Polymerization of chondroitin sulfate and its stimulatory effect on cartilage regeneration; a bioactive material for cartilage regeneration

Chondroitin sulfate (CS) is one of the major glycosaminoglycans (GAGs). GAGs are linear polymers comprising disaccharide residues and are found as the side chains of proteoglycans. CS has significant stimulatory effects on cell behavior and is widely used in tissue-engineered and drug delivery devices. However, it is difficult to incorporate a sufficient amount of CS into biopolymer-based scaffolds such as collagen to take full advantage of its benefit. In this study, CS has been polymerized to an 11 times higher molecular weight polymer (PCS) in an attempt to overcome this deficiency. We have previously shown that PCS was significantly more effective than CS in chondrogenesis. This study aimed to characterize the physicochemical properties of the manufactured PCS. PCS was characterized by Fourier transform infra-red (FTIR) spectroscopy together with X-ray photoelectron spectroscopy (XPS) to obtain information about its chemical structure and elemental composition. Its molecular size was measured using dynamic light scattering (DLS) and its viscoelastic properties were determined by rheology measurements. The average PCS diameter increased 5 times by polymerization and PCS has significantly enhanced viscoelastic properties compared to CS. The molecular weight of PCS was calculated from the rheological experiment to give more than an order of magnitude increase over CS molecular weight. Based on these results, we believe there is a great potential for using PCS in regenerative medicine devices

A Bilayer Osteochondral Scaffold with Self‐Assembled Monomeric Collagen Type‐I, Type‐II, and Polymerized Chondroitin Sulfate Promotes Chondrogenic and Osteogenic Differentiation of Mesenchymal Stem Cells

Osteochondral (OC) injuries are suffered by over 40 million patients in Europe alone. Tissue-engineering approaches may provide a more promising alternative over current treatments by potentially eliminating the need for revision surgery and creating a long-term substitute. Herein, the goal is to capture the natural biological and mechanical properties of the joint by developing a bilayer scaffold that is novel in two ways: first, a biomimetic bottom-up approach is used to improve production precision and reduce immunogenicity; monomeric collagen type I and II are self-assembled to fibrils and then processed to 3D scaffolds. Second, to induce a tissue-specific response in mesenchymal stem cells (MSCs), polymerized chondroitin sulfate (PCS) is synthesized and grafted to collagen II and hydroxyapatite (HA) is added to collagen I. Incorporation of PCS into collagen II induces a chondrogenic response by upregulation of COL2A1 and ACAN expression, and incorporation of HA into collagen I stimulates osteogenesis and upregulates the expression of COL1A2 and RUNX2. It is remarkable that MSCs give rise to distinct behavior of chondrogenesis and osteogenesis in the two different regions of the bilayer scaffold. This hybrid scaffold of collagen II-PCS and collagen I-HA offers a great potential treatment for OC injuries

Characteristics and young's modulus of collagen fibrils from expanded skin using anisotropic controlled rate self-inflating tissue expander

Mechanical properties of expanded skin tissue are different from normal skin, which is dependent mainly on the structural and functional integrity of dermal collagen fibrils. In the present study, mechanical properties and surface topography of both expanded and nonexpanded skin collagen fibrils were evaluated. Anisotropic controlled rate self-inflating tissue expanders were placed beneath the skin of sheep's forelimbs. The tissue expanders gradually increased in height and reached equilibrium in 2 weeks. They were left in situ for another 2 weeks before explantation. Expanded and normal skin samples were surgically harvested from the sheep (n = 5). Young's modulus and surface topography of collagen fibrils were measured using an atomic force microscope. A surface topographic scan showed organized hierarchical structural levels: collagen molecules, fibrils and fibers. No significant difference was detected for the D-banding pattern: 63.5 ± 2.6 nm (normal skin) and 63.7 ± 2.7 nm (expanded skin). Fibrils from expanded tissues consisted of loosely packed collagen fibrils and the width of the fibrils was significantly narrower compared to those from normal skin: 153.9 ± 25.3 and 106.7 ± 28.5 nm, respectively. Young's modulus of the collagen fibrils in the expanded and normal skin was not statistically significant: 46.5 ± 19.4 and 35.2 ± 27.0 MPa, respectively. In conclusion, the anisotropic controlled rate self-inflating tissue expander produced a loosely packed collagen network and the fibrils exhibited similar D-banding characteristics as the control group in a sheep model. However, the fibrils from the expanded skin were significantly narrower. The stiffness of the fibrils from the expanded skin was higher but it was not statistically different

Hardness of Alumina/Silicon Carbide Nanocomposites at Various Silicon Carbide Volume Percentages

Presented at the 37th International Conference and Expo on Advanced Ceramics and Composites (ICACC'13), Daytona Beach, Florida.Vickers indentation was employed to measure the microhardness of monolithic alumina and six alumina-based nanocomposites consisting of variable silicon carbide nanoparticle volume percentages of 0.3% to 20%. Indentation tests were performed over a broad range of loads from 0.5N to 40N. The resultant hardness-load curves exhibit cumulative increases in the apparent hardness based on the silicon carbide content and reveal each sample suffers from a prominent indentation size effect (ISE). Herein, we present a comprehensive analysis of this data using Meyer’s Law, the proportional specimen resistance model (PSR) and the modified proportional specimen resistance model (MPSR) and employ TEM imagery to detail potential mechanisms by which silicon carbide nano-reinforcements influence the “true hardness” and the ISE

Factors affecting the wear behaviour of ceramics

In 2 volsSIGLEAvailable from British Library Document Supply Centre- DSC:D58636/86 / BLDSC - British Library Document Supply CentreGBUnited Kingdo