Humans ; Liver Transplantation ; methods ; Tissue Donors

Adipose Tissue ; transplantation ; Humans ; Mammaplasty ; methods ; Safety ; Transplantation, Autologous

The field of tissue engineering has made steady progress in translating various tissue applications. Although the classical tissue engineering strategy, which involves the use of culture-expanded cells and scaffolds to produce a tissue construct for implantation, has been validated, this approach involves extensive cell expansion steps, requiring a lot of time and laborious effort before implantation. To bypass this ex vivo process, a new approach has been introduced. In situ tissue regeneration utilizes the body's own regenerating capacity by mobilizing host endogenous stem cells or tissue-specific progenitor cells to the site of injury. This approach relies on development of a target-specific biomaterial scaffolding system that can effectively control the host microenvironment and mobilize host stem/progenitor cells to target tissues. An appropriate microenvironment provided by implanted scaffolds would facilitate recruitment of host cells that can be guided to regenerating structural and functional tissues.
Animals ; Guided Tissue Regeneration/*methods ; Humans ; Stem Cell Transplantation/*methods ; Stem Cells/*cytology/metabolism ; Tissue Engineering/methods ; Tissue Scaffolds

OBJECTIVETo explore suitable scaffold material for big segmental long bone defect by studying the properties of the prepared deproteinized bone.

METHODSCancellated bone were made as 30 mm x mm x 3 mm bone blocks from inferior extremity of pig femur along bone trabecula. The deproteinized bone was prepared with an improved method. Their morphological features, components, cell compatibility, mechanical and immunological properties were investigated respectively.

RESULTSDeproteinized bone maintained natural reticular pore system. The main organic material is collagen I and inorganic composition is hydroxyapatite. It has good mechanical properties, cell adhesion rate and histocompatibility.

CONCLUSIONThis deproteinized bone can be applicable as scaffold for reparation of big segmental defect in long bone.

Animals ; Bone Regeneration ; physiology ; Bone Transplantation ; methods ; Collagen ; Hydroxyapatites ; Swine ; Tissue Engineering ; methods ; Tissue Scaffolds

Liver transplantation is the only way to treat end-stage liver disease. In order to overcome the shortage of donor, marginal donors have been used widely, which bring about a series of problems. Machine perfusion can stimulate the circulation in vivo and is beneficial for the protection of liver. It could also improve the graft function and reduce postoperative complications, which makes it a hot spot in recent years. The aim of this study is to summarize the current status and prospects of application of machine perfusion on clinical liver transplantation.
Humans ; Liver ; Liver Transplantation ; Perfusion ; instrumentation ; methods ; Tissue Donors

Cryopreservation is essential for the long-term storage and banking of cartilage grafts. This paper reviews the developments on the cryopreservation of cartilage and transplantation of cryopreserved cartilage grafts during the past 10 years. It is stated that the current technologies for cryopreservation of cartilage grafts are not mature. Further systematic studies are necessary.
Animals ; Cartilage ; transplantation ; Cryopreservation ; Humans ; Tissue Preservation ; methods

Artificial dermis is a kind of tissue engineering dermal substitute and is used to repair dermal defects caused by a variety of reasons. This article describes the characteristics and the mechanism of repair and reconstruction of bilayer artificial dermis. Based on domestic experience of clinical applications and relative literature of bilayer artificial dermis, more than 50 domestic experts in related field reached a consensus on indications, contraindications, operation procedures in clinical application, cautions, and treatment and prevention of complications of bilayer artificial dermis, providing reference for clinical application.
Consensus ; Dermis ; pathology ; Skin Transplantation ; methods ; Skin, Artificial ; Tissue Engineering

Articular cartilage damage is very common in clinical practices. Due to the low self healing abilities of articular cartilage, it must be repaired or substituted by implants once natural articular cartilage is damaged. On the other hand, the various technologies currently used for healing damaged articular cartilage are little satisfactory, and rarely restore full function or return the tissue to its natively normal state. Tissue engineering technology holds great promise for the healing of damage or defects of articular cartilage. Tissue engineered articular cartilage is one of the most promising methods for repairing articular cartilage trauma and defects. In this paper, the authors review the research progress of three elements such as seed cells, growth factors and scaffolds which constitute tissue engineered articular cartilage.
Animals ; Cartilage, Articular ; injuries ; surgery ; Chondrocytes ; transplantation ; Humans ; Mesenchymal Stem Cell Transplantation ; methods ; Osteoblasts ; cytology ; Tissue Engineering ; methods ; Tissue Scaffolds

It has been extensively confirmed that fetal ventral mesencephalic cell (VMC) transplantation can ameliorate the symptoms of Parkinson's disease (PD). But there are still several problems to be resolved before the extensive clinical application of this technology. The major limitations are the poor survival of grafted dopamine (DA) neurons and restricted dopaminergic reinnervation of host striatum. Some attempts have been made to solve these problems including use of some trophic factor and co-transplantation with neural/paraneural origins. The purpose of this review is to overview advances of the means improving the survival of grafts and their current limitations.
Animals ; Brain Tissue Transplantation ; methods ; Fetal Stem Cells ; transplantation ; Fetal Tissue Transplantation ; methods ; Graft Survival ; Humans ; Mesencephalon ; embryology ; transplantation ; Parkinson Disease ; therapy

OBJECTIVETo investigate the feasibility of using marrow stromal osteoblast (MSO) as bone derived cell and using cancellous bone matrix (CBM) as scaffold for bone tissue engineering, the subcutaneous osteogenesis of MSO-CBM compound artificial bone (MCCAB) was observed in the experiment.

METHODSThe marrow stromal cells of adult New Zealand rabbits cultivated and induced in vitro were used to form MCCAB by mixing, seeding and solidifying methods assisted by alginate. The MCCABs were auto-transplanted subcutaneously into the rabbits for 4 to 8 weeks. The alginate-cancellous bone matrix composites or the cancellous bone matrix alone were implanted as control. The effectiveness of bone formation was assessed by means of roentgenography, histology and computerized histomorphometry.

RESULTSThe osteogenesis of MCCABs was better than that of the alginate-cancellous bone matrix composites and of the cancellous bone matrixes. In the MCCABs, both intramembranous and cartilaginous osteogeneses were seen but the former was obvious. In the control, only slight cartilaginous osteogeneses were seen.

CONCLUSIONSThe osteogeneses of the MCCABs constructed by using tissue engineering method were obvious when transplanted subcutaneously. The MSO and CBM can be used as good bone-derived cell and scaffold material respectively for tissue-engineered bone construction.

Animals ; Bone Marrow Transplantation ; Bone Matrix ; transplantation ; Bone Transplantation ; methods ; Male ; Osteoblasts ; transplantation ; Osteogenesis ; Rabbits ; Tissue Engineering