Polyglycolide (PGA)/poly(lactide-co-glycolide) (PLGA) scaffolds were fabricated by a solvent casting/particulate leaching method using hexafluoroisopropanol (HFIP) or acetone for material dissolution and NaCl particles as porogen. The results revealed that the mechanical strength increased as the PGA percentage in a HFIP-processed scaffold increased. Chemical ingredients did not substantially affect the mechanical strength of acetone-processed scaffolds. Large NaCl particles led to weak mechanical strength, low porosity, and small specific surface area. For a fixed composition, PGA crystals in a HFIP-processed scaffold were smaller than those in an acetone-processed scaffold. High PGA fractions yielded partly fused PGA/PLGA scaffolds. A faster degradation rate of a scaffold could result from a higher PGA percentage, smaller NaCl particles, or the existence of chondrocytes. The combination of PGA and PLGA, which compensated each other for bioactivity, would be beneficial to cartilage regeneration.
Polyglycolide (PGA)/poly(lactide-co-glycolide) (PLGA) scaffolds were fabricated by a solvent casting/particulate leaching method using hexafluoroisopropanol (HFIP) or acetone for material dissolution and NaCl particles as porogen. The results revealed that the mechanical strength increased as the PGA percentage in a HFIP-processed scaffold increased. Chemical ingredients did not substantially affect the mechanical strength of acetone-processed scaffolds. Large NaCl particles led to weak mechanical strength, low porosity, and small specific surface area. For a fixed composition, PGA crystals in a HFIP-processed scaffold were smaller than those in an acetone-processed scaffold. High PGA fractions yielded partly fused PGA/PLGA scaffolds. A faster degradation rate of a scaffold could result from a higher PGA percentage, smaller NaCl particles, or the existence of chondrocytes. The combination of PGA and PLGA, which compensated each other for bioactivity, would be beneficial to cartilage regeneration.
This study analyzes the effects of pituitary extract supplement on the cultivation of bovine knee chondrocytes (BKCs) in three‐dimensional chitin/chitosan biomaterials. Transforming growth factor‐β1 (TGF‐β1) in the supplement was identified by Western blot near 23 kDa, and the immunoassayed concentration of TGF‐β1 in the supplement was about 33 ng/mL. The typical pore diameter of the chitin/chitosan scaffolds was 250 μm, indicating an apposite void space for chondrocyte growth. The characteristic width of needlelike hydroxyapatite crystals was 85 nm after chemical co‐precipitation of hydroxyapatite on the pore surfaces of the scaffolds. Over 4‐wk cultivation, the amounts of proliferated BKCs, secreted glycosaminoglycans and produced collagen were improved with the concentration of TGF‐β1 in culture medium. In addition, the cultivated constructs revealed mature neocartilage with lacunas enclosing BKCs, demonstrating chondrogenesis. Pituitary extract supplement was more efficient in the synthesis of extracellular matrix than pure TGF‐β1. Hence, an appropriate addition of the supplement can enhance the formation of cartilaginous components in the scaffolds to regenerate articular cartilage.
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