Nano-particle coated or impregnated acrylic resins in dental applications: A systematic review of in Vivo Evidence on mechanical properties, biocompatibility and clinical performance.
Parthasarthy Natarajan, Seenivasan Madhan Kumar, Shanmuganathan Natarajan, Dr K S Sridharan, Dr S Narayana Kalkura
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引用次数: 0
Abstract
Background: Acrylic resins are extensively used in prosthodontics, orthodontics and maxillofacial prosthetics due to their ease of fabrication and cost-effectiveness. However, conventional acrylic materials are susceptible to microbial colonization, mechanical deterioration and esthetic compromise. To overcome these limitations, recent research has explored the incorporation of nanoparticles into polymethyl methacrylate (PMMA)-based resins to enhance their antimicrobial efficacy, mechanical strength, biocompatibility, and long-term durability.
Methods: This systematic review was conducted according to PRISMA guidelines. An extensive literature search was performed across PubMed/MEDLINE, Scopus, Web of Science, Cochrane Library and Embase for studies published up to January 18, 2025. Only in vivo studies conducted on humans or animals evaluating nanoparticle-coated or nanoparticle-impregnated acrylic resins were included. Standalone in vitro studies were excluded. Risk of bias was assessed using Cochrane's RoB 2.0 tool for randomized controlled trials (RCTs), ROBINS-I for non-randomized studies and the SYRCLE tool for animal studies.
Results: Out of 3154 records initially identified, six studies met the eligibility criteria. The nanoparticles incorporated included silver, titanium dioxide, nanocopper, nanogold and quaternary ammonium polyethyleneimine (QPEI). All included studies reported antimicrobial activity with nanogold, nanocopper and QPEI showing sustained microbial inhibition. Mechanical outcomes varied: silver and titanium dioxide nanoparticles were associated with reduced material strength, whereas nanocopper maintained mechanical performance. Esthetic outcomes indicated that silver-based modifications caused discoloration, while nanocopper and QPEI preserved color stability.
Conclusion: Nanoparticle-modified acrylic resins exhibit enhanced antimicrobial and biocompatibility profiles with certain formulations particularly those incorporating nanocopper, nanogold and QPEI showing greater clinical potential. However, mechanical durability and esthetic alterations remain challenges especially with silver and titanium-based additives. Further well-designed, long-term randomized controlled trials are warranted to validate the clinical applicability of these nano-enhanced acrylic materials.
背景:丙烯酸树脂因其易于制造和成本效益而广泛应用于口腔修复学,正畸学和颌面修复学。然而,传统的丙烯酸材料容易受到微生物定植,机械退化和美学妥协。为了克服这些限制,最近的研究探索了将纳米颗粒掺入聚甲基丙烯酸甲酯(PMMA)基树脂中,以提高其抗菌功效、机械强度、生物相容性和长期耐久性。方法:根据PRISMA指南进行系统评价。在PubMed/MEDLINE、Scopus、Web of Science、Cochrane Library和Embase上进行了广泛的文献检索,检索截止到2025年1月18日发表的研究。仅包括对人类或动物进行的体内研究,评估纳米颗粒涂层或纳米颗粒浸渍丙烯酸树脂。排除了独立的体外研究。随机对照试验(rct)采用Cochrane的RoB 2.0工具评估偏倚风险,非随机研究采用ROBINS-I工具评估偏倚风险,动物研究采用sycle工具评估偏倚风险。结果:在最初确定的3154条记录中,有6项研究符合资格标准。纳米颗粒包括银、二氧化钛、纳米铜、纳米金和季铵聚乙烯亚胺(QPEI)。所有纳入的研究报告了纳米金、纳米铜和QPEI的抗菌活性,显示出持续的微生物抑制作用。力学结果不同:银和二氧化钛纳米粒子与材料强度降低有关,而纳米铜则保持机械性能。美学结果表明,银基改性引起变色,而纳米铜和QPEI保持了颜色稳定性。结论:纳米颗粒改性丙烯酸树脂在某些配方中表现出增强的抗菌和生物相容性,特别是那些含有纳米铜、纳米金和QPEI的配方,显示出更大的临床潜力。然而,机械耐久性和美观的改变仍然是挑战,特别是银和钛基添加剂。需要进一步精心设计的长期随机对照试验来验证这些纳米增强丙烯酸材料的临床适用性。
期刊介绍:
Journal of Oral Biology and Craniofacial Research (JOBCR)is the official journal of the Craniofacial Research Foundation (CRF). The journal aims to provide a common platform for both clinical and translational research and to promote interdisciplinary sciences in craniofacial region. JOBCR publishes content that includes diseases, injuries and defects in the head, neck, face, jaws and the hard and soft tissues of the mouth and jaws and face region; diagnosis and medical management of diseases specific to the orofacial tissues and of oral manifestations of systemic diseases; studies on identifying populations at risk of oral disease or in need of specific care, and comparing regional, environmental, social, and access similarities and differences in dental care between populations; diseases of the mouth and related structures like salivary glands, temporomandibular joints, facial muscles and perioral skin; biomedical engineering, tissue engineering and stem cells. The journal publishes reviews, commentaries, peer-reviewed original research articles, short communication, and case reports.
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