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Contemporary aesthetic restorative dental composite materials

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: This is a review paper that gives an insight into the most popular group of aesthetic dental materials - dental composite materials. This article describes the historical background, the main features of this group of materials, the cathegorization of the materials in relation to clinical applications and the polymerization proces. Design/methodology/approach: This review is based on the contemporary scientific literature most relevant to the topic. The literature search has been made in Elsevier - Science Direct. Findings: Light-curing dental composites exhibit some resemblance to the construction of the hard tissues of the tooth. They also consist of two basic components. These are: an organic matrix and an inorganic filler. The third component, which is regularly added, is so-called "binding agent". According to the composition of the materials they make a good choice for aesthetic restoration in natural dentition. Practical implications: In the clinical observations there are many complications resulting from inadequate polymerization of composite materials. This may be the result of poor quality of curing lights of a very low intensity, too long distance between the tip of the lamp and the surface of the material or improper exposure time Originality/value: Dental composite materials are the only group of dental materials in which these features are combined together, ensuring naturally looking final effect of the restoration. Easy handling of the dental composite materials together with effective polymerization process with portable light units make these materials a good choice for clinical use.
Rocznik
Strony
32--40
Opis fizyczny
Bibliogr. 27 poz., rys.
Twórcy
autor
  • Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland
  • Health Care Centre Denticus 2, ul. Bolesława Śmiałego 28, 70-348 Szczecin, Poland
Bibliografia
  • [1] J.M. Powers, R.L. Sakaguchi, dental materials, H. Limanowska-Shaw, J. Shaw. Wrocław, Urban & Partner, 2008.
  • [2] K. Anusavice, C. Shen, H.R. Rawls, Philips’ science of dental materials, 12th edition, St. Louis: Elsevier Health Sciences, 2012.
  • [3] M.A. Saghiri, S. Banava, M.A. Sabzian et al., Correlation between long-term in vivo amalgam restorations and the presence of heavy elements in the dental pulp, Journal of Trace Elements in Medicine and Biology 28/2 (2014) 200-204.
  • [4] A.E. Papakonstantinou, T. Eliades, F. Cellesi, D.C. Watts, N. Silikas, Evaluation of UDMA’s potential as a substitute for Bis-GMA in orthodontic adhesives. Dental Materials 29/8 (2013) 898-905.
  • [5] H. Shaw, The biocompatibility of materials used in orthodontics, Allergic reactions - diagnosis and treatment, red. A. Komorowska, Materials and Technique, Lublin, Polish Orthodontic Society, 2009, (in Polish).
  • [6] Q. Chen, Y. Zhao, W. Wu, T. Xu, H. Fong, Fabrication and evaluation of Bis-GMA/TEGDMA dental resins/composites containing halloysite nanotubes, Dental Materials 28/10 (2012) 1071-1079.
  • [7] W. Świderski, Z. Czech, P. Malara, Studies on compression strength of photoreactive composite fillings cured with visible light, Chemical Industry 12 (2014) 2214-2217 (in Polish).
  • [8] I.M. Barczewska-Rybarek, Structure-property relationships in dimethacrylate networks based on BisGMA, UDMA and TEGDMA, Dental Materials 25/9 (2009) 1082-1089.
  • [9] R. Bhola, S.M. Bhola, H. Liang, B. Mishra Biocompatible denture polymers, Trends in Biomaterials & Artificial Organs 23/3 (2010) 129-136.
  • [10] W.M. Palin, G.J.P. Fleming, F.J.T. Burke, P.M. Marquis, R.C. Randall, The influence of short and medium-term water immersion on the hydrolytic stability of novel low-shrink dental composites. Dental Material 21/9 (2005) 852-863.
  • [11] D.A. Terry, W. Geller, Esthetic and restorative dentistry, Material selection and technique, Hanover Park: Quintessence Publishing, 2013.
  • [12] Z. Jańczuk, Conservative dentistry - clinical outline. Handbook for dental students, Warszawa, PZWL, 2004 (in Polish).
  • [13] P.A.F. Amato, R.P. Martins, C.A.S. Cruz, M.V. Capella, L.P. Martins, Time reduction of light curing: Influence on conversion degree and microhardness of orthodontic composites, American Journal of Orthodontics and Dentofacial Orthopedics 146/1 (2014) 40-46.
  • [14] I.M. Hammouda, Effect of light-curing method on wear and hardness of composite resin. Journal of the Mechanical Behavior of Biomedical Materials 3/2 (2010) 216-222.
  • [15] M.M. Baig, M. Mustafa, Z.A.A. Jeaidi, M. AlMuhaiza, Microleakage evaluation in restorations using different resin composite insertion techniques and liners in preparations with high c-factor - an in vitro study, Journal of King Saud University Journal of Dental Sciences 4/2 (2013) 57-64.
  • [16] C. Ganss, A. Young, A. Lussi, Tooth wear and erosion: Methodological issues in epidemiological and public health research and the future research agenda, Community Dental Health 28 (2011) 191-195.
  • [17] L.F.J. Schneider, L.M. Cavalcante, S.A. Prahl, C.S. Pfeifer, J.L. Ferracane, Curing efficiency of dental resin composites formulated with camphorquinone or trimethylbenzoyl-diphenyl-phosphine oxide, Dental Materials 28/4 (2012) 392-397.
  • [18] J.L. Ferracane, Resin composite - state of the art, Dental Materials 27/1 (2011) 29-38.
  • [19] J.G. Leprince, W.M. Palin, M.A. Hadis, J. Devaux, G. Leloup, Progress in dimethacrylate-based dental composite technology and curing efficiency, Dental Materials 29/2 (2013) 139-156.
  • [20] B. Howard, N.D. Wilson, S.M. Newman, C.S. Pfeifer, J.W. Stansbury, Relationship between conversion, temperature and optical properties during composite photopolymerization, Acta Biomaterialia 6/6 (2010) 2053-2059.
  • [21] C.S. Pfeifer, Z.R. Shelton, R.R. Braga, D. Windmoller, J.C. Machade, J.W. Stansbury, Characterization of dimethacrylate polymeric networks: A study of crosslinked structure formed by monomers used in dental composites. European Polymer Journal 47/2 (2010) 162-170.
  • [22] S. Asmusen, G. Arenas, W.D. Cook, C. Valloa, Photobleaching of camphorquinone during polymerization of dimethacrylate-based resins, Dental Material 12 (2009) 1603-1611.
  • [23] N. Fatima, Influence of extended light exposure curing times on the degree of conversion of resin-based pit and fissure sealant materials, The Saudi Dental Journal 26/4 (2014) 151-155.
  • [24] F.A. Rueggeberg, State-of-the-art: dental photocuring - a review, Dental Materials 27 (2011) 39-52.
  • [25] J.G. Leprince, M. Hadis, A.C. Shortall et al., Photoinitiatior type and applicability of exposure reciprocity law in filled and unfilled photoactive resins, Dental Materials 27/2 (2011) 157-164.
  • [26] K.D. Jandt, R.W. Mills, A brief history of LED photopolymerization, Dental Materials 29/6 (2013) 605-617.
  • [27] A. Pacyk, J. Sokołowski, H. Pawlicka, Contemporary modifications of inorganic phase compound materials in the context of the polymerization shrinkage phenomenon, e-Dentico 3/11 (2006) 54-61 (in Polish).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5038defc-4f10-4437-81d5-12adf6abe6cd
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