Improved electrochemical performance of nitrocarburised stainless steel by hydrogenated amorphous carbon thin films for bone tissue engineering

Derakhshandeh, Seyed Mohammad Reza; Hadavi, S.M.M.; Eshraghi, Mohamad Javad; Javaheri, Masoumeh; Mozafari, Masoud

doi:10.1049/iet-nbt.2016.0163

Cited by 23 publications

(4 citation statements)

References 31 publications

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“…DLC surfaces have a diversity of properties, such as great hardness, near to the ground friction coefficients, chemical inertness, great resistance to wear, and good biocompatibilities, which make them promising candidates for biomedical applications (Allen et al, 1994; Butter and Lettington, 1995; Wei et al, 2016; Derakhshandeh et al, 2017; Huacho et al, 2017). DLC films are promising applicants for modifying the surface of artificial joints, which the cell responses to its surface properties have attracted attentions of scientists in recent years (Liao et al, 2016).…”

Section: Carbon-family Nanomaterials At the Nano-bio Interfacementioning

confidence: 99%

Biological Response to Carbon-Family Nanomaterials: Interactions at the Nano-Bio Interface

Rahmati

Mozafari

2019

Front. Bioeng. Biotechnol.

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During the last few decades, several studies have suggested that carbon-based nanomaterials, owing to their unique properties, could act as promising candidates in biomedical engineering application. Wide-ranging research efforts have investigated the cellular and molecular responses to carbon-based nanomaterials at the nano-bio interfaces. In addition, a number of surface functionalization strategies have been introduced to improve their safety profile in the biological environment. The present review discusses the general principles of immunological responses to nanomaterials. Then, it explains essential physico-chemical properties of carbon-familynanomaterials, including carbon nanotubes (CNTs), graphene, fullerene, carbon quantum dots (CDs), diamond-like carbon (DLC), and mesoporous carbon biomaterials (MCNs), which significantly affect the immunological cellular and molecular responses at the nano-bio interface. The discussions also briefly highlight the recent studies that critically investigated the cellular and molecular responses to various carbon-based nanomaterials. It is expected that the most recent perspective strategies for improving the biological responses to carbon-based nanomaterials can revolutionize their functions in emerging biological applications.

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Section: Carbon-family Nanomaterials At the Nano-bio Interfacementioning

confidence: 99%

Biological Response to Carbon-Family Nanomaterials: Interactions at the Nano-Bio Interface

Rahmati

Mozafari

2019

Front. Bioeng. Biotechnol.

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“…Regarding diamond‐like carbon (DLC) coatings, their benefits for improving the in vitro biological response of polymeric and metallic tissue engineering scaffolds and implants have been investigated (Figure 6c). [ 118,121,122 ] These coatings tend to enhance cell adhesion and provide a remarkable surface hardness, thanks to their high content of sp 3 hybridization, as well as an adequate corrosion resistance against chemicals, abrasion endurance, good biocompatibility, and uniform flat surface. [ 123 ] However, their long‐term performance may be affected by adhesion or delamination problems, as happens with thin‐film technologies in general.…”

Section: Carbon‐based Materials In Tissue Engineering: State‐of‐the‐artmentioning

confidence: 99%

Carbon‐Based Materials for Articular Tissue Engineering: From Innovative Scaffolding Materials toward Engineered Living Carbon

Islam

Lantada

Mager

et al. 2021

Adv Healthcare Materials

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Carbon materials constitute a growing family of high-performance materials immersed in ongoing scientific technological revolutions. Their biochemical properties are interesting for a wide set of healthcare applications and their biomechanical performance, which can be modulated to mimic most human tissues, make them remarkable candidates for tissue repair and regeneration, especially for articular problems and osteochondral defects involving diverse tissues with very different morphologies and properties. However, more systematic approaches to the engineering design of carbon-based cell niches and scaffolds are needed and relevant challenges should still be overcome through extensive and collaborative research. In consequence, this study presents a comprehensive description of carbon materials and an explanation of their benefits for regenerative medicine, focusing on their rising impact in the area of osteochondral and articular repair and regeneration. Once the state-of-the-art is illustrated, innovative design and fabrication strategies for artificially recreating the cellular microenvironment within complex articular structures are discussed. Together with these modern design and fabrication approaches, current challenges, and research trends for reaching patients and creating social and economic impacts are examined. In a closing perspective, the engineering of living carbon materials is also presented for the first time and the related fundamental breakthroughs ahead are clarified.

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“…To explain this, conventional coating materials, such as Mg-substituted fluorapatite [151], agarose [152], chitosan [153] and Ti/titanium oxide [78,154] are ineffective against the embedding of antibacterial or drug materials and corrosive degradation [155,156]. This is where CVD diamond offers its impressive corrosion resistance against fluidic corrosive elements around the implants [125,126], as shown in figure 6(a). With regard to orthopedic implant materials, some earlier studies have reported the deposition of CVD diamond on metallic implants (e.g.…”

Section: Applications Of Cvd Diamond Coatings In Orthopedicsmentioning

confidence: 99%

A comprehensive account of biomedical applications of CVD diamond coatings

Ali¹,

Ali²,

Yang³

et al. 2021

J. Phys. D: Appl. Phys.

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The last two decades have witnessed a massive increase in research pertaining to the wide range of use of artificial diamond films, in particular, chemical vapor deposition (CVD) diamond coatings. Exclusive attention has been given to these coatings as a result of their immense biocompatibility, biofunctionality and non-toxic properties, thereby justifying their preference over other conventional long-used biomedical materials. This review study details the deposition chemistry, growth mechanism, forms and determinants of CVD diamond coatings. The sole purpose of this review revolves around the account of potential biomedical applications of CVD diamond coatings to date. Earlier reports along with the most recent trends of employing CVD diamond films in orthopedic, ophthalmological, dental, biosensing, neuronal implant and antibacterial applications, are recapped. The consequential effects of CVD diamondsurface termination, functionalization and doping have also been explained. It is clear that although ample advancement has been made with regard to CVD coatings in the fields of tissue engineering, implantable devices, implant-body electrochemical interactions and fluidic activation, differentiation or immobilization, there is still plenty of room to exploit the full potential of this CVD diamond technology.

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Improved electrochemical performance of nitrocarburised stainless steel by hydrogenated amorphous carbon thin films for bone tissue engineering

Cited by 23 publications

References 31 publications

Biological Response to Carbon-Family Nanomaterials: Interactions at the Nano-Bio Interface

Biological Response to Carbon-Family Nanomaterials: Interactions at the Nano-Bio Interface

Carbon‐Based Materials for Articular Tissue Engineering: From Innovative Scaffolding Materials toward Engineered Living Carbon

A comprehensive account of biomedical applications of CVD diamond coatings

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