2006
DOI: 10.1089/ten.2006.12.775
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Repair of Tendon Defect with Dermal Fibroblast Engineered Tendon in a Porcine Model

Abstract: Harvesting autologous tenocytes for tendon engineering may cause secondary tendon defect at the donor site. Dermal fibroblasts are an easily accessible cell source and do not cause major donor site defect. This study aims to explore the possibility of tendon engineering using dermal fibroblasts. A total of 45 hybrid pigs were randomly divided into three groups: experimental group (n = 15)--repair of tendon defect with a dermal fibroblast engineered tendon; control group 1 (n = 15)--repair of defect with a teno… Show more

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Cited by 206 publications
(158 citation statements)
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“…Further, in a subcutaneous model, none of the substrates induced cellular orientation parallel to the direction of the substrate topography. It is tempting to hypothesise that two-dimensional imprinted substrates are overwhelmed with body fluids and protein adsorption upon implantation, prohibiting favourable cell / material interaction at the substrate-tissue nano-biointerface and that three-dimensional fibrous constructs are more effective for directional neural [77][78][79], tendon [29,35,80], bone [81][82][83] and skin [84][85][86] neotissue formation and promote relatively enhanced cell growth, motility, matrix deposition and neotissue growth through the provision of a true three-dimensional environment.…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…Further, in a subcutaneous model, none of the substrates induced cellular orientation parallel to the direction of the substrate topography. It is tempting to hypothesise that two-dimensional imprinted substrates are overwhelmed with body fluids and protein adsorption upon implantation, prohibiting favourable cell / material interaction at the substrate-tissue nano-biointerface and that three-dimensional fibrous constructs are more effective for directional neural [77][78][79], tendon [29,35,80], bone [81][82][83] and skin [84][85][86] neotissue formation and promote relatively enhanced cell growth, motility, matrix deposition and neotissue growth through the provision of a true three-dimensional environment.…”
Section: Discussionmentioning
confidence: 99%
“…electro-spinning [26][27][28][29][30][31], fibre extrusion [32][33][34][35], isoelectric focusing [36,37] and imprinting [38][39][40]) have been at the forefront of scientific and technological research and innovation to recapitulate native tendon extracellular matrix (ECM) supramolecular assemblies. Although fibrous constructs (e.g.…”
Section: Introductionmentioning
confidence: 99%
“…Porcine dermal fibroblasts and TCs loaded on PLGA electro-spun fibres have been shown to promote tenogenic function in vitro and improved healing, as evidenced by improved gross morphology, histological analysis and biomechanical properties, in vivo [413][414][415][416]. In conjugation with BMSCs, electro-spun PLGA scaffolds have demonstrated suppression of lymphocytes in vitro and improved biomechanical properties and acceptable integration into the native tendon tissue [417].…”
Section: Bottom-up Approached For Tendon Repair Based On Synthetic Inmentioning
confidence: 99%
“…Nonwoven PGA meshes have been used extensively by our group 15,16 and others to culture engineered vessels and other tissues such as cartilage, 18 skin, 19 tendon, and ligaments. 20,21 However, PGA-based tissues often contain polymer fragments at the end of culture. 15,16,22,23 To achieve a goal of creating biological connective tissues with minimal to no synthetic polymeric fragments in the final product, and hence maximal mechanical properties, there was an obvious need for a scaffold that degrades very rapidly, and yet supports cellular adhesion and collagenous matrix deposition.…”
mentioning
confidence: 99%