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Immature articular cartilage is an adequate support to initiate morphological, structural and biomolecular changes1 in order to obtain an adult joint-specific function. The principal change is reorganization of collagen fibrils from one displaying a parallel orientation with respect to the surface in immature cartilage to one where fibrils deeper in the tissue are perpendicular in mature cartilage. Pseudo-stratification of adult cartilage is evident through the reorganization of resident chondrocytes along the direction of collagen fibril orientation with cells at the surface disc-like and parallel to the surface and in the deeper zones cells becoming progressively larger and organized in columns. Post-natal maturation is known to occur over many months and is essentially completed at the end of puberty, the long timescale was thought to make studying this important developmental transition at best difficult or technically impossible to study in detail2. Some advances into the solution to this problem have been made through the finding that fibroblast growth factor-2 and transforming growth factor-β1 together are able to induce important physiological and morphological changes that replicate articular cartilage maturation2,3 (Figure 1). Growth factor-induced in vitro maturation occurs within three weeks and does not require any biomechanical input. After culture, collagen type II expression is significantly reduced and the ratio of mature trivalent to immature divalent collagen crosslinks increases as is seen in maturing cartilage. Also, the organization of the extracellular matrix and collagen fibrils is closer to that seen in mature cartilage though this facet of transition is not complete. Biochemically, the composition of growth factor-treated cartilage is mimicking an adult articular cartilage3.
The model used in the article is based on an in vitro culture of 4- or 6-mm diameter explants that were excised under sterile conditions from the lateral aspect of the metacarpophalangeal joint medial condyle from immature male (7 days-old) bovine steers. A thin layer of calcified cartilage and subchondral bone was kept on the basal aspect of each explant. The articular cartilage were cultured in a classical serum-free medium Dulbecco's modified Eagles medium (high glucose 4.5 g/L) in which insulin-transferrin-selenium (ITS), 10 mM HEPES buffer pH 7.4, ascorbic acid and 50 µg/mL gentamicin were added. This culture medium is supplemented with 100 ng/mL fibroblast growth factor 2 (FGF-2) and 10 ng/mL transforming growth factor β1 (TGF-β1) that are replenished every third day with media changes2. Highly accelerated cartilage maturation is induced by combining growth factors. These changes occur within 21 days. Growth factor stimulation additionally induces apoptosis and resorption from the basal aspect and cellular proliferation in surface chondrocytes3. The culture medium composition is described in Table 1. Following the model developed by Khan et al. 20112, articular cartilage explants are cultured with TGF-β1 at a concentration of 10 ng/µL and FGF2 at 100 ng/µL concentration (stock concentrations 10 μg/mL and 100 μg/mL dissolved in phosphate buffered saline/0.1% BSA). 1 µL of each growth factor is used per 1 mL of the medium. DMEM-F12 with L- glutamine and high glucose is an artificial medium which, once supplemented with insulin, transferrin and selenium (ITS), ascorbic acid, gentamicin and HEPES provides a complete medium supplementation with all the physiological growth requirements specific to the different cell lines and explants cultures. DMEM-F12 is composed of several diverse inorganic salts (i.e., NaCl, KCl, CaCl2, MgCl2, NaH2PO4), glucose, amino acids (nitrogen sources), vitamins, co-factors and water. Those salts provide adequate energetic inputs to sustain the cellular survival and normal growth in culture. The mineral ions contribute to maintaining the osmolarity close to the natural physiological environment. The higher concentration of glucose (4.5 g/L) is used as chondrocytes respire primarily through glycolysis. F12 medium supplementation is used because it offers number of sources of sulfate, CuSO4, FeSO4, ZnSO4 and MgSO4 required for sulfated glycosaminoglycan synthesis. As checked by colored indicators (here phenol red) and CO2/HCO-3 buffer combined with phosphates, the pH remains constant at a value close to 7.4. The major respiratory pathway used by chondrocytes is glycolysis where lactic acid is the end product which causes an increase in pH, therefore, in the absence of biomechanical forces that would help to remove locally produced lactic acid, HEPES acts to maintain a buffered environment for physiological processes. Gentamicin is an aminoglycoside antibiotic controls external bacterial contamination through inhibition of growth. Ascorbic acid is used as medium complement for its anti-oxidant action4. Ascorbic acid is a co-factor for enzymes, prolyl hydroxylases, that function to hydroxylate proline residues in collagen stabilizing its triple helical structure. The transferrin usually serves as extracellular antioxidant (toxicity and ROS reductions)5,6. It is also added to the culture medium for its ability to provide and facilitate extracellular iron storage and transport in cell culture. Transferrin binds iron so tightly under physiological conditions that virtually no free iron exists to catalyze the production of free radicals7. The insulin hormone signaling from its bound receptor increases the absorption of several elements such as glucose, amino acids. It is also involved in several processes such as intracellular transport, lipogenesis, protein, and nucleic acid syntheses. Insulin has a growth-promoting effect. Selenium is present additionally in the composite solution “insulin-transferrin-selenium”, as sodium selenite. It is mainly used as a cofactor for (seleno-) proteins such gluthatione peroxidase (GPX), as supplementary antioxidant agent in the culture. In in vitro articular chondrocytes, ITS seems to enhance cellular proliferation and phenotype preservation by inhibiting the gene expression related to cellular dedifferentiation and hypertrophic differentiation8. Growth factors like fibroblast growth factor-2 and transforming growth factor-β1 are added to the culture medium. They are used to induce and regulate cell differentiation, growth, healing, and development2,3. FGF-2 and TGF-β1 in combination also potently promote cellular proliferation in cultured cells and tissues9.
This in vitro maturation model of articular cartilage is useful for three main reasons. First, the accelerated developmental phase transition in this model allows us to study imperceptible changes that occur over many months in in vivo models such as the elevated expression of lysl oxidase-L1 during maturation10. Secondly, tissue engineering of articular cartilage suffers from the fact that cartilage with an isotropic morphology and structure is produced which is functionally deficient when transplanted into joints to repair focal defects. Understanding how to induce maturational changes will accelerate the development of fully functional implantable devices. Thirdly and pertinent to this study, there are degenerative joint conditions such as Kashin-Beck disease occurring during childhood that lead to severe joint deformities in adulthood. This particular disease is strongly associated to geographic areas (China) with endemic deficiencies in selenium and iodine potentially affecting tens of millions of inhabitants11,12,13. Examination of skeletal defects in Kashin-Beck disease show that it occurs peri-pubertally, implicating perturbation of skeletal maturational processes. Therefore, to further understand the role of selenium in articular cartilage (AC) a robust model for cartilage growth and development is required. An in vitro growth factor-induced model of maturation provides a useful starting point for studies on the growth and metabolism of articular cartilage during maturation in presence or absence of selenium ions14,15,16. Our knowledge of the effects of selenium (Se) deficiency on complex and inter-related biological processes remains very poor. The main problem lies in the fact that selenium remains an element to study due to its restrictive action range (required concentration between 40 and 400 µg/kg17) and the very low concentration involved. The accelerated maturation model using immature bovine cartilage offers an unprecedented ability to look at biological changes that occur during an important phase of development. The Se-concentration in organisms is tightly controlled, and this model is a starting point to develop imaging techniques allowing its precise tracking during maturation. These techniques could then be a powerful tool to study strategies to prevent AC degradation and potentially to develop the basis of novel regenerative medicine-based therapies.
Simultaneous visualization of soft tissue, cartilage and bone changes is a major challenge in conventional preclinical imaging modalities. This would be indeed an important help for joint disease follow-up18,19 . As an example, conventional X-ray micro Computed Tomography (µCT) presents poor performances for soft tissue that limit its use to the depiction of bone defects, osteophytes, and indirect visualization of cartilage. Magnetic Resonance Imaging (MRI), on the other hand, is conventionally employed for soft tissue imaging despite its poor ability to precisely render changes in the bone (e.g., micro-calcifications) during initial stages of diseases. The ability to be sensitive to bones and cartilages, and to distinguish the constitutive cells of cartilage, chondrocytes is of tremendous importance. Phase Contrast Imaging (PCI) relies on the property that the X-rays refraction index of materials can be a thousand times greater than the absorption index for light elements. This generates a higher contrast for soft tissues in comparison to the conventional methods based on the sole absorption. Therefore, PCI is able to image all the tissues that constitute the joint having concurrent representation of both high absorbing (e.g., bones) and less absorbing tissues (e.g., fibrous cartilage, ligaments, tendons, meniscus and associated soft tissues (synovial membranes and muscle))18,19,20,21.
As demonstrated in ref.20, X-ray PCI outperforms the other preclinical imaging modalities for cartilage. The purpose of this protocol is to detail the procedure and to show some representative results. Scheme of the effect of growth factors on immature cartilage explant is shown in Figure 1.