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ABSTRACT: The aim of this study was to perform an evaluation of a braided fiber scaffold for anterior cruciate ligament (ACL) reconstruction. The scaffold was composed of 50% type I collagen (Col-I) and 50% polyvinyl alcohol (PVA). First, the biocompatibility and in vitro weight loss of the scaffold were tested. Then, the scaffolds were used to reconstruct the ACL in China Bama mimi pigs. At 24 weeks post-operation, the mechanical properties and histology of the regenerated ACL were analyzed. The maximum load and tensile strength were 472.43± 15.2 N and 29.71± 0.96 MPa, respectively; both were ∼75% of those of native ACL and ∼90% of those of fiber scaffold. This indicated that the scaffold maintained a large portion of native ACL's mechanical properties, and tissue formation on the scaffold compensated most of the tensile strength loss caused by scaffold degradation. Histology and immunohistology analysis showed the morphology and major extracellular matrix components of the regenerated ligament resembled the native ACL. Thus, the Col-I/PVA blend fiber ACL scaffold showed good potential for clinical applications.
Biomedical Materials 03/2013; 8(3):035001. · 2.16 Impact Factor
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ABSTRACT: As the connecting tissue between the hyaline articular cartilage and the subchondral bone, calcified cartilage zone (CCZ) plays a great role in the force transmission and materials diffusion. However, the questions that remain to be resolved are its mineral composition and organization. In this study, 40 healthy human knee specimens were harvested; first the CCZ was dissected and observed by Safranin O/fast green staining, then CCZ chemical characteristics were measured by using amino acid assay and X-ray diffraction. The percentage of dry weight of type II collagen as an organic compound of CCZ was 20.16% ± 0.96%, lower than that of the hyaline cartilage layer (61.39% ± 0.38%); the percentage of dry weight of hydroxyapatite as an inorganic compound was 65.09% ± 2.31%, less than that of subchondral bone (85.78% ± 3.42%). Our study provides the accurate data for the reconstruction of the CCZ in vitro and the elucidation of CCZ structure and function.
International journal of medical sciences 01/2012; 9(5):353-60. · 2.24 Impact Factor
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ABSTRACT: Adult articular cartilage has a low regeneration capacity due to lack of viable progenitor cells caused by limited blood supply to cartilage. However, recent studies have demonstrated the existence of chondroprogenitor cells in articular cartilage. A critical question is whether these mesenchymal progenitor cells are functionally viable for tissue renewal and cartilage repair to postpone cartilage degeneration. This study was designed to compare the number and function of mesenchymal progenitor cells in articular cartilage collected from human fetuses, healthy adults (aged 28-45 years), and elderly adults (aged 60-75 years) and cultured in vitro. We detected multipotent mesenchymal progenitor cells, defined as CD105+/CD166+ cells, in human articular cartilage of all ages. However, mesenchymal progenitor cells accounted for 94.69%±2.31%, 4.85%±2.62%, and 6.33%±3.05% of cells in articular cartilage obtained from fetuses, adults, and elderly patients, respectively (P<.001). Furthermore, fetal mesenchymal progenitor cells had the highest rates of proliferation measured by cell doubling times and chondrogenic differentiation as compared to those from adult and elderly patients. In contrast, alkaline phosphatase levels, which are indicative of osteogenic differentiation, did not show significant reduction with aging. However, spontaneous osteogenic differentiation was detected only in mesenchymal progenitor cells from elderly patients (with lower Markin scales). The lower chondrogenic and spontaneous osteogenic differentiation of mesenchymal progenitor cells derived from elderly patients may be associated with the development of primary osteoarthritis. These results suggest that measuring cartilage mesenchymal progenitor cells may not only identify underlying mechanisms but also offer new diagnostic and therapeutic potential for patients with osteoarthritis.
Orthopedics 01/2011; 34(8):e382-8. · 2.66 Impact Factor
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ABSTRACT: The aim of this study was to carry out a histomorphometric analysis of calcified cartilage zone (CCZ) and its interfaces between hyaline cartilage and subchondral bone. The study used 40 donated normal human femoral condyles, from which paraffin-embedded sections were prepared after fixation and decalcification. The histomorphology of the CCZ were qualitatively and quantitatively observed by staining, scanning electron microscopy (SEM) and three-dimensional (3D) reconstruction. The hyaline cartilage and CCZ were stained red with Safranin-O, and the subchondral bone was stained blue with Fast green. CCZ was stained black after von Kossa staining. The hyaline cartilage was interlocked tightly in the manner of "ravine-engomphosis" by the CCZ. The surface roughnesses of tidemark and cement line were 1.14+/-0.04 and 1.99+/-0.38. The maximum, minimum and mean thicknesses of CCZ were 277.12+/-8.6, 9.83+/-6.72 and 104.162+/-0.87 microm, respectively. The cell density of CCZ (51.25+/-21.26 cells/mm(2)) was significantly lower than that of the hyaline cartilage (152.54+/-35.77 cells/mm(2)) (P<0.05). The subchondral bone was anchored tightly in the manner of a "comb-anchor" by the CCZ in our 3D reconstruction model. Thus, we discovered two junctional interfaces of CCZ using different histomorphometric methods. The upper interface of CCZ is a "ravine-engomphosis" shape, while its lower interface is a "comb-anchor" shape.
Journal of Structural Biology 08/2009; 168(3):359-65. · 3.41 Impact Factor
