Sains
Malaysiana 52(3)(2023): 967-979
http://doi.org/10.17576/jsm-2023-5203-20
Decellularized and Genipin
Crosslinked Human Umbilical Cord Artery and Vein for Potential Use as
Peripheral Nerve Conduit
(Pautan Silang Arteri dan Urat Tali
Pusat Manusia Dinyahsel dan Genipin untuk Potensi Kegunaan sebagai Konduit
Saraf Periferi)
NABILA SYAHIDA BINTI ZAILAN1,
NISRIENA AZLIN BINTI MD ISA1, MUHAMMAD ASYRAF BIN HUMAYOON KABIR1,
SYAHIDA RABIA BINTI SYED ALI1, MUHAMAD FIRDAUS BIN NORISMAN1,
SITI A. M. IMRAN1, MOHAMAD FIKERI ISHAK1, MOHD
REUSMAAZRAN YUSOF2 & YOGESWARAN LOKANATHAN1,*
1Centre for
Tissue Engineering and Regenerative Medicine, Faculty of Medicine, Universiti
Kebangsaan Malaysia, Jalan Yaacob Latiff, Bandar Tun Razak, 56000 Cheras, Kuala
Lumpur, Federal Territory, Malaysia
2Industrial
Technology Division (BTI), Malaysian Nuclear Agency, Bangi, 43000 Kajang,
Selangor Darul Ehsan, Malaysia
Diserahkan: 30 November
2022/Diterima: 3 Februari 2023
Abstract
Critical gap peripheral nerve injury, commonly caused
by motor vehicle accidents, results in dysfunctional nerve and impaired body
function. Our study aims to develop a conduit from decellularized and genipin
crosslinked human umbilical cord artery and vein for future use in critical
nerve gap injury treatments. Human umbilical cord arteries (HUCA) and veins
(HUCV) were divided into native (nHUCA and nHUCV), decellularized (dHUCA and
dHUCV) and genipin-crosslinked (clHUCA and clHUCV) groups. Both the
decellularized and crosslinked groups were decellularized, and subsequently,
the clHUCA and clHUCV groups were crosslinked with 0.1%, 0.4% and 0.7% (w/v)
genipin. The HUCA and HUCV were then studied for decellularization efficiency,
crosslinking index, biodegradation, swelling ratio, ultrastructure analysis,
flexibility and mechanical strength. In addition, mesenchymal stem cells
isolated from Wharton’s jelly were seeded into HUCA and HUCV for
biocompatibility studies. The degradation test showed that nHUCV and dHUCV
degraded at day 7 compared to other groups that did not show any degradation
even after 21 days. Biocompatibility studies showed that the conduits
crosslinked with 0.4% (w/v) genipin were successfully seeded and was having the
most amount of seeded cells. In conclusion, the decellularization and genipin
crosslinking of human umbilical cord artery and vein enabled successful in
fabrication of conduit with suitable properties such as reduced swelling,
flexibility, porosity and mechanical strength, with potential in tissue
engineering applications.
Keywords:
Decellularization; genipin; nerve conduit; nerve injury; umbilical cord artery
Abstrak
Kecederaan
saraf periferi jurang kritikal, biasanya disebabkan oleh kemalangan kenderaan
bermotor mengakibatkan saraf tidak berfungsi dan fungsi badan akan terjejas.
Kajian ini bertujuan untuk membangunkan konduit daripada arteri dan urat tali
pusat manusia yang dinyahsel dan genipin untuk kegunaan masa hadapan dalam
rawatan kecederaan jurang saraf kritikal. Arteri tali pusat manusia (HUCA) dan
urat (HUCV) dibahagikan kepada kumpulan asli (nHUCA dan nHUCV), dinyahsel
(dHUCA dan dHUCV) dan pautan silang genipin (clHUCA dan clHUCV). Kedua-dua
kumpulan dinyahsel dan pautan silang telah dinyahsel dan seterusnya, kumpulan
clHUCA dan clHUCV telah dipaut silang dengan 0.1%, 0.4% dan 0.7% (w/v) genipin.
HUCA dan HUCV kemudiannya dikaji untuk kecekapan dinyahsel, indeks paut silang,
biodegradasi, nisbah bengkak, analisis ultrastruktur, kefleksibelan dan
kekuatan mekanikal. Di samping itu, sel stem mesinkima yang diasingkan daripada
jeli Wharton telah disemai ke dalam HUCA dan HUCV untuk kajian biokeserasian.
Ujian degradasi menunjukkan nHUCV dan dHUCV merosot pada hari ke-7 berbanding
kumpulan lain yang tidak menunjukkan sebarang degradasi walaupun selepas 21
hari. Kajian biokeserasian menunjukkan bahawa konduit yang dipaut silang dengan
genipin 0.4% (w/v) berjaya dibenih dan mempunyai jumlah sel yang paling banyak.
Kesimpulannya, dinyahsel dan pautan silang genipin arteri dan urat tali pusat
manusia telah berjaya menghasilkan konduit dengan sifat yang sesuai seperti
mengurangkan bengkak, kefleksibelan, keliangan dan kekuatan mekanikal dengan
potensi dalam aplikasi kejuruteraan tisu.
Kata
kunci: Arteri tali pusat; dinyahsel; genipin; kecederaan saraf; konduit saraf
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*Pengarang
untuk surat-menyurat; email: lyoges@ppukm.ukm.edu.my
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