BACKGROUND: The limited regeneration capacity of hyaline articular cartilage requires detailed studies concerning the tissue integration of cartilage transplants with meaningful but time and/or resource-consuming and in part ethically problematic animal models or, alternatively, with in vitro test systems for implant materials. MATERIAL AND METHODS: The present study describes a regeneration model with bovine cartilage rings (outer Ø 6 mm, central defect Ø 2 mm) for insertion, cultivation and biomechanical or histological testing of cartilage replacement materials (HE and safranin O staining). In this study, resorbable polymers composed of polyglycolic acid (PGA) were analyzed. RESULTS: Biomechanical testing showed a continuous decrease of the push-out force for the PGA inserts from the cartilage rings, probably due to the resorbability of the material. Histologically, clear immigration of cells into cell-free PGA was observed even after 4 weeks of culture, but in particular after 10 weeks. In addition, storage of proteoglycans was interpreted as an initial sign of the formation of new matrix. CONCLUSION: Thus, the new regeneration model is in principle suitable for the testing of biomaterials, but shows limitations in assessing the "lateral bonding" of resorbable materials.
BACKGROUND: The limited regeneration capacity of hyaline articular cartilage requires detailed studies concerning the tissue integration of cartilage transplants with meaningful but time and/or resource-consuming and in part ethically problematic animal models or, alternatively, with in vitro test systems for implant materials. MATERIAL AND METHODS: The present study describes a regeneration model with bovinecartilage rings (outer Ø 6 mm, central defect Ø 2 mm) for insertion, cultivation and biomechanical or histological testing of cartilage replacement materials (HE and safranin O staining). In this study, resorbable polymers composed of polyglycolic acid (PGA) were analyzed. RESULTS: Biomechanical testing showed a continuous decrease of the push-out force for the PGA inserts from the cartilage rings, probably due to the resorbability of the material. Histologically, clear immigration of cells into cell-free PGA was observed even after 4 weeks of culture, but in particular after 10 weeks. In addition, storage of proteoglycans was interpreted as an initial sign of the formation of new matrix. CONCLUSION: Thus, the new regeneration model is in principle suitable for the testing of biomaterials, but shows limitations in assessing the "lateral bonding" of resorbable materials.
Authors: M Endres; K Neumann; S E A Schröder; S Vetterlein; L Morawietz; J Ringe; M Sittinger; C Kaps Journal: Tissue Cell Date: 2007-08-03 Impact factor: 2.466
Authors: Victoria Horbert; Long Xin; Peter Foehr; Olaf Brinkmann; Matthias Bungartz; Rainer H Burgkart; T Graeve; Raimund W Kinne Journal: Cartilage Date: 2018-02-20 Impact factor: 4.634
Authors: Victoria Horbert; Long Xin; Peter Föhr; René Huber; Rainer H Burgkart; Raimund W Kinne Journal: Int J Mol Sci Date: 2021-10-29 Impact factor: 5.923