Abstract
In the context of an aging population, unhealthy Western lifestyle, and the lack of an optimal surgical treatment, deep osteochondral defects pose a great challenge for the public health system. Biodegradable, biomimetic scaffolds seem to be a promising solution. In this study we investigated the biocompatibility of porous poly-((D,L)-lactide-ε-caprolactone)dimethacrylate (LCM) scaffolds in contrast to compact LCM scaffolds and blank cell culture plastic. Thus, morphology, cytotoxicity and metabolic activity of human mesenchymal stromal cells (MSC) seeded directly on the materials were analyzed after three and six days of culturing. Further, osteoclastogenesis and osteoclastic activity were assessed using reverse-transcriptase real-time PCR of osteoclast-specific genes, EIA and morphologic aspects after four, eight, and twelve days. LCM scaffolds did not display cytotoxic effects on MSC. After three days, metabolic activity of MSC was enhanced on 3D porous scaffolds (PS) compared to 2D compact scaffolds (CS). Osteoclast activity seemed to be reduced at PS compared to cell culture plastic at all time points, while no differences in osteoclastogenesis were detectable between the materials. These results indicate a good cytocompatibility of LCM scaffolds. Interestingly, porous 3D structure induced higher metabolic activity of MSC as well as reduced osteoclast activity.
Highlights
Deep osteochondral defects represent an increasing worldwide public health problem caused by the aging population, unhealthy lifestyles, and sport injuries
Osteoclast activity seemed to be reduced at porous scaffolds (PS) compared to cell culture plastic at all time points, while no differences in osteoclastogenesis were detectable between the materials
A significantly better viability was measured for mesenchymal stromal cells (MSC) growing on porous scaffolds compared to compact scaffolds (p = 0.043)
Summary
Deep osteochondral defects represent an increasing worldwide public health problem caused by the aging population, unhealthy lifestyles, and sport injuries. They impair the public health system as well as the life quality of patients due to deteriorated joint function and pain. Progress in the field of 3D biomaterial generation allows the production of biphasic porous scaffolds that mimics the cartilage, tide zone, and subchondral bone. These biomimetic biphasic porous scaffolds should hold unlimited availability and personalized size adaption [3] capability [4]. One aim of present study was to analyze the cellular compatibility of new designed 3D implants
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