Bone marrow-derived mesenchymal stromal stem cells (BMSCs) are a promising cell source for treating articular cartilage defects. Quality of cartilaginous repair tissue following BMSC transplantation has been shown to correlate with functional outcome. Therefore, tissue-engineering variables, such as cell expansion environment and seeding density of scaffolds, are currently under investigation. The objectives of this study were to demonstrate chondrogenic differentiation of BMSCs seeded within a collagen I scaffold following isolation and expansion in two-dimensional (2D) and three-dimensional (3D) environments, and assess the impact of seeding density on in vitro chondrogenesis. It was hypothesised that both expansion protocols would produce BMSCs capable of hyaline-like chondrogenesis with an optimal seeding density of 10 million cells/cm3.

Ovine BMSCs were isolated in a 2D environment by plastic adherence, expanded to passage two in flasks containing expansion medium, and seeded within collagen I scaffolds (6 mm diameter, 3.5 mm thickness and 0.115 ± 0.020 mm pore size; Integra LifeSciences Corp.) at densities of 50, 10, 5, 1, and 0.5 million BMSCs/cm3. For 3D isolation and expansion, bone marrow aspirates containing known quantities of mononucleated cells (BMNCs) were seeded on scaffolds at 50, 10, 5, 1, and 0.5 million BMNCs/cm3 and cultured in expansion medium for an equivalent duration to 2D expansion. All cell-scaffold constructs were differentiated in vitro in chondrogenic medium containing transforming growth factor-beta three for 21 days and assessed with RT-qPCR, safranin O staining, histological scoring using the Bern Score, collagen immunofluorescence, and glycosaminoglycan (GAG) quantification.

Two dimensional-expanded BMSCs seeded at all densities were capable of proteoglycan production and displayed increased expressions of aggrecan and collagen II mRNA relative to pre-differentiation controls. Collagen II deposition was apparent in scaffolds seeded at 0.5–10 million BMSCs/cm3. Chondrogenesis of 2D-expanded BMSCs was most pronounced in scaffolds seeded at 5–10 million BMSCs/cm3 based on aggrecan and collagen II mRNA, safranin O staining, Bern Score, total GAG, and GAG/DNA. For 3D-expanded BMSC-seeded scaffolds, increased aggrecan and collagen II mRNA expressions relative to controls were noted with all densities. Proteoglycan deposition was present in scaffolds seeded at 0.5–50 million BMNCs/cm3, while collagen II deposition occurred in scaffolds seeded at 10–50 million BMNCs/cm3. The highest levels of aggrecan and collagen II mRNA, Bern Score, total GAG, and GAG/DNA occurred with seeding at 50 million BMNCs/cm3.

Within a collagen I scaffold, 2D- and 3D-expanded BMSCs are capable of hyaline-like chondrogenesis with optimal cell seeding densities of 5–10 million BMSCs/cm3 and 50 million BMNCs/cm3, respectively. Accordingly, these densities could be considered when seeding collagen I scaffolds in BMSC transplantation protocols.

Purpose

Traumatic articular cartilage (AC) defects are common in young adults and frequently progresses to osteoarthritis. Matrix-Induced Autologous Chondrocyte Implantation (MACI) is a recent advancement in cartilage resurfacing techniques and is a variant of ACI, which is considered by some surgeons to be the gold standard in AC regeneration. MACI involves embedding cultured chondrocytes into a scaffold that is then surgically implanted into an AC defect. Unfortunately, chondrocytes cultured in a normoxic environment (conventional technique) tend to de-differentiate resulting in decreased collagen II and increased collagen I producing in a fibrocartilagous repair tissue that is biomechanically inferior to AC and incapable of withstanding physiologic loads over prolonged periods. The optimum conditions for maintenance of chondrocyte phenotype remain elusive. Normal oxygen tension within AC is <7%. We hypothesized that hypoxic conditions would induce gene expression and matrix production that more closely characterizes normal articular chondrocytes than that achieved under normoxic conditions when chondrocytes are cultured in a collagen scaffold.

Purpose

The biomechanical role of the meniscus in the knee joint is a function of its extracellular matrix which consists of type I collagen throughout, type II collagen in the inner meniscus region and glycosaminoglynated (GAG) proteins of which aggrecan is the most prevaleet. Meniscus reparative capacity is limited, particularly when a defect is located in the inner avascular portion, and menisectomy predisposes the joint to osteoarthritis. Using meniscus cells in tissue engineering strategies has been advocated to generate functional meniscus substitutes. However, meniscus cells, like chondrocytes of cartilage, lose their matrix-forming phenotype during culture expansion. Co-culture of chondrocytes with stem cells has been shown to result in enhanced matrix formation. We hypothesized that meniscus cells in co-culture with stem cells will result in increased matrix formation.

Purpose

Bone marrow multi-potent stromal cells represent a heterogenous source of cells with great promise in joint cartilage regenerative medicine. However, due to their low numbers upon harvesting, MSCs need to be expanded without compromising their capacity to form chondrocytes (cartilage cells). To date there is no consensus on how to expand MSCs in order to maximize their potential for cartilage repair and nor are there any specific cell signatures of MSCs with chondrogenic propensity. Emerging evidence suggest that marrow stem cells exist in a hypoxic microenvironment. On this basis and in addition to cartilages natural existence in hypoxic environment (1–7% O2), we hypothesized that MSC expansion under hypoxia will result in the enrichment of MSCs with predilection to chondrocytes compared to expansion under the conventional culture conditions of 21% O2.