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The size effects of micron particles on the physico-mechanical properties of resinous composites containing inorganic-organic dual fillers

Yıl 2023, Cilt: 6 Sayı: 1, 8 - 15, 28.03.2023
https://doi.org/10.56150/tjhsl.1207922

Öz

In this study, thermal polymerized resinous composites containing inorganic-organic dual fillers were developed. The size effects of micron particles on the physico-mechanical properties of composites were investigated. According to the standard BS EN ISO 4049, the degree of transformation, hardness, three-point flexural strength, water absorption and water solubility of the prepared composite materials were determined. Contrary to expectations, the degree of transformation of the composites increased as the micron particle size increased. It has been deduced that this increase is directly related to the varying surface areas depending on the particle sizes and the modification rates that can vary depending on the surface areas. The hardness values did not show a general trend with increasing particle size. When the flexural strengths of composites containing varying micron size particles were examined, their strengths differed in relation to the degree of transformation and the rate of modification, which is also effective in hardness. As with other properties, the effects of competing particle size and rate of modification had an effect on the absorption behavior. When the resolutions of the composites are examined, the values of all are positive. It was concluded that this situation may be due to the absence of polar groups in the main monomer structure other than ester, hydroxyl and urethane groups, which will keep the absorbed water in the structure, and the release of unreacted monomers with the absorbed water.

Kaynakça

  • 1. Yoon J, Lee JH, Lee JB, Lee JH. Highly scattering hierarchical porous polymer microspheres with a high-refractive index inorganic surface for a soft-focus effect. Polymers. 2020;12(10):2418.
  • 2. Kundie F, Azhari CH, Muchtar A, Ahmad ZA. Effects of filler size on the mechanical properties of polymer-filled dental composites: A review of recent developments. Journal of Physical Science. 2018;29(1):141-65.
  • 3. Kondo Y, Takagaki T, Okuda M, Ikeda M, Kadoma Y, Yamauchi J, et al. Effect of PMMA filler particles addition on the physical properties of resin composite. Dental Materials Journal. 2010:1008270069-.
  • 4. Chen H, Wang R, Qian L, Ren Q, Jiang X, Zhu M. Dental restorative resin composites: modification technologies for the matrix/filler interface. Macromolecular Materials and Engineering. 2018;303(10):1800264.
  • 5. Sideridou ID, Karabela MM. Effect of the amount of 3-methacyloxypropyltrimethoxysilane coupling agent on physical properties of dental resin nanocomposites. Dental Materials. 2009;25(11):1315-24.
  • 6. Xia Y, Zhang F, Xie H, Gu N. Nanoparticle-reinforced resin-based dental composites. Journal of dentistry. 2008;36(6):450-5.
  • 7. Lung CYK, Sarfraz Z, Habib A, Khan AS, Matinlinna JP. Effect of silanization of hydroxyapatite fillers on physical and mechanical properties of a bis-GMA based resin composite. Journal of the mechanical behavior of biomedical materials. 2016;54:283-94.
  • 8. Yeşil Acar Z, Tunç Koçyiğit M, Asiltürk M. Development of nanohybrid dental composite containing mesoporous carrier silica particles: Synthesis particles, determination of fluoride adsorption capacities, and addition of the composite. Polymer Composites. 2022;43(11):8545-59.
  • 9. Standard B. BS EN ISO 4049: 2019. Dentistry-Polymer-Based Restorative Materials; BSI Standards Limited: London, UK. 2019.
  • 10. Pirmoradian M, Hooshmand T, Jafari-Semnani S, Fadavi F. Degree of conversion and microhardness of bulk-fill dental composites polymerized by LED and QTH light curing units. Journal of Oral Biosciences. 2020;62(1):107-13.
  • 11. Marovic D, Panduric V, Tarle Z, Ristic M, Sariri K, Demoli N, et al. Degree of conversion and microhardness of dental composite resin materials. Journal of molecular structure. 2013;1044:299-302.
  • 12. Bayraktar ET, Atali PY, Korkut B, Kesimli EG, Tarcin B, Turkmen C. Effect of modeling resins on microhardness of resin composites. European journal of dentistry. 2021;15(03):481-7.
  • 13. Alrahlah A, Khan R, Vohra F, Alqahtani IM, Alruhaymi AA, Haider S, et al. Influence of the Physical Inclusion of ZrO2/TiO2 Nanoparticles on Physical, Mechanical, and Morphological Characteristics of PMMA-Based Interim Restorative Material. BioMed Research International. 2022;2022.
  • 14. Razali R, Rahim N, Zainol I, Sharif A, editors. Preparation of dental composite using hydroxyapatite from natural sources and silica. Journal of Physics: Conference Series; 2018: IOP Publishing.
  • 15. Karabela MM, Sideridou ID. Synthesis and study of properties of dental resin composites with different nanosilica particles size. Dental materials. 2011;27(8):825-35.
  • 16. Gajapriya M, Jayalakshmi S, Geetha R. Fillers in composite resins-recent advances. European Journal of Molecular & Clinical Medicine. 2020;7(01):971-7.
  • 17. Acar ZY. Antibakteriyel ve hidrofob özellikli yeni nesil kompozit yapay diş geliştirilmesi. 2018.
Yıl 2023, Cilt: 6 Sayı: 1, 8 - 15, 28.03.2023
https://doi.org/10.56150/tjhsl.1207922

Öz

Kaynakça

  • 1. Yoon J, Lee JH, Lee JB, Lee JH. Highly scattering hierarchical porous polymer microspheres with a high-refractive index inorganic surface for a soft-focus effect. Polymers. 2020;12(10):2418.
  • 2. Kundie F, Azhari CH, Muchtar A, Ahmad ZA. Effects of filler size on the mechanical properties of polymer-filled dental composites: A review of recent developments. Journal of Physical Science. 2018;29(1):141-65.
  • 3. Kondo Y, Takagaki T, Okuda M, Ikeda M, Kadoma Y, Yamauchi J, et al. Effect of PMMA filler particles addition on the physical properties of resin composite. Dental Materials Journal. 2010:1008270069-.
  • 4. Chen H, Wang R, Qian L, Ren Q, Jiang X, Zhu M. Dental restorative resin composites: modification technologies for the matrix/filler interface. Macromolecular Materials and Engineering. 2018;303(10):1800264.
  • 5. Sideridou ID, Karabela MM. Effect of the amount of 3-methacyloxypropyltrimethoxysilane coupling agent on physical properties of dental resin nanocomposites. Dental Materials. 2009;25(11):1315-24.
  • 6. Xia Y, Zhang F, Xie H, Gu N. Nanoparticle-reinforced resin-based dental composites. Journal of dentistry. 2008;36(6):450-5.
  • 7. Lung CYK, Sarfraz Z, Habib A, Khan AS, Matinlinna JP. Effect of silanization of hydroxyapatite fillers on physical and mechanical properties of a bis-GMA based resin composite. Journal of the mechanical behavior of biomedical materials. 2016;54:283-94.
  • 8. Yeşil Acar Z, Tunç Koçyiğit M, Asiltürk M. Development of nanohybrid dental composite containing mesoporous carrier silica particles: Synthesis particles, determination of fluoride adsorption capacities, and addition of the composite. Polymer Composites. 2022;43(11):8545-59.
  • 9. Standard B. BS EN ISO 4049: 2019. Dentistry-Polymer-Based Restorative Materials; BSI Standards Limited: London, UK. 2019.
  • 10. Pirmoradian M, Hooshmand T, Jafari-Semnani S, Fadavi F. Degree of conversion and microhardness of bulk-fill dental composites polymerized by LED and QTH light curing units. Journal of Oral Biosciences. 2020;62(1):107-13.
  • 11. Marovic D, Panduric V, Tarle Z, Ristic M, Sariri K, Demoli N, et al. Degree of conversion and microhardness of dental composite resin materials. Journal of molecular structure. 2013;1044:299-302.
  • 12. Bayraktar ET, Atali PY, Korkut B, Kesimli EG, Tarcin B, Turkmen C. Effect of modeling resins on microhardness of resin composites. European journal of dentistry. 2021;15(03):481-7.
  • 13. Alrahlah A, Khan R, Vohra F, Alqahtani IM, Alruhaymi AA, Haider S, et al. Influence of the Physical Inclusion of ZrO2/TiO2 Nanoparticles on Physical, Mechanical, and Morphological Characteristics of PMMA-Based Interim Restorative Material. BioMed Research International. 2022;2022.
  • 14. Razali R, Rahim N, Zainol I, Sharif A, editors. Preparation of dental composite using hydroxyapatite from natural sources and silica. Journal of Physics: Conference Series; 2018: IOP Publishing.
  • 15. Karabela MM, Sideridou ID. Synthesis and study of properties of dental resin composites with different nanosilica particles size. Dental materials. 2011;27(8):825-35.
  • 16. Gajapriya M, Jayalakshmi S, Geetha R. Fillers in composite resins-recent advances. European Journal of Molecular & Clinical Medicine. 2020;7(01):971-7.
  • 17. Acar ZY. Antibakteriyel ve hidrofob özellikli yeni nesil kompozit yapay diş geliştirilmesi. 2018.
Toplam 17 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Sağlık Kurumları Yönetimi
Bölüm Makaleler
Yazarlar

Zerin Yeşil Acar 0000-0002-1083-0222

Yayımlanma Tarihi 28 Mart 2023
Yayımlandığı Sayı Yıl 2023 Cilt: 6 Sayı: 1

Kaynak Göster

APA Yeşil Acar, Z. (2023). The size effects of micron particles on the physico-mechanical properties of resinous composites containing inorganic-organic dual fillers. Turkish Journal of Health Science and Life, 6(1), 8-15. https://doi.org/10.56150/tjhsl.1207922