Blood exposure has a negative effect on engineered cartilage.

PURPOSE: The aim of this study was to investigate the in vitro effect of different concentrations of blood on the morphological and biochemical properties of engineered cartilage. Previous studies have demonstrated a negative effect of blood on native cartilage; however, the effect of the contact of blood on engineered cartilage is unclear. METHODS: Articular chondrocytes were isolated from swine joints, expanded in monolayer culture, and seeded onto collagen membranes. The seeded membranes were cultured for 3 days in the presence of different concentrations of peripheral blood. Some samples were retrieved at the end of the blood contact, others after 21 additional days of standard culture conditions, in order to investigate the "long-term effect" of the blood contact. RESULTS: All seeded samples showed an increase in the weight and an evident cartilage-like matrix production. A concentration-dependent reduction in the mitochondrial activity due to blood contact was shown at the earlier culture time, followed by a partial recover at the longer culture time. CONCLUSION: A blood contact of 3 days affected the chondrocytes' activity and determined a delay in the maturation of the engineered cartilage. These findings have clinical relevance, as autologous chondrocytes seeded onto biological scaffolds has become an established surgical method for articular cartilage repair. Therefore, further investigation into material sciences should be encouraged for the development of scaffold protecting the reparative cells from the blood insult.

A tissue engineered osteochondral plug: an in vitro morphological evaluation.

Articular cartilage lesions have a poor intrinsic healing potential. The repair tissue is often fibrous, having insufficient biomechanical properties, which could frequently lead to the development of early osteoarthritis. In the last decade, tissue engineering approaches addressed this topic in order to restore joint function with a differentiated and functional tissue. Many biomaterials and techniques have been proposed and some of them applied in clinical practice, even though several concerns have been raised on the quality of the engineered tissue and on its integration in the host joint. In this study, we focused on engineering in vitro a biphasic composite made of cellular fibrin glue and a calcium-phosphate scaffold. Biphasic composites are the latest products of tissue engineering applied to articular cartilage and they seem to allow a more efficient integration of the engineered tissue with the host. However, a firm in vitro bonding between the two components of the composite is a necessary condition to validate this model. Our study demonstrated a gross and microscopic integration of the two components and a cartilage-like quality of the newly formed matrix. Moreover, we noticed an improvement of this integration and GAGs production during the in vitro culture.

Effect of blood on the morphological, biochemical and biomechanical properties of engineered cartilage.

The use of autologous chondrocytes seeded onto a biological scaffold represents a current valid tool for cartilage repair. However, the effect of the contact of blood to the engineered construct is unknown. The aim of this work was to investigate in vitro the effect of blood on the morphological, biochemical and biomechanical properties of engineered cartilage. Articular chondrocytes were enzymatically isolated from swine joints, expanded in monolayer culture and seeded onto collagen membranes for 2 weeks. Then, the seeded membranes were placed for 3 days in contact with peripheral blood, which was obtained from animals of the same species and diluted with a standard medium. As controls, some samples were left in the standard medium. After the 3 days' contact, some samples were retrieved for analysis; others were returned to standard culture conditions for 21 additional days, in order to investigate the "long-term effect" of the blood contact. Upon retrieval, all seeded samples showed increasing sizes and weights over time. However, the samples exposed to blood presented lower values with respect to the controls. Biochemical evaluation demonstrated a reduction in the mitochondrial activity due to blood contact at the early culture time (3 days post blood contact), followed by a partial recovery at the longer culture time (21 days post blood contact). Histological evaluation demonstrated evident cartilage-like matrix production for both groups. Biomechanical data showed a reduction of the values, followed by stabilization, regardless of the presence of blood. Based on the data obtained in this study, we can conclude that blood contact affects the chondrocyte activity and determines a delay in the dimensional growth of the engineered cartilage; however, at the experimental times utilized in this study, this delay did not affect the histological pattern and the biomechanical properties of the construct.

Cell-based tissue-engineered allogeneic implant for cartilage repair.

The potential for using of allogeneic cartilage chips, transplanted in a biologic polymer with articular chondrocytes, as a tool for articular cartilage repair was studied. Small lyophilized articular cartilage chips were mixed with a cell/fibrinogen solution and thrombin to obtain implantable constructs made of fibrin glue, chondrocytes, and cartilage chips. Specimens were implanted in the subcutaneous tissue on the backs of nude mice (experimental group A). Three groups of controls (groups B, C, and D) were also prepared. Group B consisted of fibrin glue and cartilage chips without chondrocytes. Group C consisted of fibrin glue and chondrocytes without cartilage chips, and group D was composed solely of fibrin glue. All samples were carefully weighed before implantation in the mice. The constructs were harvested from the animals at 6, 9, and 12 weeks, examined grossly, and weighed. The samples were then processed and stained with hematoxylin and eosin for histological examination. Gross evaluation and weight analysis of the constructs at the time of retrieval showed retention of the original mass in the samples made of fibrin glue, chondrocytes, and cartilage chips (group A) and demonstrated a cartilaginous consistency upon probing. Specimens from constructs of fibrin glue and cartilage chips without chondrocytes (control group B) retained most of their volume, but were statistically lighter than specimens from group A and were much softer and more pliable than those in group A. Samples of specimens from constructs of fibrin glue and chondrocytes (groups C) and fibrin glue alone (group D) both showed a substantial reduction of their original masses over the experimental time periods when compared to the samples in groups A and B, although specimens from group C demonstrated new cartilage matrix formation. Histological analysis of specimens in experimental group A demonstrated the presence of cartilage chips surrounded by newly formed cartilaginous matrix, while specimens of control group B showed only fibrotic tissue surrounding the devitalized cartilage pieces. Cartilaginous matrix was also observed in control group C, in which cartilage chips were absent, whereas only fibrin glue debris was observed in control group D. This study demonstrated that a composite of fibrin glue and devitalized cartilage can serve as a scaffold for chondrocyte transplantation, preserve the original phenotype of the chondrocytes, and maintain the original mass of the implant. This may represent a valid option for addressing the problem of articular cartilage repair.