&lt;p&gt;Applications of Graphene and Its Derivatives in Bone Repair: Advantages for Promoting Bone Formation and Providing Real-Time Detection, Challenges and Future Prospects&lt;/p&gt;

Du, Zhipo; Wang, Cunyang; Zhang, Ruihong; Wang, Xiumei; Li, Xiaoming

doi:10.2147/ijn.s271917

Cited by 57 publications

(42 citation statements)

References 174 publications

(240 reference statements)

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“…Composite structures shaped either as 3D porous scaffolds, 2D planar coatings or barrier membranes have been developed ( Figure 16 ) to enhance the bone volume in bone defect zones [ 234 ]. The potential of graphene and GRM for the differentiation of various types of stem cells has captured remarkable attention [ 228 ]; actually, this ability has been ascribed to its peculiar noncovalent binding to different biomolecules that allows GRM to behave as pre-concentration platforms for osteogenic inducers, accelerating the differentiation of hMSC (Human Mesenchymal Stem Cells) into osteogenic cells.…”

Section: Ceramic/graphene Composites In Biomedicinementioning

confidence: 99%

“…Reinforcement has been observed also in printed bioactive glass scaffolds containing rGO [ 237 ]. In addition to BTE applications, graphene-based composites may be applied as the contrast agent in vivo imaging for real-time detection of the bone repair process, detecting structural changes, tumorigenicity, degradation and mineralization of the bone repair materials in complex environments (see review [ 234 ]).…”

Section: Ceramic/graphene Composites In Biomedicinementioning

confidence: 99%

“… Scheme showing the possible role of graphene-based materials (GDs) in BTE applications. Reprinted from reference [ 234 ]. …”

Section: Figurementioning

confidence: 99%

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Applications of Ceramic/Graphene Composites and Hybrids

et al. 2021

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Research activity on ceramic/graphene composites and hybrids has increased dramatically in the last decade. In this review, we provide an overview of recent contributions involving ceramics, graphene, and graphene-related materials (GRM, i.e., graphene oxide, reduced graphene oxide, and graphene nanoplatelets) with a primary focus on applications. We have adopted a broad scope of the term ceramics, therefore including some applications of GRM with certain metal oxides and cement-based matrices in the review. Applications of ceramic/graphene hybrids and composites cover many different areas, in particular, energy production and storage (batteries, supercapacitors, solar and fuel cells), energy harvesting, sensors and biosensors, electromagnetic interference shielding, biomaterials, thermal management (heat dissipation and heat conduction functions), engineering components, catalysts, etc. A section on ceramic/GRM composites processed by additive manufacturing methods is included due to their industrial potential and waste reduction capability. All these applications of ceramic/graphene composites and hybrids are listed and mentioned in the present review, ending with the authors’ outlook of those that seem most promising, based on the research efforts carried out in this field.

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Section: Ceramic/graphene Composites In Biomedicinementioning

confidence: 99%

Section: Ceramic/graphene Composites In Biomedicinementioning

confidence: 99%

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Applications of Ceramic/Graphene Composites and Hybrids

et al. 2021

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“…Recently, in order to improve these problems, carbon nanostructures such as graphene (Gr) and graphene oxide (GO) are providing new perspectives for TE. These can be applied in drugs and genes delivery of, as well as in the articular repair and bone defects [ 3 , 7 , 8 , 9 , 10 ] due to their physical characteristics such as mechanical strength, flexibility, elasticity [ 11 ], low density [ 12 ], structural support, self-lubricating properties and anti-wear due to its laminar structure which supports in the surface lubrication. Furthermore, these can be applied to mediate cell proliferation, differentiation and migration and improve the bone repair effect [ 7 , 13 , 14 , 15 , 16 ].…”

Section: Introductionmentioning

confidence: 99%

“…These can be applied in drugs and genes delivery of, as well as in the articular repair and bone defects [ 3 , 7 , 8 , 9 , 10 ] due to their physical characteristics such as mechanical strength, flexibility, elasticity [ 11 ], low density [ 12 ], structural support, self-lubricating properties and anti-wear due to its laminar structure which supports in the surface lubrication. Furthermore, these can be applied to mediate cell proliferation, differentiation and migration and improve the bone repair effect [ 7 , 13 , 14 , 15 , 16 ]. Additionally, GO plays an important role in stimulating cell functions and guiding tissue regeneration, as presented by Du et al [ 7 ], comparatively showing the osteogenic capacity of treated multiple-wall carbon nanotubes (MCNTs) and the inorganic component of natural bone.…”

Section: Introductionmentioning

confidence: 99%

Biological Characterization of Polymeric Matrix and Graphene Oxide Biocomposites Filaments for Biomedical Implant Applications: A Preliminary Report

et al. 2021

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Carbon nanostructures application, such as graphene (Gr) and graphene oxide (GO), provides suitable efforts for new material acquirement in biomedical areas. By aiming to combine the unique physicochemical properties of GO to Poly L-lactic acid (PLLA), PLLA-GO filaments were produced and characterized by X-ray diffraction (XRD). The in vivo biocompatibility of these nanocomposites was performed by subcutaneous and intramuscular implantation in adult Wistar rats. Evaluation of the implantation inflammatory response (21 days) and mesenchymal stem cells (MSCs) with PLLA-GO took place in culture for 7 days. Through XRD, new crystallographic planes were formed by mixing GO with PLLA (PLLA-GO). Using macroscopic analysis, GO implanted in the subcutaneous region showed particles’ organization, forming a structure similar to a ribbon, without tissue invasion. Histologically, no tissue architecture changes were observed, and PLLA-GO cell adhesion was demonstrated by scanning electron microscopy (SEM). Finally, PLLA-GO nanocomposites showed promising results due to the in vivo biocompatibility test, which demonstrated effective integration and absence of inflammation after 21 days of implantation. These results indicate the future use of PLLA-GO nanocomposites as a new effort for tissue engineering (TE) application, although further analysis is required to evaluate their proliferative capacity and viability.

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Biological and Mechanical Response of Graphene Oxide Surface‐Treated Polylactic Acid 3D‐Printed Bone Scaffolds: Experimental and Numerical Approaches

Mashhadi Keshtiban,

Taghvaei,

Noroozi

et al. 2024

Adv Eng Mater

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Employing 3D printing bone scaffolds with various polymers is growing due to their biocompatibility, biodegradability, and good mechanical properties. However, their biological properties need modification to have fewer difficulties in clinical experiments. Herein, the fused‐deposition modeling technique is used to design triply‐periodic‐minimal‐surfaces polylactic‐acid scaffolds and evaluate their biological response under static and dynamic cell culture conditions. To enhance the biological response of 3D‐printed bone scaffolds, graphene‐oxide (GO) is coated on the surface of the scaffolds. Fourier‐transform infrared spectroscopy, X‐ray diffraction, and energy‐dispersion X‐ray analysis are conducted to check the GO presence and its effects. Also, computational fluid dynamics analysis is implemented to investigate the shear stress on the scaffold, which is a critical parameter for cell proliferation under dynamic cell culture conditions. Compression tests and contact‐angle measurements are performed to assess the GO effect on mechanical properties and wettability, respectively. Also, it was shown that surface‐treated scaffolds have lower mechanical properties and higher wettability than uncoated scaffolds. A perfusion bioreactor is used to study cell culture. Also, field‐emission‐scanning‐electron‐microscope and 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5 diphenyl‐tetrazolium‐bromide (MTT) assay analyses are conducted to observe cell viability and cell attachment. An increase of up to 220% in viability was achieved with GO and dynamic cell culture.

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<p>Applications of Graphene and Its Derivatives in Bone Repair: Advantages for Promoting Bone Formation and Providing Real-Time Detection, Challenges and Future Prospects</p>

Cited by 57 publications

References 174 publications

Applications of Ceramic/Graphene Composites and Hybrids

Applications of Ceramic/Graphene Composites and Hybrids

Biological Characterization of Polymeric Matrix and Graphene Oxide Biocomposites Filaments for Biomedical Implant Applications: A Preliminary Report

Biological and Mechanical Response of Graphene Oxide Surface‐Treated Polylactic Acid 3D‐Printed Bone Scaffolds: Experimental and Numerical Approaches

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