Abstract
Dental implants resemble synthetic materials, mainly designed as teeth-mimics to replace the damaged or irregular teeth. Specifically, they are demarcated as a surgical fixture of artificial implant materials, which are placed into the jawbone, and are allowed to be fused with the bone, similar to natural teeth. Dental implants may be categorized into endosteal, subperiosteal, and zygomatic classes, based on the placement of the implant “in the bone” or on top of the jawbone, under the gum tissue. In general, titanium and its alloys have found everyday applications as common, successful dental implant materials. However, these materials may also undergo corrosion and wear, which can lead to degradation into their ionic states, deposition in the surrounding tissues, as well as inflammation. Consequently, nanomaterials are recently introduced as a potential alternative to replace the conventional titanium-based dental implants. However, nanomaterials synthesized via physical and chemical approaches are either costly, non/less biocompatible, or toxic to the bone cells. Hence, biosynthesized nanomaterials, or bionanomaterials, are proposed in recent studies as potential non-toxic dental implant candidates. Further, nanobiomaterials with plant origins, such as nanocelluloses, nanometals, nanopolymers, and nanocarbon materials, are identified to possess enhanced biocompatibility, bioavailability and no/less cytotoxicity with antimicrobial efficacy at low costs and ease of fabrication. In this minireview, we present an outline of recent nanobiomaterials that are extensively investigated for dental implant applications. Additionally, we discuss their action mechanisms, applicability, and significance as dental implants, shortcomings, and future perspectives.
Highlights
Implants are synthetic components that are placed in a living organism as a replacement for a damaged part and eventually supports the normal activity of the organism (Prakasam et al, 2017)
Due to the recent advantages in biomedical science and surgical techniques, dental implants are defined as a surgical fixture of artificial implant material, which are placed into the jawbone and are allowed to be fused with the bone, similar to a natural teeth (Huang et al, 2017)
It is noteworthy that noteworthy in vitro research findings and breakthroughs are increasingly being reported in the context of plant-synthesized nanobiomaterials for dental implant applications, especially as a surface modifier of implants
Summary
Implants are synthetic components that are placed in a living organism as a replacement for a damaged part and eventually supports the normal activity of the organism (Prakasam et al, 2017). Plant isolates are comprehensively employed to synthesize non-toxic nanomaterials with distinct morphologies and surface properties (Shanmuganathan et al, 2019) These plant-derived nanobiomaterials are recently under extensive research to be included as novel materials to manufacture the generation dental implants as a potential alternative for conventional implant materials (Augustine and Hasan, 2020). Metal nanomaterials, such as gold, silver, platinum, copper, and selenium possess enhanced antimicrobial properties These nanomaterials find applications in the form of an antimicrobial, surface coating substance of the conventional dental implants, to prevent them from microbial attackmediated degradation (Parnia et al, 2017). Carbon-based nanoparticles, for instance carbon nanotubes, graphene, diamond nanoparticles, and quantum dots were utilized as a coating or dental implant material These carbon nanomaterials are incorporated with metallic or polymer nanomaterials as nanocomposites to retain their mechanical properties and enhance their biological properties. Nanosized polymers or polymer matrix composites, such as natural or biopolymers namely poly (lactic acid) and chitosan, synthetic polymers including polyetheretherketone (PEEK) and glycidyl methacrylate/triethylene glycol dimethacrylate (BisGMA/TEGDMA) are widely fabricated as nanoparticles or incorporated with nanoparticles to exhibit enhanced efficiency in dental implant applications (Kadambi et al, 2021)
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