Objective To review the basic researches and the cl inical appl ication of the nano-neural tissue engineering materials, especially the electrically conductive carbon nanotubes (CNT). Methods The l iterature concerning the basic and cl inical researches of the conductive materials of nano-neural tissue engineering, especially the electrically conductive CNT were reviewed. Results The researches of conductive materials of nano-neural tissue engineering have made some progress, the electrically conductive CNT can not only promote Schwan cells’ adhension, migration, and prol iferation, but also mimic the function of electric conductivity of neural myel in and enhance neurite growth and regeneration. So the electrically conductive CNT make great sense in stimulating and directing the growth of neurite and the regeneration of axons. Conclusion Because of these unique properties, the electrically conductive CNT have great advantages in peripheral nerve repair and function reconstruction, and are promising to provide a novel method for cl inical peri pheral nerve repair and function reconstruction after injury.
Objective To explore the method of fabricating freeze-dried demineralized bone matrix with nanoscale topography (nFDBM) and to investigate the feasibility of reconstruction of tissueengineered bone with the novel scaffold. Methods Allogenic dogs’ phalangeal cortical bone was fabricatedinto freeze-dried demineralized bone (FDBM) with modified Urist’s method. FDBM was subjected toNd∶YAG laser irradiation under special conditions. The surface topography was identified by atomic force microscope(AFM) and scanning electron microscope (SEM). The osteoblasts were induced from autologous mesenchymal stem cells (MSCs) and mixed with nFDBM and FDBM in vitro.The effects of the different topography oncellbehavior was identified by SEM. The complex of nFDBM and osteoblasts wereimplanted into fascial bags on dogs’ back (experimental group A) and dogs’ phalangeal defects on right (experimental group C), while FDBMosteoblast complex (control group B) and unique FDBM (control group D) were implanted into the corresponding sites on left as control groups. The osteogenic status was assessed by X-ray, HE and SEM at 4, 8 and 12 weeks after surgery. Results The surface of FDBM subjected to Nd∶YAG laser irradiation resulted in well-defined three-dimensional nanoscale grooves (150 nm in depth and 600 to 800 nm in width). When the osteoblasts were implanted on the scaffold, the cells adhering to nFDBM were morethan those to FDBM and secreted more extracellular matrix. Either new bone-likethin layer on the nanoscale surface or a lot of new boneformation inner the experimental complex was observed by HE after 12 weeks of surgery and the experimental complexes were partially calcified at the same time, while the control groups almost had no osteogenic phenomena. Conclusion Nd∶YAG laser could produce nanoscale grooves on the FDBM surface. The nanoscale grooves are conductive to adherence, proliferation and matrix secretion of osteoblasts. Complexes by tissue engineering and nanoscale technology have some osteogenic abilities in vivoafter implanted the animal model.
Tissue engineering has emerged as a promising approach for the repair and functional reconstruction of damaged tissues. The bionic and intelligentized scaffolds provide the structural support for cell growth and differentiation as well as tissue regeneration. The surface properties of the biological material implant, the nanotopology in particular, become key aspects in determining the success of the implant. Mesenchymal stem cells (MSC) are widely favored by researchers as the seed cells in tissue engineering. Recently, it has been shown that nanotopographical characteristics of biomaterials regulate a wide range of MSC properties from their cellular behavior and differentiation potential. Herein, this review will provide an update on studies investigating the roles of nanotopography in the development of tissue engineering using MSC.
Despite the continuous improvement in perioperative use of antibiotics and aseptic techniques, the incidence of infection continues to rise as the need for surgery increasing and brings great challenges to orthopedic surgery. The rough or porous structure of the prosthesis provides an excellent place for bacterial adhesion, proliferation and biofilm formation, which is the main cause of infection. Traditional antibiotic therapy and surgical debridement are difficult to determine whether the infected focus have been removed completely and whether the infection will recur. In recent years, nanotechnology has shown obvious advantages in biomaterials and drug delivery. Nano drug carriers can effectively achieve local antimicrobial therapy, prevent surgical infection by local sustained drug release or intelligent controlled drug release under specific stimuli, and reduce the toxic side effects of drugs. The unique advantages of nanotechnology provide new ideas and options for the prevention and treatment of periprosthetic infection. At present, the application of nano-technology in the prevention and treatment of infection can be divided into the addition of nano-drug-loaded materials to prosthesis materials, the construction of drug-loaded nano-coatings on the surface of prosthesis, the perfusable nano-antimicrobial drug carriers, and the stimulation-responsive drug controlled release system. This article reviews the methods of infection prevention and treatment in orthopaedic surgery, especially the research status of nanotechnology in the prevention and treatment of periprosthetic infection.