High Nanodiamond Content-PCL Composite for Tissue Engineering Scaffolds

Fox, Kate; Ratwatte, Rahul; Booth, Marsilea A.; Tran, Hoai My; Tran, Phong A.

doi:10.3390/nano10050948

Cited by 24 publications

(18 citation statements)

References 46 publications

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“…NDs (crystal size between 3 and 100 nm) can be purchased commercially as powders or aqueous suspensions. [ 13 ] Typically, ND coatings are processed as part of a composite [ 17,18 ] or via dip coating producing a monolayer‐type thin film. [ 11,19 ] NDs present a cheaper and simpler coating process; albeit with a less compact layer, possible leakage of NDs, and higher variability.…”

Section: Shine Bright: a Closer Look At Diamond‐enhanced Materialsmentioning

confidence: 99%

Diamond in the Rough: Toward Improved Materials for the Bone−Implant Interface

Fong

Booth

Rifai

et al. 2021

Adv Healthcare Materials

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The ability of an orthopedic implant to integrate successfully with the surrounding bone tissue is imperative for optimal patient outcomes. Here, the recent advances and future prospects for diamond-based coatings of conventional osteo-implant materials (primarily titanium) are explored. The ability of these diamond coatings to enhance integration into existing bone, improved implant mechanical properties, facilitate surface chemical functionalization, and provide anti-microbial properties are discussed in context of orthopedic implants. These diamond-based materials may have the additional benefit of providing an osteo-inductive effect, enabling better integration into existing bone via stem cell recruitment and bone regeneration. Current and timely research is highlighted to support the discussion and suggestions in further improving implant integration via an osseoinductive effect from the diamond composite materials.

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Section: Shine Bright: a Closer Look At Diamond‐enhanced Materialsmentioning

confidence: 99%

Diamond in the Rough: Toward Improved Materials for the Bone−Implant Interface

Fong

Booth

Rifai

et al. 2021

Adv Healthcare Materials

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“…Tissue scaffolds and surgical implants: Due to the restoring potential for damaged tissue, regenerative medicine, and tissue engineering are of great interest [174][175][176][177]. Like protein-coated materials, ND monolayers have been indicated to act as a suitable platform for the growth of neuronal cells [178].…”

Section: General Applicationsmentioning

confidence: 99%

“…Also, microbial activity decreased with the increase in the ND content. Fox et al [177] also reported the synthesis of PCL/ND composites by the solvent casting method. The results demonstrated that hydrophilicity and surface roughness of the ND-PCL composite films were higher than those of PCL alone.…”

Section: Nanocomposite Scaffolds and Implantsmentioning

confidence: 99%

Nanodiamond-containing composites for tissue scaﬀolds and surgical implants: A review

Zamani

Zareein

Bazli

et al. 2020

jcc

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“…Work by Fox et al showed improved human osteoblast cellular adhesion on their soft composite of polycaprolactone with NDs, when compared to polycaprolactone alone. The ND‐polymer composite was extruded through a needle in a simple design printed prototype scaffold (Fox et al, 2020b). Although this work highlights the potential for additively manufactured diamond composites, it requires improvement to get the mechanical properties and complex geometries closer to those required of implants.…”

Section: Fabrication and Application Of Different Diamond Surfaces Fomentioning

confidence: 99%

Diamond in medical devices and sensors: An overview of diamond surfaces

et al. 2020

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The human body is a sophisticated environment for research. There has been progress in developing advanced medical devices and sensors to contribute to recovery and therapy. However, as the field progresses new materials with specific properties are required to maximize recovery and therapy efficiency. Desired properties include materials that can contribute to cell regeneration and proliferation while preventing bacterial biofilm formation. Additionally, the variability in geometries of diseased parts requires improvement in processing to provide case and geometry-specific solutions (Raghavendra et al., 2015). Hence, there is a need for novel biomaterials that better match the native tissue. Their effectiveness and functionality are crucial to the long-term physical activity and health of patients. Carbon-based materials have attracted attention due to their unique characteristics, including mechanical, thermal and optical properties (Martel-Estrada, 2018), and they have been used in the

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High Nanodiamond Content-PCL Composite for Tissue Engineering Scaffolds

Cited by 24 publications

References 46 publications

Diamond in the Rough: Toward Improved Materials for the Bone−Implant Interface

Diamond in the Rough: Toward Improved Materials for the Bone−Implant Interface

Nanodiamond-containing composites for tissue scaﬀolds and surgical implants: A review

Diamond in medical devices and sensors: An overview of diamond surfaces

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