'Evaluation of Photo-Functionalisation Effect on Dental Implants by ICP-MS'

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• Conditions: Corrosion

• Registration Number: NCT06759870
• Lead Sponsor: Cumhuriyet University

Brief Summary

Dental implants are used to rehabilitate and restore aesthetic and functional losses caused by tooth loss. They are made of titanium, which is considered to have the best biological safety as a material. However, it is known that implants can continuously corrode, releasing titanium particles and increasing the overall titanium content in the human body. This increased local concentration can lead to damage in intraepithelial hemostasis, exacerbation of inflammatory reactions in surrounding tissues, bone resorption, implant failure, allergic reactions, and accumulation in distal organs through blood and lymph pathways.

The surface properties of implants play a critical role in their corrosion behavior, with surface free energy and hydrophilicity providing advantages for implant osseointegration and wound healing. The titanium oxide layer covers the outer surface of the implant and helps maintain its integrity against external factors. It is known that UV light-mediated photo-functionalization reduces carbon concentration on the implant surface and increases oxygen levels, thereby improving the osseointegration of titanium. The hydroxylated oxide surface shows reactivity with ions, amino acids, and proteins in tissue fluid. Additionally, UV irradiation can create oxygen vacancies at bridging sites between titanium and oxygen atoms, forming a -OH hydrophilic layer in the outermost layer. Given that the oxide layer on the titanium surface provides corrosion resistance for implants, increasing surface hydrophilicity and thus strengthening osseointegration will also confer resistance to corrosion on titanium.

Although the mechanism of titanium particle release is not fully understood, it is influenced by the surface structure of the implant and wear from surgical operations, making it a concern that needs to be addressed.

In light of all this information, the aim of the study was to evaluate titanium particle release in implants with increased surface hydrophilicity by UV photofunctionalization during surgery and three months later during the healing process using ICP-MS.

Detailed Description

Nowadays, dental implants have become a common treatment for the removal of missing teeth. Studies on implant treatment have proven that titanium (Ti) implanted in bone continuously releases particles and significantly increases the total titanium content in the human body.

The two main reasons for the release of Ti particles from the implant are chemical corrosion and surface wear.

When the concentration of local titanium particles increases, oral intraepithelial haemostasis is damaged, inflammation in the surrounding tissues is exacerbated, and dynamic imbalance may occur in osteoblasts and osteoclasts . Ti ions and particles distributed in the human body are directly proportional to the distance from the implant. Concentration is higher in gingival and bone tissue adjacent to the implant.Recent publications in the dental implant literature have shown that treatment of dental implant titanium oxide (TiO) surfaces with 200-400 nm ultraviolet (UV) radiation can increase the bone-implant contact surface (BIC) after normal healing time. UV treatment induces energy to the surface electrons of TiO, and electron energy induces reactions to increase cell attachment and osteoblast contact. UV treatment acts mostly photochemically on titanium surfaces to increase hydrophilicity. UV treatment with this photo-functionalisation has been shown to increase biological reactivity and make the TiO surface attractive for cellular binding.

It has been shown that the hydrophilicity and electrical charge of the titanium surface play a key role in the initial attachment of cells to UV-treated titanium. The newly treated titanium surface is 'superhydrophilic'. This term is used when the contact angle of water to the surface is less than 5 degrees. Due to the ageing of titanium, the implant surface gradually becomes hydrophobic with a contact angle of more than 60 degrees after 4 weeks of treatment. However, it was observed that 5 minutes of UV exposure reduced the water contact angle to almost 0°. The main function of UV treatment is to change the surface from hydrophobic to superhydrophilic, with the removal of hydrocarbon contamination from the surface of titanium. This induced surface change increases the initial blood contact with the implant surface and facilitates cellular growth and osseointegration of bone to the implant. In fact, studies have shown that the bioactivity of UV-activated titanium surfaces is higher than the bioactivity of newly treated surfaces .

UV treatment of titanium surfaces increases the bone-implant contact area from 55% to close to 98.2% and also results in a 3-fold increase in the strength of bone-implant integration. This greatly improves primary stability even in implants placed without cortical bone support. Primary stability is very important to avoid micro-movements that may adversely affect the osseointegration process.

In the light of all this information, the aim of this study was to evaluate the effect of UV photo-functionalisation on titanium particle release in titanium implants.

Study Timeline

• Status Verified: 2024-12
• Study First Submitted: 2024-12-20
• Study First Submitted QC: 2025-01-03
• Last Update Submitted: 2025-01-03
• Study First Posted: 2025-01-06
• Last Update Posted: 2025-01-06
• Study Start: 2025-02-03
• Primary Completion: 2026-06-01
• Study Completion: 2026-06-02

Recruitment & Eligibility

• Status: NOT_YET_RECRUITING
• Sex: All
• Target Recruitment: 64

Inclusion Criteria

• Standard size implant
• Non-smoker
• No other metal-containing restorations in the mouth

Exclusion Criteria

• Soft or hard tissue augmentation
• Use of short implants or implants of 4.5 mm or more

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Primary Outcome Measures

Name	Time	Method
ICP-MS (Inductively Coupled Plasma - Mass Spectrometer) results	3 months	The levels of titanium element will be measured on the ICP-MS device and the results will be expressed at ppb level.
ISQ (Implant stability quotient) result	3 months	ISQ values will be measured on the implant stability measurement device and expressed as numerical values.