Abstract
Three-dimensional (3D) printing has gained popularity in tissue engineering and in the field of cartilage regeneration. This is due to its potential to generate scaffolds with spatial variation of cell distribution or mechanical properties, built with a variety of materials that can mimic complex tissue architecture. In the present study, horse articular chondrocytes were cultured for 2 and 4 weeks in 3D-printed chitosan (CH)-based scaffolds prepared with or without hyaluronic acid and in the presence of fetal bovine serum (FBS) or platelet lysate (PL). These 3D culture systems were analyzed in terms of their capability to maintain chondrocyte differentiation in vitro. This was achieved by evaluating cell morphology, immunohistochemistry (IHC), gene expression of relevant cartilage markers (collagen type II, aggrecan, and Sox9), and specific markers of dedifferentiated phenotype (collagen type I, Runx2). The morphological, histochemical, immunohistochemical, and molecular results demonstrated that the 3D CH scaffold is sufficiently porous to be colonized by primary chondrocytes. Thereby, it provides an optimal environment for the colonization and synthetic activity of chondrocytes during a long culture period where a higher rate of dedifferentiation can be generally observed. Enrichment with hyaluronic acid provides an optimal microenvironment for a more stable maintenance of the chondrocyte phenotype. The use of 3D CH scaffolds causes a further increase in the gene expression of most relevant ECM components when PL is added as a substitute for FBS in the medium. This indicates that the latter system enables a better maintenance of the chondrocyte phenotype, thereby highlighting a fair balance between proliferation and differentiation.
Highlights
Osteoarthritis (OA) is one of the major challenges in joint pathology in both humans and animals
The platform physically supporting the 3D construction consisted of a 0.6-mm-thick stainless-steel plate coated with a 0.6-mm chitosan or chitosan–hyaluronic acid (HA) film casted prior to printing, which was fixed on the Peltier cells of the 3D machinery and instantly frozen at temperature of −18◦C: this film constituted the base for the scaffold
The main role of the scaffold is to support cell colonization, migration, growth, and differentiation for the development and integration of the desired tissue [54]. 3D printing has gained popularity in tissue engineering owing to its capability to develop scaffolds with spatial variation in cell distribution or in mechanical properties, and scaffolds built with multiple materials for the cultivation of complex tissues like cartilage [41, 55]
Summary
Osteoarthritis (OA) is one of the major challenges in joint pathology in both humans and animals. The cartilage has limited capability for repair due to its avascular nature and to the low metabolic index of chondrocytes. Cellular and molecular mechanisms that cause altered repair involve the loss of chondrocyte differentiation and cartilage homeostasis [1]. In. Chondrocytes in 3D-Printed Chitosan addition, fibrocartilaginous tissue is formed, with reduced mechanical capacity compared with native cartilage. Tissue engineering is a potential field of regenerative medicine. It is based on the interaction of three main elements (a support biomaterial, growth factors, and cells) for the development of a biological substitute that can be used for replacement, restoration, or regeneration of damaged tissues and organs [2]
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