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Dental Materials: Foundations of Modern Dentistry

Jordan Daves*

Department of Dentistry, University of Sydney, NSW, Australia

*Corresponding Author:
Jordan Daves
Department of Dentistry, University of Sydney, NSW, Australia
E-mail: jordandaves324@gmail.com

Received: 17-May-2024, Manuscript No. JDS-24-139458; Editor assigned: 21-May-2024, Pre QC No. JDS-24-139458 (PQ); Reviewed: 04-Jun-2024, QC No.JDS-24-139458; Revised: 11-Jun-2024, Manuscript No.JDS-24-139458 (R); Published: 18-Jun-2024, DOI: 10.4172/2320-7949.12.2.001

Citation: Daves J. Dental Materials: Foundations of Modern Dentistry. RRJ Dental Sci. 2024;12:001

Copyright: © 2024 Daves J. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Visit for more related articles at Research & Reviews: Journal of Dental Sciences

Abstract

Description

Dental materials are integral to contemporary dental practice, consisting a wide variety of substances used for preventive, restorative, and cosmetic dental procedures. These materials must meet stringent standards to ensure they are safe, durable, and aesthetically pleasing. Their development and refinement are essential for advancing dental care, providing both functional and esthetic solutions for patients.

Classification and types of dental materials

Restorative materials

Amalgam: This is a longstanding restorative material, primarily composed of mercury mixed with other metals like silver, tin, and copper. Known for its durability and strength, amalgam is often used in posterior teeth where chewing forces are greatest. However, its use has declined due to aesthetic concerns and mercury content.

Composite resins: These tooth-colored materials are composed of an organic polymer matrix, typically bis-GMA, reinforced with inorganic fillers like silica. They are highly versatile and can be used for fillings, veneers, inlays, and onlays. The material's ability to bond to tooth structure and its aesthetic quality make it a popular choice.

Glass ionomer cements: These materials release fluoride, offering an additional preventive benefit against caries. They adhere to tooth structure without the need for a bonding agent, making them suitable for non-load-bearing restorations, such as cervical fillings and pediatric dentistry.

Prosthetic materials

Ceramics: Dental ceramics, such as porcelain and zirconia, are valued for their natural appearance and biocompatibility. These materials are used in crowns, bridges, and veneers. Zirconia, in particular, offers excellent strength and is often used for posterior restorations.

Metals and alloys: Metals like gold, and nickel-chromium alloys, are used for their strength and longevity. They are often employed in crowns and bridges, especially in areas of the mouth where aesthetic concerns are less critical.

Implant materials

Titanium and titanium alloys: Titanium is the gold standard for dental implants due to its biocompatibility, strength, and ability to osseointegrate (bond with bone). It provides a stable foundation for prosthetic teeth.

Ceramic implants: Zirconia implants are an alternative for patients with metal sensitivities or those seeking metal-free options. They are strong, biocompatible, and provide a natural tooth-like appearance.

Preventive materials

Sealants: These are resin-based materials applied to the occlusal surfaces of molars to prevent decay. They act as a physical barrier, protecting the tooth enamel from plaque and acids.

Fluoride varnishes: Fluoride varnish is applied to teeth to strengthen enamel and prevent caries. It releases fluoride over time, enhancing enamel resistance to acid attacks.

Properties of dental materials

Biocompatibility: The material must be non-toxic and not provoke an immune response. It should be compatible with oral tissues and not cause any adverse reactions.

Mechanical properties: Dental materials must withstand the forces of mastication without deforming or fracturing. This includes properties like compressive strength, tensile strength, and elasticity.

Aesthetic properties: For materials used in visible areas, color, translucency, and texture must closely mimic natural tooth structures. The ability to blend seamlessly with surrounding teeth is important for patient satisfaction.

Longevity and durability: Dental materials should resist wear, corrosion, and degradation over time, maintaining their functionality and appearance throughout the lifespan of the restoration.

Handling properties: The ease with which a material can be manipulated during a procedure affects the quality and efficiency of dental treatment. Materials should have favorable setting times, workability, and should not be overly technique-sensitive.

Advances in dental materials

Nanotechnology: Incorporating nanoparticles into dental materials enhances their mechanical properties, wear resistance, and antimicrobial characteristics. Nano-filled composites, for example, offer superior strength and polishability compared to traditional composites.

Digital dentistry: The advent of CAD/CAM technology and 3D printing has revolutionized dental restorations. Digital workflows allow for precise fabrication of crowns, bridges, and prostheses, reducing chair time and improving fit and function.

Biomimetic materials: These materials are designed to mimic the natural properties of tooth structure. For instance, bioactive materials like calcium phosphates can promote remineralization and integrate with natural tooth tissue.

Conclusion

Dental materials are the basis of effective and enduring dental treatments. The ongoing evolution of these materials reflects the dynamic nature of dental science, continually pushing the boundaries to offer safer, more durable, and more aesthetically pleasing options for patients. Understanding their properties and applications is essential for dental professionals to deliver optimal care.