Lukito Dwi Yuono
Yuono

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Surface Engineering of Dental Implants: Techniques, Mechanisms, and Clinical Considerations Eko Budiyanto; Lukito Dwi Yuono
Asian Journal of Mechanical Engineering Vol. 1 No. 1 (2025): January – June
Publisher : Global Scientific Media

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Dental implants have emerged as one of the most effective and widely accepted solutions for replacing missing natural teeth in modern dentistry. The long-term success or potential failure of dental implants is influenced by a range of local and systemic factors. Among these, the surface characteristics of the implant play a pivotal role in the initial biological response following implantation. In particular, surface roughness has garnered significant interest in recent years due to its ability to enhance the interaction between the implant and the surrounding bone tissue. To promote faster and more effective osseointegration, the direct structural and functional connection between living bone and the surface of the implant, numerous surface modification techniques have been explored. These include mechanical, chemical, and physical treatments, often utilizing various materials designed to improve biocompatibility and promote early bone healing. While a growing body of research suggests that such surface treatments can significantly accelerate healing, particularly in the initial stages following implant placement, clinical decision-making must still be guided by both the available scientific evidence and the specific needs of each patient case. This review article aims to synthesize current knowledge regarding the surface treatment of dental implants. By critically analyzing findings from various experimental and clinical studies, it provides insights into the advantages and limitations of different surface modification techniques currently in use. The goal is to assist clinicians and researchers in selecting appropriate implant systems based on evidence-based outcomes and clinical applicability.
Titanium Dental Implant Corrosion: Mechanisms, Effects, and Preventive Strategies Eko Budiyanto; Lukito Dwi Yuono
Asian Journal of Mechanical Engineering Vol. 1 No. 2 (2025): July – December (In progress)
Publisher : Global Scientific Media

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Titanium and its alloys are widely employed in dental implantology due to their favorable mechanical properties, corrosion resistance, and excellent biocompatibility, which are primarily attributed to the formation of a stable surface titanium dioxide (TiO2) passive layer. Despite these advantages, titanium dental implants are not completely immune to corrosion in the complex and dynamic oral environment. Variations in pH, presence of aggressive ions such as fluoride and chloride, microbial activity, mechanical loading, and micromovements at the implant–bone interface can disrupt the passive oxide layer and initiate corrosion processes. This degradation may result in the release of metallic ions and particles into peri-implant tissues, potentially triggering inflammatory reactions, hypersensitivity responses, bone resorption, and implant failure. This review comprehensively discusses the fundamental mechanisms of corrosion affecting titanium dental implants, including galvanic, pitting, crevice, fretting corrosion, and tribocorrosion. The biological and clinical consequences of corrosion products on peri-implant soft and hard tissues are critically analyzed, with emphasis on their role in peri-implantitis and aseptic implant loosening. Furthermore, current preventive strategies aimed at minimizing corrosion are examined, including implant material selection, surface modification techniques, protective coatings, and optimization of prosthetic design. Understanding the interplay between electrochemical, mechanical, and biological factors governing titanium implant corrosion is essential for improving long-term implant performance and clinical outcomes.