Resorbable polyesters in cartilage engineering: Affinity and biocompatibility of polymer fiber structures to chondrocytes

Sittinger, Michael; Reitzel, D.; Dauner, Martin; Hierlemann, Helmut; Hammer, C.; Kastenbauer, E.; Planck, H.; Burmester, Gerd R.; Bujía, J

doi:10.1002/(sici)1097-4636(199622)33:2<57::aid-jbm1>3.0.co;2-k

Cited by 208 publications

(105 citation statements)

References 22 publications

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“…Of the synthetic polymers, those derived from poly(a-hydroxy esters), 136 poly(propylene fumarates), 137 polyurethanes, 138 PGA, 139 and poly(lactideco-glycolide) 140 have been used for cartilage regeneration; however, inflammatory reaction due to synthetic scaffolds that impaired the quality of regenerated cartilage has also been reported in some studies. 141,142 Natural matrix scaffolds Naturally occurring polymers as scaffolds offer options for cartilage tissue engineering due to biocompatibility, biodegradability, low toxicity of degradation by-products, and plasticity in processing into a variety of material formats.…”

Section: Ecm Strategymentioning

confidence: 99%

Anti-Inflammatory Strategies in Cartilage Repair

Zhang

Pizzute

Pei

2014

Tissue Engineering Part B: Reviews

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Section: Ecm Strategymentioning

confidence: 99%

Anti-Inflammatory Strategies in Cartilage Repair

Zhang

Pizzute

Pei

2014

Tissue Engineering Part B: Reviews

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“…Compared to fibrin, collagen, Poly(L-lactic acid) (PLLA), and poly (DL-lactic-co-glycolic acid) (PLGA), PGA was shown to provide a better scaffold for in vitro cartilage regeneration, as demonstrated by cell densities equivalent to those found in natural tissues, and by continuous cellular production of type II collagen [174]. Although such engineered constructs have also been tested for articular cartilage repair in animal models, mainly in rabbits [94,171,[175][176][177]), they have not been applied in human patients. The possible reasons include the graft induction of foreign body giant cell reaction [100] and the hydrolytic activity of the polymer substrate, which yields both toxic and partially cytotoxic degradation products.…”

Section: Scaffoldsmentioning

confidence: 99%

Cartilage tissue engineering for degenerative joint disease☆

Nešić

Whiteside

Brittberg

et al. 2006

Advanced Drug Delivery Reviews

208

156

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Pain in the joint is often due to cartilage degeneration and represents a serious medical problem affecting people of all ages. Although many, mostly surgical techniques, are currently employed to treat cartilage lesions, none has given satisfactory results in the long term. Recent advances in biology and material science have brought tissue engineering to the forefront of new cartilage repair techniques. The combination of autologous cells, specifically designed scaffolds, bioreactors, mechanical stimulations and growth factors together with the knowledge that underlies the principles of cell biology offers promising avenues for cartilage tissue regeneration. The present review explores basic biology mechanisms for cartilage reconstruction and summarizes the advances in the tissue engineering approaches. Furthermore, the limits of the new methods and their potential application in the osteoarthritic conditions are discussed.

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“…PLGA was chosen because (A) its proven biocompatibility, (B) the feasibility of threedimensional molding of the constructs in the shape of the experimental defects, (C) it allowed minimally invasive arthroscopic implantation and (D) its degradation rate, which was compatible with the expected deposition of ECM by the cells loaded on the scaffolds (Villalobos Córdoba et al 2007;Niederauer et al 2000;Sittinger et al 1996;Uematsu et al 2005). Moreover, the use of porous PLGA scaffolds permitted the retention of the cells at the defect site and promoted homogeneous distribution throughout the graft.…”

Section: Discussionmentioning

confidence: 99%

Cartilage resurfacing potential of PLGA scaffolds loaded with autologous cells from cartilage, fat, and bone marrow in an ovine model of osteochondral focal defect

et al. 2015

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Current developments in tissue engineering strategies for articular cartilage regeneration focus on the design of supportive three-dimensional scaffolds and their use in combination with cells from different sources. The challenge of translating initial successes in small laboratory animals into the clinics involves pilot studies in large animal models, where safety and efficacy should be investigated during prolonged follow-up periods. Here we present, in a single study, the long-term (up to 1 year) effect of biocompatible porous scaffolds non-seeded and seeded with fresh ex vivo expanded autologous progenitor cells that were derived from three different cell sources [cartilage, fat and bone marrow (BM)] in order to evaluate their advantages as cartilage resurfacing agents. An ovine model of critical size osteochondral focal defect was used and the test items were implanted arthroscopically into the knees. Evidence of regeneration of hyaline quality tissue was observed at 6 and 12 months post-treatment with variable success depending on the cell source. Cartilage and BM-derived mesenchymal stromal cells (MSC), but not those derived from fat, resulted in the best quality of new cartilage, as judged qualitatively by magnetic resonance imaging and macroscopic assessment, and by histological quantitative scores. Given the limitations in sourcing cartilage tissue and the risk of donor site morbidity, BM emerges as a preferential source of MSC for novel cartilage resurfacing therapies of osteochondral defects using copolymeric poly-D,L-lactide-co-glycolide scaffolds.

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Resorbable polyesters in cartilage engineering: Affinity and biocompatibility of polymer fiber structures to chondrocytes

Cited by 208 publications

References 22 publications

Anti-Inflammatory Strategies in Cartilage Repair

Anti-Inflammatory Strategies in Cartilage Repair

Cartilage tissue engineering for degenerative joint disease☆

Cartilage resurfacing potential of PLGA scaffolds loaded with autologous cells from cartilage, fat, and bone marrow in an ovine model of osteochondral focal defect

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