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Cartilage Tissue Engineering Using Decellularized Biomatrix Hydrogel Containing Tgf-Β-Loaded Alginate Microspheres in Mechanically Loaded Bioreactor Publisher Pubmed



Bordbar S1, 2, 3, 4 ; Li Z4 ; Lotfibakhshaiesh N1 ; Ai J1 ; Tavassoli A5 ; Beheshtizadeh N6, 7 ; Vainieri L4 ; Khanmohammadi M1, 8 ; Sayahpour FA9 ; Baghaban Eslaminejad M3 ; Azami M1, 7 ; Grad S4 ; Alini M4
Authors

Source: Scientific Reports Published:2024


Abstract

Physiochemical tissue inducers and mechanical stimulation are both efficient variables in cartilage tissue fabrication and regeneration. In the presence of biomolecules, decellularized extracellular matrix (ECM) may trigger and enhance stem cell proliferation and differentiation. Here, we investigated the controlled release of transforming growth factor beta (TGF-β1) as an active mediator of mesenchymal stromal cells (MSCs) in a biocompatible scaffold and mechanical stimulation for cartilage tissue engineering. ECM-derived hydrogel with TGF-β1-loaded alginate-based microspheres (MSs) was created to promote human MSC chondrogenic development. Ex vivo explants and a complicated multiaxial loading bioreactor replicated the physiological conditions. Hydrogels with/without MSs and TGF-β1 were highly cytocompatible. MSCs in ECM-derived hydrogel containing TGF-β1/MSs showed comparable chondrogenic gene expression levels as those hydrogels with TGF-β1 added in culture media or those without TGF-β1. However, constructs with TGF-β1 directly added within the hydrogel had inferior properties under unloaded conditions. The ECM-derived hydrogel group including TGF-β1/MSs under loading circumstances formed better cartilage matrix in an ex vivo osteochondral defect than control settings. This study demonstrates that controlled local delivery of TGF-β1 using MSs and mechanical loading is essential for neocartilage formation by MSCs and that further optimization is needed to prevent MSC differentiation towards hypertrophy. © The Author(s) 2024.
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