Animal Origin Bioactive Hydroxyapatite Thin Films Synthesized by RF-Magnetron Sputtering on 3D Printed Cranial Implants

Chioibasu, Diana; Duta, L.; Popescu-Pelin, Gianina; Popa, Nicoleta Mirela; Milodin, Nichita Larisa; Iosub, Ştefana; Balescu, Liliana Marinela; Gâlcă, A.C.; Popa, Ana Maria; Oktar, Faik N.; Stan, George E.; Popescu, Andrei C.

doi:10.3390/met9121332

Cited by 17 publications

(10 citation statements)

References 87 publications

(124 reference statements)

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“…3D cranial meshes of Ti6Al4V were successfully manufactured using SLM and coated using radio-frequency magnetron sputtering with a~600-nanometer layer of hydroxyapatite that was derived from biogenic sustainable resources (i.e., calcined cortical bovine bones). The Bio-HA sputtered films elicited promising biological performances [9].…”

Section: Contributionsmentioning

confidence: 99%

Metal Additive Manufacturing—State of the Art 2020

Asnafi

2021

Metals

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Section: Contributionsmentioning

confidence: 99%

Metal Additive Manufacturing—State of the Art 2020

Asnafi

2021

Metals

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“…It showed that they could be used for load-bearing implants such as hip, knee and shoulder joints [ 151 , 152 ]. Moreover, orthopedic bone prototypes and meshed cranial prostheses implants were successfully developed for biomedical applications [ 57 , 153 , 154 ].…”

Section: Metal Matrix Composites (Mmcs)mentioning

confidence: 99%

Metal Matrix Composites Synthesized by Laser-Melting Deposition: A Review

2020

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Metal matrix composites (MMCs) present extraordinary characteristics, including high wear resistance, excellent operational properties at elevated temperature, and better chemical inertness as compared to traditional alloys. These properties make them prospective candidates in the fields of aerospace, automotive, heavy goods vehicles, electrical, and biomedical industries. MMCs are challenging to process via traditional manufacturing techniques, requiring high cost and energy. The laser-melting deposition (LMD) has recently been used to manufacture MMCs via rapid prototyping, thus, solving these drawbacks. Besides the benefits mentioned above, the issues such as lower ultimate tensile strength, yield strength, weak bonding between matrix and reinforcements, and cracking are still prevalent in parts produced by LMD. In this article, a detailed analysis is made on the MMCs manufactured via LMD. An illustration is presented on the LMD working principle, its classification, and dependent and independent process parameters. Moreover, a brief comparison between the wire and powder-based LMDs has been summarized. Ex- and in-situ MMCs and their preparation techniques are discussed. Besides this, various matrices available for MMCs manufacturing, properties of MMCs after printing, possible complications and future research directions are reviewed and summarized.

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“…The PLD coated samples were immersed in 1 mL of the same cell culture medium (i.e., DMEM supplemented with 10% fetal bovine serum), used in the case of the cytocompatibility assay, detailed here-under. Recent developments have indicated that a more truthful evaluation of the degradation speed/biomineralization capacity of a material can be achieved by testing under cell culture media, and not in the simplistic simulated body fluids such as Tris-HCl or Kokubo SBF, since the cell culture media reproduces with higher accuracy the composition of the intercellular medium [59,64,79]. The solubility/bioactivity in vitro tests were carried out in a dedicated biological incubator under homeostatic conditions (i.e., humidified atmosphere, temperature of 37 • C, and partial pressure of CO 2 of 5 kPa) for different time periods of 1, 3, and 7 days, respectively.…”

Section: Solubility/bioactivity Tests Under Biomimetic Conditionsmentioning

confidence: 99%

Fish Bone Derived Bi-Phasic Calcium Phosphate Coatings Fabricated by Pulsed Laser Deposition for Biomedical Applications

et al. 2020

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We report on new biomaterials with promising bone and cartilage regeneration potential, from sustainable, cheap resources of fish origin. Thin films were fabricated from fish bone-derived bi-phasic calcium phosphate targets via pulsed laser deposition with a KrF * excimer laser source (λ = 248 nm, τFWHM ≤ 25 ns). Targets and deposited nanostructures were characterized by SEM and XRD, as well as by Energy Dispersive X-ray (EDX) and FTIR spectroscopy. Films were next assessed in vitro by dedicated cytocompatibility and antimicrobial assays. Films were Ca-deficient and contained a significant fraction of β-tricalcium phosphate apart from hydroxyapatite, which could contribute to an increased solubility and an improved biocompatibility for bone regeneration applications. The deposited structures were biocompatible as confirmed by the lack of cytotoxicity on human gingival fibroblast cells, making them promising for fast osseointegration implants. Pulsed laser deposition (PLD) coatings inhibited the microbial adhesion and/or the subsequent biofilm development. A persistent protection against bacterial colonization (Escherichia coli) was demonstrated for at least 72 h, probably due to the release of the native trace elements (i.e., Na, Mg, Si, and/or S) from fish bones. Progress is therefore expected in the realm of multifunctional thin film biomaterials, combining antimicrobial, anti-inflammatory, and regenerative properties for advanced implant coatings and nosocomial infections prevention applications.

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Animal Origin Bioactive Hydroxyapatite Thin Films Synthesized by RF-Magnetron Sputtering on 3D Printed Cranial Implants

Cited by 17 publications

References 87 publications

Metal Additive Manufacturing—State of the Art 2020

Metal Additive Manufacturing—State of the Art 2020

Metal Matrix Composites Synthesized by Laser-Melting Deposition: A Review

Fish Bone Derived Bi-Phasic Calcium Phosphate Coatings Fabricated by Pulsed Laser Deposition for Biomedical Applications

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