Recent advances in polymeric scaffolds containing carbon nanotube and graphene oxide for cartilage and bone regeneration

Bone and cartilage defects may occur for various reasons such as degenerative, surgical, and traumatic diseases. Autograft and allograft transplantations have the inherent problems of donor tissue and risks of infection. Tissue engineering is a combination of scaffolds, cells, and bioactive molecules for the regeneration of injured tissue. Among various advanced materials, graphene oxide (GO) and carbon nanotubes (CNTs) have widely been examined for their potential in tissue engineering primarily due to their extraordinary physicochemical and mechanical properties as well as acceptable biocompatibility. Therefore, they have been used for cell proliferation, chondrogenic differentiation, and bone regeneration. In biomedical research, artificial three-dimensional (3D) biomaterials have been advanced for treating bone and cartilage defects. CNT and GO as promising materials can serve a similar microenvironment for the natural function of bone and cartilage such as mechanical strength. A variety of synthetic and natural polymers have been utilized to develop artificial bones and cartilages. In this review, we discuss the physicochemical characteristics of the GO- and CNT-based polymeric scaffolds and delineate their impacts on the cellular behaviors in cartilage and bone regeneration, including cell attachment, growth, and differentiation into osteoblast and chondrocyte. We also impart on the development of the 3D hydrogel-based scaffolds, electrospinning, and 3D-printing methods as well as their potential in bone and cartilage tissue engineering.

Automated summary

The passage discusses the reasons for bone and cartilage defects, issues with autograft and allograft transplantations, and the application of tissue engineering. Graphene oxide and carbon nanotubes are highlighted for their potential in tissue engineering, particularly in cell proliferation, chondrogenic differentiation, and bone regeneration. The development of artificial three-dimensional biomaterials and the impact of polymer scaffolds based on GO and CNT on cellular behaviors in cartilage and bone regeneration are also explored. Additionally, the review touches on the importance of 3D hydrogel-based scaffolds, electrospinning, and 3D-printing methods in bone and cartilage tissue engineering.