Overcoming the biological aging of titanium using a wet storage method after ultraviolet treatment

Choi, Sang Sik; Jeong, Won Seok; Yul, Jung; Lee, Jae Hoon; Lee, Kee Joon; Yu, Hyung Seog; Choi, Eun Ha; Kim, Kwang Mahn; Hwang, Chung Ju

doi:10.1038/s41598-017-04192-9

Cited by 32 publications

(24 citation statements)

References 41 publications

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“…Therefore, the amount of hydrocarbon adsorbed on TiO 2 from the time of manufacture to the time of implantation is crucial in determining the initial affinity level for osteoblasts. Choi et al [59] observed larger spindle-shaped MC3T3-E1 with extended actin filaments on the UV-treated surface of titanium stored in distilled water prior to their experiment. To date, the dental implant system with a SLActive ® surface (Institute Straumann AG, Basel, Switzerland) is the only implant system that is rinsed with nitrogen to prevent exposure to air and stored in a glass ampoule containing saline solution (0.9% sodium chloride) following manufacture.…”

Section: Titanium Surface Contaminationmentioning

confidence: 93%

An Integrated Overview of Ultraviolet Technology for Reversing Titanium Dental Implant Degradation: Mechanism of Reaction and Effectivity

et al. 2020

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Titanium is widely used as an implanted material in various clinical applications, especially in orthopedics and dental implantology. Following manufacturing and storage, titanium dental implants have the ability to undergo aging, which renders a reduction in osteoblast cellular activity during the healing process, so advancement of a surface treatment to recreate bioactive implant surfaces are required. Ultra-violet (UV) surface treatment has been introduced as a potential solution to reverse the aging process via removal of hydrocarbon contamination on the surface. This narrative review aimed to discuss the current understanding of the mechanism of titanium aging and provide insights into the mechanism that improves the biocompatibility of titanium implants following UV treatment. Additionally, the findings from preclinical and clinical studies is integratively presented. A reference search was performed through the PubMed, Embase, and Scopus databases based on the keywords titanium degradation, titanium aging, photofunctionalization, and UV treatment. Emerging data demonstrated the positive effect of UV light on osteoblast cells with enhanced alkaline phosphatase activity in vitro and increased bone-implant contact in animal studies. Despite limited human studies, the data reported here appear to support the benefit of UV light photofunctionalization on titanium surfaces as an alternative to reverse the titanium aging process. The direction of future research should focus on prospective randomized blinded clinical trials.

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Section: Titanium Surface Contaminationmentioning

confidence: 93%

An Integrated Overview of Ultraviolet Technology for Reversing Titanium Dental Implant Degradation: Mechanism of Reaction and Effectivity

et al. 2020

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“…It has been determined that the zeta potential of a biphasic calcium composite material is approximately À20.4 mV 172 and of nonmodified titanium around À10 mV. 173 Usually it is accepted that the increase of the negativity of the zeta potential of an implant allows a more favorable integration of the material into the tissue (e.g. ref.…”

Section: Biocompatibility and Zeta Potentialmentioning

confidence: 99%

Amorphous polyphosphate, a smart bioinspired nano-/bio-material for bone and cartilage regeneration: towards a new paradigm in tissue engineering

2018

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“…Induced aspects involve the hierarchical structure of threads, screw pitch, concave grooves generated by sandblasting (in the range of 5 to about 70 μm), and pores of different shapes created by acid etching (in the range of several hundred nanometers up to 3 μm). This combination naturally leads to hydrocarbon adsorption (Att et al, ; Choi et al, , ) and a wetting behavior that, as explained in basic teaching of wettability science (Cassie & Baxter, , Dettre & Johnson Jr, , Wenzel, , ), is magnified by topographic details, leading to hydrophobic implant surfaces and large contact angle hysteresis on aging, as nicely described by Rupp et al (). Within these boundaries, prevention of hydrocarbon adsorption by wet storage (Baier & Meyer, ) or removal of adsorbed hydrocarbons by discharge techniques just before usage (Canullo et al, ; Choi et al, , ) stop or reverse the natural trend and provide high‐energy surfaces whose hydrophilicity is further enhanced by capillary wicking into grooves and pores.…”

Section: Discussionmentioning

confidence: 89%

“…In the case of titanium dental implants, the basic determinant of excess specific surface free energy, that is, the surface chemical composition, combines with the other properties that affect macroscopic wetting behavior and capillary rise, that is surface microtopography and thread size and shape (Rupp, Scheideler, Rehbein, Axmann, & Gels‐Gerstorfer, ), yielding increasingly hydrophobic surfaces as time from production goes bay. This behavior has been defined “biological aging” (Att et al, ; Choi et al, , ), with a view to its biological effects. Its cause, however, is plainly chemical–physical, as just discussed.…”

Section: Introductionmentioning

confidence: 99%

“…Its cause, however, is plainly chemical–physical, as just discussed. The hitherto most investigated chemical–physical approaches to exploit biological responses driven by hydrophilic implant surfaces involve preventing hydrocarbon adsorption by packaging in water (i.e., the already quoted SLActive approach) or getting rid of adsorbed hydrocarbons by UV light or glow discharge cleaning just before usage by side‐chair devices (Canullo et al, ; Choi et al, , ).…”

Section: Introductionmentioning

confidence: 99%

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Permanent wettability of a novel, nanoengineered, clinically available, hyaluronan‐coated dental implant

Morra¹,

Cassinelli²,

Torre³

et al. 2018

Clinical & Exp Dental Res

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The objectives of this study are to evaluate long‐term wettability of novel surface‐engineered, clinically available dental implants, featuring a surface nanolayer of covalently linked hyaluronan, and to confirm the relationships between wetting properties and surface nanostructure and microstructure. Wettability measurements were performed on clinically available hyaluronan‐coated Grade 4 titanium implants, packaged and sterile, that is, in the “on the shelf” condition, after 1 year from production. Wetting properties were measured by the Wilhelmy plate method. Analysis of the surface structure and chemistry was perfomed by X‐ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM) and energy‐dispersive X‐ray (EDX) analysis, atomic force microscopy (AFM), and ζ‐potential measurement, either on implants or disks or plates subjected to the same surface‐engineering process. Results show that hydrophilicity and ensuing capillary rise of the hyaluronan‐coated implant surface is unaffected by aging and dry storage. Chemical analysis of the implant surface by XPS and evaluation of the ζ potential indicate that hyaluronan chemistry and not that of titanium dictates interfacial properties. Comparison between XPS versus EDX and SEM versus AFM data confirm that the thickness of the hyaluronan surface layer is within the nanometer range. Data show that nanoengineering of the implant surface by linking of the hydrophilic hyaluronan molecule endows tested titanium implants by permanent wettability, without need of wet storage as presently performed to keep long‐term hydrophilic implant surfaces. From an analytical point of view, the introduction in routine clinical practice of nanoengineered implant surfaces requires upgrading of analytical methods to the nanoscale.

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Overcoming the biological aging of titanium using a wet storage method after ultraviolet treatment

Cited by 32 publications

References 41 publications

An Integrated Overview of Ultraviolet Technology for Reversing Titanium Dental Implant Degradation: Mechanism of Reaction and Effectivity

An Integrated Overview of Ultraviolet Technology for Reversing Titanium Dental Implant Degradation: Mechanism of Reaction and Effectivity

Amorphous polyphosphate, a smart bioinspired nano-/bio-material for bone and cartilage regeneration: towards a new paradigm in tissue engineering

Permanent wettability of a novel, nanoengineered, clinically available, hyaluronan‐coated dental implant

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