The diameter of nanotubes formed on Ti-6Al-4V alloy controls the adhesion and differentiation of&amp;nbsp;Saos-2 cells

Filová, Elena; Fojt, Jaroslav; Krýslová, Markéta; Moravec, Hynek; Joska, Luděk; Bačáková, Lucie

doi:10.2147/ijn.s87474

Cited by 40 publications

(26 citation statements)

References 50 publications

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“…Nanotube on pure TiO2 would only be formed on pure Ti has been reported as the main component of the nanotube that was formed on Ti6Al-4V metal alloy, nanotube that was formed also contained vanadium, aluminum, and fluorine from the electrolyte solution such as HF/HNO3/H2O, which was used before anodization. During the process of nanotube TiO2 nanotube formation not only Ti that was oxidized but also Al and V, forming Al2O3 and V2O5 [16]. The reaction as followed: in ethylene glycol:distilled water (9:1) which was the best condition for oxide layered nanotube , as comparable with the research that has been done by Pawelska and Cydzik [17].…”

Section: The Results Of Ti-6al-4v Metal Alloy Characterization Using Semsupporting

confidence: 66%

Utilization of Electrolyte Solution in Nanotube Formation on Ti-6Al-4V Metal Alloy

Charlena

Kemala

Wulanawati

2018

ijfac

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(English)Formation of nanotube morphology on the surface of Ti-6Al-4V metal did not occur homogeneously, so when it was coated with hydroxyapatite, it did not merge well. One of the factors that affected the inhomogeneously formed nanotube was the utilization of electrolyte solution. The research has been done to observe the effect of electrolyte solution in the formation of nanotube morphology on the surface of Ti-6Al-4V metal alloy. Electrolyte solution that was used was ethylene glycol, HF, and NH4F with time variation of an hour, 2 hours, and 3 hours. Formation of nanotube morphology on the surface of Ti-6Al-4V metal alloy was done using anodization process. The result showed that in HF electrolyte solution which was anodized for an hour ɑ and β phase that composed Ti-6Al-4V metal alloy was formed, meanwhile when using electrolyte solution of ethylene glycol + NH4F for 2 hours showed that there were pores that opened on Ti-6Al-4V metal alloy surface. Nanotube morphology on the surface of Ti6Al-4V metal alloy was formed using electrolyte solution of ethylene glycol + NH4F which was anodized for 3 hours. Keywords: electrolyte solution, metal alloy, nanotube, Ti-6Al-4V Abstrak (Indonesian)Pembentukan morfologi nanotube pada permukaan logam Ti-6Al-4V tidak terjadi secara homogen, sehingga ketika dilapisi dengan hidroksiapatit maka tidak dapat menyatu dengan baik. Salah satu faktor yang mempengaruhi nanotube yang terbentuk tidak homogen yaitu penggunaan larutan elektrolit. Untuk itu dilakukan penelitian dengan tujuan melihat pengaruh larutan elektrolit dalam pembentukan morfologi nanotube pada paduan logam Ti-6Al-4V. Larutan elektrolit yang digunakan adalah etilen glikol, HF dan NH 4 F dengan variasi waktu 1 jam, 2 jam dan 3 jam. Pembentukan morfologi nanotube pada permukaan paduan logam Ti-6Al-4V dilakukan dengan menggunakan proses anodisasi. Hasil penelitian menunjukkan bahwa pada larutan elektrolit HF yang dianodisasi selama 1 jam terbentuk fase α dan β yang menyusun paduan logam Ti-6Al-4V, sedangkan menggunakan larutan elektrolit etilen glikol+NH 4 F selama 2 jam terlihat adanya pori yang membuka pada permukaan paduan logam Ti-6Al-4V. Morfologi nanotube pada permukaan paduan logam Ti-6Al-4V terbentuk dengan menggunakan larutan elektrolit etilen glikol+NH 4 F yang dianodisasi selama 3 jam. Kata kunci: larutan elektrolit, nanotube, paduan logam

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Section: The Results Of Ti-6al-4v Metal Alloy Characterization Using Semsupporting

confidence: 66%

Utilization of Electrolyte Solution in Nanotube Formation on Ti-6Al-4V Metal Alloy

Charlena

Kemala

Wulanawati

2018

ijfac

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“…Although several binary and ternary mixed oxide nanotubes were fabricated by the anodization of Ti-Fe [148], Ti-Ta, Ti-Nb [175], Ti-Pd [176], Ti-Al [177], Ti-Mo [178], Ti-V [179], Ti-W [180], Ti-Mn [181], Ti-Ni [182], Ti-Mo-Ni [183], and Ti-6Al-4V [184] alloys, only some of them were applied as electrodes in lithium ion batteries. As an example, well-ordered mixed Ti-Mn-O nanotubes were grown on the surface of a Ti-8Mn alloy by anodization [181].…”

Section: Mixed Oxide Nanotubesmentioning

confidence: 99%

Current Advances in TiO2-Based Nanostructure Electrodes for High Performance Lithium Ion Batteries

2018

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The lithium ion battery (LIB) has proven to be a very reliably used system to store electrical energy, for either mobile or stationary applications. Among others, TiO 2-based anodes are the most attractive candidates for building safe and durable lithium ion batteries with high energy density. A variety of TiO 2 nanostructures has been thoroughly investigated as anodes in LIBs, e.g., nanoparticles, nanorods, nanoneedles, nanowires, and nanotubes discussed either in their pure form or in composites. In this review, we present the recent developments and breakthroughs demonstrated to synthesize safe, high power, and low cost nanostructured titania-based anodes. The reader is provided with an in-depth review of well-oriented TiO 2-based nanotubes fabricated by anodic oxidation. Other strategies for modification of TiO 2-based anodes with other elements or materials are also highlighted in this report.

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“…Our previous work based on anodization of Ti‐6Al‐4V and other publications demonstrated a reduction in Ti, Al, and V content compared with polished control, whereas O and F were detected on anodized Ti‐6Al‐4V surfaces. [ 27,71,72 ] However, F content was not expected to influence biocompatibility for application of anodized surfaces since in vitro and in vivo studies have validated the supportive effect on bone regeneration of anodized surfaces. [ 72,73 ] Furthermore, fluoride‐modified dental implants via electrochemical etching illustrated the significant improvement of bone regeneration and has been widely used in clinical applications, even though it is difficult to distinguish the individual contribution made by surface texture or chemical composition.…”

Section: Resultsmentioning

confidence: 99%

Combined Infection Control and Enhanced Osteogenic Differentiation Capacity on Additive Manufactured Ti‐6Al‐4V are Mediated via Titania Nanotube Delivery of Novel Biofilm Inhibitors

Mutreja

Hooper

et al. 2020

Adv Materials Inter

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Additive manufacturing (AM) of titanium alloys offers the capacity to fabricate patient-specific implants with defined porous architecture to enhance bone-implant fixation. However, clinical challenges associated with orthopedic implants include inconsistent osseointegration and biofilm-associated peri-implant infection, leading to implant failure. Here, a strategy is developed to reduce infection and promote osteogenesis simultaneously on AM Ti-6Al-4V implants by delivering biofilm inhibitor molecules via titania nanotube surface modification. Electrochemical anodization is performed on polished and as-manufactured Ti-6Al-4V to generate nanotubes, which are utilized for delivery of a novel methylthioadenosine nucleosidase inhibitor (MTANi) that targets MTAN-a key enzyme in bacterial metabolism involved in biofilm formation-thereby offering biofilm inhibition capacity combined with surface nano-topography for promoting osteogenesis. Clinical isolates of staphylococcus cohnii formed firm biofilms on polished and AM Ti-6Al-4V controls whereas modified implants loaded with MTANi inhibit biofilm formation. Anodized AM Ti-6Al-4V nanotube substrates enhance alkaline phosphatase production, bone-specific protein expression (osteocalcin, collagen I) and mineral deposition of human mesenchymal stromal cells (hMSCs), compared to as-manufactured controls. Importantly, no detrimental effects on hMSC proliferation and osteogenic differentiation are observed for MTANi-loaded substrates. Application of novel MTANi and electrochemical anodization offers a promising strategy for titanium alloy implant surface modification.

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The diameter of nanotubes formed on Ti-6Al-4V alloy controls the adhesion and differentiation of Saos-2 cells

Cited by 40 publications

References 50 publications

Utilization of Electrolyte Solution in Nanotube Formation on Ti-6Al-4V Metal Alloy

Utilization of Electrolyte Solution in Nanotube Formation on Ti-6Al-4V Metal Alloy

Current Advances in TiO2-Based Nanostructure Electrodes for High Performance Lithium Ion Batteries

Combined Infection Control and Enhanced Osteogenic Differentiation Capacity on Additive Manufactured Ti‐6Al‐4V are Mediated via Titania Nanotube Delivery of Novel Biofilm Inhibitors

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