| Title | An improved collagen scaffold for skeletal regeneration |
| Publication Type | Journal Article |
| 2010 |
| Authors | Oliveira, SM, Ringshia, RA, Legeros, RZ, Clark, E, Yost, MJ, Terracio, L, Teixeira, CC |
| Journal | Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A |
| Volume | 94 |
| Issue | 2 |
| Pagination | 371 - 379 |
| Date Published | 2010/// |
| 15493296 (ISSN) |
| alkaline phosphatase, animal cell, animal tissue, Animals, article, Biocompatible Materials, Body fluids, Bone, Bone and Bones, Bone Regeneration, Cartilage, cartilage cell, Cattle, Cell culture, cell maturation, chick embryo, Chondrocytes, Collagen, collagen implant, collagen type 1, collagen type 10, Compressive Strength, controlled study, embryo, enchondral ossification, Endochondral ossification, extracellular matrix, freeze drying, Humans, immunohistochemistry, Ligaments, materials testing, Microscopy, Electron, Scanning, nonhuman, Phosphatases, protein cross linking, Protein Isoforms, retinoic acid, Scaffolds, Scanning electron microscopy, Stress, Mechanical, Tissue engineering, tissue scaffold, Type I collagen, Type X collagen, Ultraviolet radiation |
| Bone repair and regeneration is one of the most extensively studied areas in the field of tissue engineering. All of the current tissue engineering approaches to create bone focus on intramembranous ossification, ignoring the other mechanism of bone formation, endochondral ossification. We propose to create a transient cartilage template in vitro, which could serve as an intermediate for bone formation by the endochondral mechanism once implanted in vivo. The goals of the study are (1) to prepare and characterize type I collagen sponges as a scaffold for the cartilage template, and (2) to establish a method of culturing chondrocytes in type I collagen sponges and induce cell maturation. Collagen sponges were generated from a 1% solution of type I collagen using a freeze/dry technique followed by UV light crosslinking. Chondrocytes isolated from two locations in chick embryo sterna were cultured in these sponges and treated with retinoic acid to induce chondrocyte maturation and extracellular matrix deposition. Material strength testing as well as microscopic and biochemical analyzes were conducted to evaluate the properties of sponges and cell behavior during the culture period. We found that our collagen sponges presented improved stiffness and supported chondrocyte attachment and proliferation. Cells underwent maturation, depositing an abundant extracellular matrix throughout the scaffold, expressing high levels of type X collagen, type I collagen and alkaline phosphatase. These results demonstrate that we have created a transient cartilage template with potential to direct endochondral bone formation after implantation. © 2010 Wiley Periodicals, Inc. |
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