Narrow Results

Cartilage defects remain one of the most challenging musculoskeletal tissues to treat owing to its poor healing capacity. The lack of sufficient clinical treatments has led to a drive in tissue engineering advancements that combine chondrogenic cells with scaffolds to aid in cartilage regeneration. Nanoscale materials are commonly used in scaffold synthesis because of their ability to mimic the size of extracellular matrix (ECM). This review focuses on the use of nanostructured scaffolds in combination with cells for cartilage tissue engineering. We detail the fabrication methods and materials used to produce nanostructured scaffolds, with a focus on nanofibers and their role in modulating cell biology. Lastly, we discuss various techniques that further functionalize the nanostructured scaffolds to enhance cellular responses.

Polyhedral oligomeric silsesquioxane (POSS) based nanocompounds have recently emerged as viable compounds to make totally synthetic biocompatible tissue substitutes for use in the clinical arena. Here, we report on the use of three POSS based compounds to develop bionanohybrid scaffolds composed primarily of purified Type II collagen. The bionanohybrid scaffolds were prepared by blending purified Type II collagen with octa maleamic acid POSS, octa ammonium POSS, or polyethylene glycol POSS. We were able to differentially detect the presence of the different POSS compounds in the bionanohybrid scaffolds using attenuated total reflectance Fourier transformed infrared (ATR-FTIR) spectroscopy. The differential scanning calorimetry (DSC) characterized the effect of the hydrophilic POSS additives on the thermal behavior of the bionanohybrid scaffolds. Next, scanning electron microscopy revealed that different POSS compounds enhanced, refined, or altered the three-dimensional scaffold microstructure. Finally, by using these scaffolds to create three-dimensional tissue constructs, we measured the ability of human foreskin fibroblasts to migrate out and proliferate into the biomaterials. Our data suggest that POSS can be incorporated with native polymeric structural proteins to influence biomaterial architecture where cells can migrate and proliferate.