Tissue engineering techniques to regenerate articular cartilage using polymeric scaffolds

[EN] Articular cartilage is a tissue that consists of chondrocytes surrounded by a dense extracellular matrix (ECM). The ECM is mainly composed of type II collagen and proteoglycans. The main function of articular cartilage is to provide a lubricated surface for articulation. Articular cartilage dam...

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Detalles Bibliográficos
Autor: Pérez Olmedilla, Marcos
Tipo de recurso: tesis doctoral
Fecha de publicación:2015
País:España
Institución:Universitat Politècnica de València (UPV)
Repositorio:RiuNet. Repositorio Institucional de la Universitat Politécnica de Valéncia
Idioma:inglés
OAI Identifier:oai:riunet.upv.es:10251/58987
Acceso en línea:https://riunet.upv.es/handle/10251/58987
Access Level:acceso abierto
Palabra clave:Scaffold
Tissue engineering
Acrylates
Polycaprolactone (PCL)
Chondrocyte proliferation
Chondrocyte redifferentiation
Articular cartilage.
MAQUINAS Y MOTORES TERMICOS
Descripción
Sumario:[EN] Articular cartilage is a tissue that consists of chondrocytes surrounded by a dense extracellular matrix (ECM). The ECM is mainly composed of type II collagen and proteoglycans. The main function of articular cartilage is to provide a lubricated surface for articulation. Articular cartilage damage is common and may lead to osteoarthritis. Articular cartilage does not have blood vessels, nerves or lymphatic vessels and therefore has limited capacity for intrinsic healing and repair. Tissue engineering (TE) is a powerful approach for healing degenerated cartilage. TE uses three-dimensional (3D) scaffolds as cellular culture supports. The scaffold provides a structure that facilitates chondrocyte adhesion and expansion while maintaining a chondrocytic phenotype and limiting dedifferentiation, which is a problem in two-dimensional (2D) systems. Cell attachment to the scaffolds depends on the physical and chemical characteristics of their surface (morphology, rigidity, equilibrium water content, surface tension, hydrophilicity, presence of electric charges). The primary aim of this thesis was to study the influence of different kinds of biomaterials on the response of chondrocytes to in vitro culture. 3D scaffold constructs must have an interconnected porous structure in order to allow cell development through the network, to maintain their differentiated function, as well as to allow the entry and exit of nutrients and metabolic waste removal. Therefore, the effect of the hydrophilicity and pore architecture of the scaffolds was studied. A series of polymer and copolymer networks with varying hydrophilicity was synthesised and biologically tested in monolayer culture. Cell viability, proliferation and aggrecan expression were quantified. When human chondrocytes were cultured on polymer substrates in which the hydrophilic groups were homogeneously distributed, adhesion, proliferation and viability decreased with the content of hydrophilic groups. Nevertheless, copolymers in which hydrophilic and hydrophobic domains alternate showed better results than the corresponding homopolymers. Biostable and biodegradable scaffolds with different hydrophilicity and porosity were synthesised using a template of sintered microspheres of controlled size. This technique allows the interconnectivity between pores and their size to be controlled. Periodic and regular pore architectures and reproducible structures were obtained. The mechanical behaviour of the porous samples was significantly different from that of the bulk material of the same composition. Cells fully colonised the scaffolds when the pores' size and their interconnection were sufficiently large. Another objective was to assess the chondrogenic redifferentiation in a biodegradable 3D scaffold of polycaprolactone (PCL) of human autologous chondrocytes previously expanded in monolayer. This study demonstrated that chondrocytes cultured in PCL scaffolds without fetal bovine serum (FBS) efficiently redifferentiated, expressing a chondrocytic phenotype characterised by their ability to synthesise cartilage-specific ECM proteins. The influence that pore connectivity and hydrophilicity of caprolactone-based scaffolds has on the chondrocyte adhesion to the pore walls, proliferation and composition of the ECM produced was studied. The number of cells inside polycaprolactone scaffolds increased as porosity was increased. A minimum of around 70% porosity was necessary for this scaffold architecture to allow seeding and viability of the cells within. The results suggested that some of the cells inside the scaffold adhered to the pore walls and kept the dedifferentiated phenotype, while others redifferentiated. In conclusion, the findings of this thesis provide valuable insight into the field of cartilage regeneration using TE techniques. The studies carried out shed light on the right composition, porosity and hydrophilicity of the scaffolds to be used for optimal cartilage production.