This study compares bovine chondrocytes harvested from four different animal locations--nasoseptal, articular, costal, and auricular--for tissue-engineered cartilage modeling. While the work serves as a preliminary investigation for fabricating a human ear model, the results are important to tissue- engineered cartilage in general. Chondrocytes were cultured and examined to determine relative cell proliferation rates, type II collagen and aggrecan gene expression, and extracellular matrix production. Respective chondrocytes were then seeded onto biodegradable poly(L-lactide-epsilon-caprolactone) disc-shaped scaffolds. Cell-copolymer constructs were cultured and subsequently implanted in the subcutaneous space of athymic mice for up to 20 weeks. Neocartilage development in harvested constructs was assessed by molecular and histological means. Cell culture followed over periods of up to 4 weeks showed chondrocyte proliferation from the tissue sources varied, as did levels of type II collagen and aggrecan gene expression. For both genes, highest expression was found for costal chondrocytes, followed by nasoseptal, articular, and auricular cells. Retrieval of 20-week discs from mice revealed changes in construct dimensions with different chondrocytes. Greatest disc diameter was found for scaffolds seeded with auricular chondrocytes, followed by those with costal, nasoseptal, and articular cells. Greatest disc thickness was measured for scaffolds containing costal chondrocytes, followed by those with nasoseptal, auricular, and articular cells. Retrieved copolymer alone was smallest in diameter and thickness. Only auricular scaffolds developed elastic fibers after 20 weeks of implantation. Type II collagen and aggrecan were detected with differing expression levels on quantitative RT-PCR of discs implanted for 20 weeks. These data demonstrate that bovine chondrocytes obtained from different cartilaginous sites in an animal may elicit distinct responses during their respective development of a tissue-engineered neocartilage. Thus, each chondrocyte type establishes or maintains its particular developmental characteristics, and this observation is critical in the design and elaboration of any tissue-engineered cartilage model.
This study examines the tissue engineering of a human ear model through use of bovine chondrocytes isolated from four different cartilaginous sites (nasoseptal, articular, costal, and auricular) and seeded onto biodegradable poly(l-lactic acid) and poly(L-lactide-epsilon-caprolactone) (50 : 50) polymer ear-shaped scaffolds. After implantation in athymic mice for up to 40 weeks, cell/scaffold constructs were harvested and analyzed in terms of size, shape, histology, and gene expression. Gross morphology revealed that all the tissue-engineered cartilages retained the initial human auricular shape through 40 weeks of implantation. Scaffolds alone lost significant size and shape over the same period. Quantitative reverse transcription-polymerase chain reaction demonstrated that the engineered chondrocyte/scaffolds yielded unique expression patterns for type II collagen, aggrecan, and bone sialoprotein mRNA. Histological analysis showed type II collagen and proteoglycan to be the predominant extracellular matrix components of the various constructs sampled at different implantation times. Elastin was also present but it was found only in constructs seeded with auricular chondrocytes. By 40 weeks of implantation, tissue-engineered cartilage of costal origin became calcified, marked by a notably high relative gene expression level of bone sialoprotein and the presence of rigid, nodular protrusions formed by mineralizing rudimentary cartilaginous growth plates. The collective data suggest that nasoseptal, articular, and auricular cartilages represent harvest sites suitable for development of tissue-engineered human ear models with retention over time of three-dimensional construct architecture, gene expression, and extracellular matrix composition comparable to normal, nonmineralizing cartilages. Calcification of constructs of costal chondrocyte origin clearly shows that chondrocytes from different tissue sources are not identical and retain distinct characteristics and that these specific cells are inappropriate for use in engineering a flexible ear model.
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