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Sains Malaysiana 53(12)(2024): 3349-3364
http://doi.org/10.17576/jsm-2024-5312-18
Cytoprotective
Role of Chondrocyte Coculturing for Enhanced Cartilage Regeneration
(Peranan Sitopelindung Pengkulturan Kondrosit untuk Penjanaan Semula Rawan Dipertingkat)
MUHAMMAD
FAIZAN TARIQ1, SUMERA RASHID1, AISHA TARAR1,
UMAR SAJJAD1, MUHAMMAD RAUF AHMED2, BUSHRA IJAZ1,
HAIBA KAUL3 & NOREEN LATIEF1,*
1National Centre of Excellence in Molecular
Biology, University of The Punjab, Lahore, Pakistan
Diserahkan: 28 Julai 2024/Diterima: 27 September 2024
Abstract
Osteoarthritis
is characterized by the progressive deterioration of articular cartilage,
leading to joint pain and functional impairments. Current treatment options are
limited in their ability to stimulate cartilage regeneration. Evidence suggests
that the co-culture technique, involving the interplay of multiple cell types,
may effectively restore damaged cartilage. This investigation assessed the
regenerative impact of co-culture on osteoarthritis-affected rat knee joints.
Gene expression profiling validated phenotypic and biochemical expression
analysis. Compared to the control group, the co-cultivated cohorts showed
elevated levels of cartilage-specific markers, such as collagen and aggrecan.
Notably, the group with stress and co-cultured with normal and osteoarthritic
chondrocytes (H2O2+N+OA) demonstrated significant
results, including lower LDH release (15.06 ± 1.461), decreased
glycosaminoglycan levels (1.551 ± 0.1487), and reduced cell death percentage
(17.50 ± 3.536) compared to the H2O2 control. Safranin-O
staining retention also increased (28.89 ± 2.846), indicating enhanced
cartilage matrix retention. Enhanced expression of survival markers such as Bcl (0.3974 ± 0.02241) and decreased apoptotic markers like Bax (0.2961 ± 0.01199) were observed, confirming the
stimulation of critical genes involved in cartilage development and matrix
synthesis. These findings support the potential of co-culture technology to
accelerate cartilage regeneration and offer an innovative strategy to impede
osteoarthritis progression.
Keywords: Cartilage
regeneration; cellular survival; co-culturing; osteoarthritis
Abstrak
Osteoartitis dicirikan oleh kemerosotan progresif rawan artikular yang membawa kepada sakit sendi dan gangguan fungsi. Pilihan rawatan semasa adalah terhad dalam keupayaannya untuk merangsang pertumbuhan semula rawan. Bukti menunjukkan bahawa teknik pengkulturan bersama yang melibatkan interaksi pelbagai jenis sel boleh memulihkan rawan yang rosak dengan berkesan. Penyelidikan ini menilai kesan penjanaan semula pengkulturan bersama pada sendi lutut tikus yang terjejas oleh osteoartitis. Pemprofilan pengekspresan gen mengesahkan analisis pengekspresan fenotip dan biokimia. Berbanding dengan kumpulan kawalan, kohort yang diusahakan bersama menunjukkan peningkatan tahap penanda khusus rawan, seperti kolagen dan aggrecan. Terutamanya, kumpulan dengan tekanan dan pengkulturan bersama dengan kondrosit normal dan kondrosit osteoartitis (H2O2+N+OA) menunjukkan hasil yang ketara, termasuk pelepasan LDH yang lebih rendah (15.06 ± 1.461), penurunan paras glikosaminoglikan (1.551 ± 0.1487) dan pengurangan peratusan kematian sel (17.50 ± 3.536) berbanding kawalan H2O2. Pengekalan pewarnaan Safranin-O juga meningkat (28.89 ± 2.846), menunjukkan pengekalan matriks rawan dipertingkat. Pengekspresan penanda kelangsungan hidup yang dipertingkatkan seperti Bcl (0.3974 ± 0.02241) dan penurunan penanda apoptosis seperti Bax (0.2961 ± 0.01199) telah diperhatikan, mengesahkan rangsangan gen kritikal yang terlibat dalam pembangunan rawan dan sintesis matriks. Penemuan ini menyokong potensi teknologi pengkulturan bersama untuk mempercepatkan pertumbuhan semula rawan dan menawarkan strategi inovatif untuk menghalang perkembangan osteoartitis.
Kata kunci: Kelangsungan hidup sel; osteoartitis; pengkulturan bersama; penjanaan semula rawan
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