey Cheah School of Medicine and
Health Science, Monash University Malaysia, Bandar Sunway, 47500 Selangor Darul Ehsan, Malaysia
4School of Health Sciences, Division of
Applied Biomedical Science and Biotechnology, International Medical University,
No.126, Jalan Jalil Perkasa 19, Bukit Jalil, 57000 Kuala Lumpur, Federal
Territory, Malaysia
5Material Science Program, Faculty of
Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi,
Selangor Darul Ehsan, Malaysia
Diserahkan: 15 Mei 2019/Diterima: 21 Julai 2020
ABSTRACT
With
the sharp rise in global interest in sustainability and environmental concerns,
there is a growing demand in replacing petroleum-derived raw
materials with renewable plant-based raw materials in the production
of polymers. In this study, two palm fatty acid polyesters were synthesized
from palmitic and stearic acids. Their chemical structures were identified by
FTIR and 1H-NMR analysis. Both polyesters showed a moderately high
conversion rate from the acid value determination. DSC analysis showed that the
palmitic acid polyester (PAP) had a lower Tg than that of stearic acid polyester (SAP), where PAP had a Tg of 1.8 °C, while SAP had a Tg of 31.9 °C.
TGA demonstrated that thermal decomposition of both polyesters took place via two-stage processes, which occurred above 200 °C. GPC analysis showed that PAP
(1031 g/mol) had a higher Mn value than SAP (972 g/mol). MTT assays
were performed to determine the cytotoxicity of these polyesters against human
keratinocytes (HaCaT), mouse fibroblasts (3T3), mouse
hepatocytes (H2.35), and canine kidney cells (MDCK) in both dose- and
time-dependent manners, with SDS serving as the experimental benchmark.
Comparative cytotoxicity test showed that both PAP and SAP were
biocompatibility and non-cytotoxic with the cell viability well above 80%,
except SAP demonstrated a moderately low cytotoxicity on fibroblasts with cell
viability remaining as 50.4% following 72 h exposure at 100 µg/mL of
concentration. These findings suggest that the natural-sourced palm fatty acid
polyesters have high potential to be used in pharmaceutical and nutraceutical
applications.
Keywords:
Bio-based; cytotoxicity; palm fatty acid; polyester
ABSTRAK
Dengan kenaikan mendadak minat secara global terhadapkelestarian dan
kebimbangan alam sekitar, terdapat permintaan yang semakin meningkat untuk menggantikan bahan mentah berasaskan petroleum kepada bahan mentah berasaskan tumbuhan yang boleh
diperbaharui untuk penghasilan polimer. Dalam kajian ini, dua poliester berasaskan asid lemak sawit telah disintesis daripada asid palmitik dan stearik. Struktur kimia kedua-dua poliester telah dikenal pasti oleh analisis FTIR dan 1H-NMR. Daripada ujian penentuan nilai asid, kedua-dua poliester menunjukkan kadar penukaran yang agak tinggi. Analisis DSC juga menunjukkan poliester asid palmitik (PAP) mempunyai Tg yang lebih rendah daripada poliester asid stearik (SAP) dengan PAP mempunyai Tg 1.8 °C
dan SAP mempunyai Tg 31.9 °C. Analisis TGA menunjukkan terdapat dua peringkat penguraian terma poliester yang bermula dari 200 °C ke atas. Analisis GPC menunjukkan bahawa PAP
(1031 g/mol) mempunyai nilai Mn yang lebih tinggi daripada SAP (972 g/mol). Ujian MTT dilakukan untuk menentukan kesitotoksikan poliester terhadap kultur sel seperti keratinosit manusia (HaCaT), tikus fibroblas (3T3), hepatosit tetikus (H2.35) dan sel ginjal kanin (MDCK) dalam kedua-dua faktor dos dan masa. SDS berfungsi sebagai penanda aras uji kaji untuk perbandingan. Hasil kajian menunjukkan bahawa PAP and SAP mempunyai daya tahan sel melebihi 80% dan bersifat bioserasi serta tidak sitotoksik, kecuali SAP menunjukkan sitotoksik sederhana rendah dengan daya tahan sel 50.4% ekoran pendedahan sel selama 72 jam pada kepekatan 100 µg/mL. Keputusan kajian ini mencadangkan bahawa poliester berasaskan asid lemak sawit mempunyai potensi tinggi untuk digunakan dalam aplikasi farmaseutik dan nutraseutik.
Kata kunci: Asid lemak sawit; berasaskan biologi; kesitotoksikan; poliester
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*Pengarang untuk surat-menyurat; email: leesiangyin@lgm.gov.my
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