Tissue engineered ceramic artificial joint—ex vivo osteogenic differentiation of patient mesenchymal cells on total ankle joints for treatment of osteoarthritis

“…A variety of ceramic products have been clinically applied as biomaterials, and their advantages include high biocompatibility, in vivo stability, and superior mechanical characteristics compared to biomaterials such as synthetic polymers, resins, and metals [1][2][3][4][5][6][7][8][9][10][11][12][13]. Alumina ceramics are particularly effective as biomaterials owing to their high strength, resistance to wear, and smooth surface [6][7][8].…”

“…They are particularly useful in bone repair in orthopedic surgery, and have composed many products for socket or head of hip joint prostheses for more than 20 years [8]. In addition, these ceramic products have already been used clinically in the femoral components of knee joint prostheses and in ankle joint prostheses [9,10]. In other medical fields, ceramics are used as artificial bone to repair cranial and orbital bone defects and as dental and cochlear implants, among other uses [11][12][13][14][15].…”

Biocompatibility and Bone Tissue Compatibility of Alumina Ceramics Reinforced with Carbon Nanotubes

“…A variety of ceramic products have been clinically applied as biomaterials, and their advantages include high biocompatibility, in vivo stability, and superior mechanical characteristics compared to biomaterials such as synthetic polymers, resins, and metals [1][2][3][4][5][6][7][8][9][10][11][12][13]. Alumina ceramics are particularly effective as biomaterials owing to their high strength, resistance to wear, and smooth surface [6][7][8].…”

“…They are particularly useful in bone repair in orthopedic surgery, and have composed many products for socket or head of hip joint prostheses for more than 20 years [8]. In addition, these ceramic products have already been used clinically in the femoral components of knee joint prostheses and in ankle joint prostheses [9,10]. In other medical fields, ceramics are used as artificial bone to repair cranial and orbital bone defects and as dental and cochlear implants, among other uses [11][12][13][14][15].…”

Biocompatibility and Bone Tissue Compatibility of Alumina Ceramics Reinforced with Carbon Nanotubes

“…Also, several signalling molecules are known to be present in the clot; these include platelet-derived growth factor (PDGF) secondary to platelet degranulation. Similarly, Quarto et al (2001) 3 Tibia, ulna, humerus Critical size defect HA Good integration Warnke et al (2004) 1 Mandible Tumour Titanium, bone, BMP Good integration, bone formation Kitoh et al (2004) 3 Mandible Distraction CaCl and PRP Good bone formation Ohgushi et al (2005) 3 Ankle Ankle arthritis Alumina ceramic Good bone formation around arthroplasty 1 Mandible Distraction CaCl and PRP Union and good bone formation 1 Alveolar bone Cleft palate CaCl and PRP 79.1% more bone formation Morishita et al (2006) Warnke et al (2004) reconstructed the mandible of a patient after surgical removal using a titanium construct with incorporated BMP, bone blocks and bone marrow cells. The authors 'endocultivated' the whole construct in the latissimus dorsi of the patient before transfer to the defect area.…”

“…In addition, BMSCs have been used clinically to augment bone integration into artificial implants and thus decrease loosening. Ohgushi et al (2005) cultured BMSCs on ceramic ankle arthroplasty implants in three patients. Following implantation, the authors found good host bone-implant integration with high clinical scores.…”

Updates on stem cells and their applications in regenerative medicine

“…10 We have used human MSCs from the patient's bone marrow for treating various diseases centering on bone diseases since 2001. [11][12][13] MSCs and/or osteoblasts differentiated from MSCs have been transplanted into more than 80 patients.…”

Restoration of cellular function of mesenchymal stem cells from a hypophosphatasia patient