Araştırma Makalesi
BibTex RIS Kaynak Göster

Evaluation of the Effect of Light Application Techniques On Bracket-Composite Bond Strength

Yıl 2024, , 89 - 96, 30.08.2024
https://doi.org/10.52976/vansaglik.1431605

Öz

Objective: The fixed orthodontic treatment approach relies on transmitting the desired forces to the teeth through brackets attached to them. The ability of orthodontic brackets to resist forces without detachment is crucial for achieving successful outcomes. The composites used in bonding brackets to teeth exhibit polymerization-related shrinkage and stress formation, adversely affecting bond strength. Our study aims to assess the effect of different application techniques of polymerization light sources on the bond strength between brackets and composites.
Materials and Methods: For this study, premolar metal orthodontic brackets were embedded in acrylic blocks with the base portion positioned 1mm above. A 3mm high layer of an adhesive composite was applied to the bracket base surface. Polymerization was carried out using the LED light source with three available light application modes: P1 normal mode (continuous and constant light emission), P4 pulse mode (light applied intermittently at specific intervals), and P5 ramp mode (starts with low light intensity and gradually increases over time), applied for 20 seconds. Thus, a total of 45 samples were prepared, with 15 samples for each of the three light application modes. All groups were incubated in distilled water at 37°C for 24 hours. The values at the moment of rupture of the samples placed in the testing device were recorded to measure shear bond strength. The surfaces of the detached brackets were examined under a microscope, and the remaining composite amounts were scored according to the Adhesive Remnant Index (ARI).
Results: Statistical significance was observed in shear bond strength values among P1, P4, and P5 light application modes (p=0.011; p<0.05). The values for P4 light mode were not statistically significant compared to P1 light mode (p=0.542; p>0.05). The P5 ramp mode showed a higher bond strength value than the other two groups. In all three groups, more than 50% of the composite remained on the bracket surface, as examined by the Adhesive Remnant Index.
Conclusion: The P5 ramp mode, with gradually increasing light intensity in the polymerization technique, provides a better connection between brackets and composites, preventing common bracket detachment in clinically fixed orthodontic treatments and ensuring more successful and sustainable outcomes.

Kaynakça

  • Aksoy A, Şahin Ş. (2018). Ortodontide kullanılan materyallerin ve adeziv sistemlerin tutuculuklarına genel bir bakış. Black Sea Journal of Health Science, 1(3), 58-69.
  • Aktürk H, Gür G, Baltacıoğlu İH. (2014). Kompozit rezinin yüzey sertlik değerleri üzerine farklı ışık cihazlarının etkisi. Ankara Üniversitesi Diş Hekimliği Fakültesi Dergisi, 41(3), 139-144.
  • Arash V, Naghipour F, Ravadgar M, Karkhah A, Barati MS. (2017). Shear bond strength of ceramic and metallic orthodontic brackets bonded with self-etching primer and conventional bonding adhesives. Electron Physician, 9(1), 3584–3591.
  • Armellin E, Bovesecchi G, Coppa P, Pasquantonio G, Cerroni L. (2016). LED curing lights and temperature changes in diferent tooth sites. Biomedical Research International, 2016:1894672.
  • Årtun J, Bergland S. (1984). Clinical trials with crystal growth conditioning as an alternative to acid-etch enamel pretreatment. American Journal of Orthodontics, 85(4), 333-40.
  • Balakrishnan A, Antony V, Shaloob M, Roshan G, Nayaz M, Parayaruthottam P et al. (2022). Effect of different light-tip distances on shear bond strength of orthodontic brackets cured with light-emitting diode and highintensity light-emitting diode. Journal of Contemporary Dental Practice, 23(8), 775–780.
  • Bektaş ÖÖ. (2006). Farklı Işık Kaynaklarının Ve Işık Uygulama Tekniklerinin Kompozit Rezinlerdeki Polimerizasyon Büzülmesi ve Dentine Bağlanma Dayanımlarına Etkisinin İncelenmesi. Doktora Tezi, Cumhuriyet Üniversitesi, Sağlık Bilimleri Enstitüsü, Sivas.
  • Bektas Ö, Eren D, Herguner Siso S, Akin GE. (2012). Effect of thermocycling on the bond strength of composite resin to bur and laser treated composite resin. Lasers in Medical Science, 27(4), 723-728.
  • Bektaş Ö, Siso ŞH, Eren D. (2006). Işık kaynakları polimerizasyon ve klinik uygulamalar. Ege Üniversitesi Diş Hekimliği Fakültesi Dergisi, 27(2), 117-124.
  • Caughman WF, Rueggeberg FA. (2002). Shedding new light on composite polymerization. Operative Dentistry, 27(6), 636-8.
  • Chapman JL. (2011). Bond failure rates of two self-ligating brackets: a randomised clinical trial. Australasian Orthodontic Journal, 27(2), 139–144.
  • Condo R, Mampieri G, Ciof A, Cataldi ME, Frustaci I, Giancotti A et al. (2021). Physical and chemical mechanisms involved in adhesion of orthodontic bonding composites: in vitro evaluations. BMC Oral Health, 21,350
  • Finnema KJ, Özcan M, Post WJ, Ren Y, Dijkstra PU. (2010). In-vitro orthodontic bond strength testing: a systematic review and meta-analysis. American Journal of Orthodontics and Dentofacial Orthopedics, 137(5), 615-622.
  • Gonçalves F, Azevedo CL, Ferracane JL, Braga RR. (2011). BisGMA/TEGDMA ratio and filler content effects on shrinkage stress. Dental Materials, 27(6), 520-526.
  • Hajrassie MK, Kheir SE. (2007). In-vivo and in-vitro comparison of bond strengths of orthodontic brackets bonded to enamel and debonded at various times. American Journal of Orthodontics and Dentofacial Orthopedics, 131, 384-390.
  • Harari D, Aunni E, Gillis I, Redlich M. (2000). A new multipurpose dental adhesive for orthodontic use: in vitro bond-strength study. American Journal of Orthodontics Dentofacial Orthopedics, 118(3), 307-310.
  • Heintze SD. (2013). Clinical relevance of tests on bond strength, microleakage and marginal adaptation. Dental Material, 29(1), 59–84.
  • Hellak A, Ebeling J, Schauseil M, Stein S, Roggendorf M, Korbmacher Steiner H. (2016). Shear bond strength of three orthodontic bonding systems on enamel and restorative materials. Biomedical Research International, 6307107. 27
  • Hu B, Hu Y, Li X, Gao J, Sun R, Zhan D et al. (2022). Shear bond strength of different bonding agents to orthodontic metal bracket and zirconia. Dental Materials Journal, 41(5), 749–756.
  • Ilie N, Kunzelmann KH, Hickel R. (2006). Evaluation of micro-tensile bond strengths of composite materials in comparison to their polymerization shrinkage. Dental Materials, 22(7), 593-601.
  • Ishida K, Endo T, Shinkai K, Katoh Y. (2011). Shear bond strength of rebonded brackets after removal of adhesives with Er, Cr:YSGG. Laser. Odontology, 99(2), 129–134.
  • Jafarzadeh Kashi TS, Erfan M, Rakhshan V, Aghabaigi N, Tabatabaei FS. (2011). An in vitro assessment of the effects of three surface treatments on repair bond strength of aged composites. Operative Dentistry, 36(6), 608-17.
  • Kanashiro LK, Robles-Ruíz JJ, Ciamponi AL, Medeiros IS, Tortamano A, JB Paiva. (2014). Infuence of diferent methods of cleaning custom bases on the shear bond strength of indirectly bonded brackets. Journal of Orthodontics, 41(3), 175–180.
  • Katona TR, Chen J. (1994). Engineering and experimental analyses of the tensile loads applied during strength testing of direct bonded orthodontic brackets. American Journal of Orthodontics Dentofacial Orthopedics, 106(2), 167–174.
  • Katona TR, Moore BK. (1994). The efects of load misalignment on tensile load testing of direct bonded orthodontic brackets–a fnite element model. American Journal of Orthodontics Dentofacial Orthopedics, 105(6), 543–551
  • Katona TR. (1997). A comparison of the stresses developed in tension, shear peel, and torsion strength testing of direct bonded orthodontic brackets. American Journal of Orthodontics Dentofacial Orthopedics, 112(3), 244–251.
  • Keim RG, Gottlieb EL, Nelson AH. (2002). JCO study of orthodontic diagnosis and treatment procedures. Journal of Clinical Orhodontics, 36(10), 553-568.
  • Kiomarsi N, Saburian P, Chiniforush N, Karazifard MJ, Hashemikamangar SS. (2017). Effect of thermocycling and surface treatment on repair bond strength of composite. Journal of Clinical and Experimental Dentistry, 9(8), 945-951.
  • Knox J, Hubsch P, Jones ML, Middleton J. (2000). The influence of bracket base design on the strength of the bracket cement interface. Journal of Orthodontics, 27(3), 249-54.
  • Koran P, Kurschner R. (1998). Effect of sequential versus continuous irradiation of a light-cured resin composite on shrinkage, viscosity, adhesion, and degree of polymerization. American Journal of Dentistry, 11(1), 17-22.
  • Kwon Y, Ferracane J, Lee IB. (2012). Effect of layering methods, composite type, and flowable liner on the polymerization shrinkage stress of light cured composites. Dental Materials, 28(7), 801-809.
  • Mc Court JW, Cooley RL, Barnwell S. (1991). Bond strength of light cure fluoride-releasing base- liners as orthodontic bracket adhesives. American Journal of Orthodontics and Dentofacial Orthopedics, 100, 47-52.
  • Mehl A, Hickel R, Kunzelmann KH (1997). Physical properties and gap formation of light-cured composites with and without 'softstart-polymerization. Journal of Dentistry, 25(3-4), 321-330.
  • Obici AC, Sinhoreti MA, de Goes MF, Consani S, Sobrinho LC. (2002). Effect of the photo-activation method on polymerization shrinkage of restorative composites. Operative Dentistry, 27(2), 192-198.
  • Pakshir HR, Zarif Najaf H, Hajipour S. (2012). Efect of enamel surface treatment on the bond strength of metallic brackets in rebonding process. European Journal of Orthodontics, 34(6), 773–777.
  • Pamukcu H, Ozsoy OP, Dagalp R. (2018). In vitro and in vivo comparison of orthodontic indirect bonding resins: a prospective study. Niger Journal of Clinical Practice. 21(5), 614–623.
  • Porto IC, Soares LE, Martin AA, Cavalli V, Liporoni PC. (2010). Infuence of the photoinitiator system and light photoactivation units on the degree of conversion of dental composites. Brazilian Oral Research, 24(4), 475–481
  • Prylińska-Czyżewska A, Maciejewska-Szaniec Z, Olszewska A, Polichnowska M, Grabarek BO, Dudek D et al. (2022). Comparison of bond strength of orthodontic brackets onto the tooth enamel of 120 freshly extracted adult bovine medial lower incisors using 4 adhesives: A resin-modified glass ionomer adhesive, a composite adhesive, a liquid composite adhesive, and a one-step light-cured adhesive. Medical Science Monitor, 28, e938867
  • Romano FL, Valério RA, Gomes-Silva JM, Ferreira JT, Faria G, Borsatto MC. (2012). Clinical evaluation of the failure rate of metallic brackets bonded with orthodontic composites. Brazilian Dental Journal, 23(4), 399–402.
  • Rueggeberg FA, Jordan DM. (1993). Effect of light-tip distance on polymerization of resin composite. International Journal of Prosthodontics, 6(4), 364–370.
  • Sakaguchi RL, Berge HX. (1998). Reduced light energy density decreases post-gel contraction while maintaining degree of conversion in composites. Journal of Dentistry, 26(8), 695-700.
  • Sakaguchi R. (2012). Fundamentals of materials science. In: Sakaguchi RL, Powers JM (Editors). Craigs’s Restorative Dental Materials. 13th edition, Philadelphia, Mosby, 33-81.
  • Schneider LF, Cavalcante, LM, Silikas N. (2010). Shrinkage Stresses Generated during Resin-Composite Applications: A Review. Journal of Dental Biomechanics, 1-14.
  • Sturdevant C, Roberson T, Heuman H, Sturdevant J. (1995). The art and science of operative dentistry. Mosby: St. Louis.
  • Sunna S, Rock WP. (1998). Clinical performance of orthodontic brackets and adhesive systems: a randomized clinical trial. British Journal of Orthodontics, 25, 283-287.
  • Tezcanlı O. (2022). Ortodontide Kompozit Yüzeylere Bağlanma: Farklı Materyal ve Yüzey Değişikliği Uygulamalarının Metal ve Seramik Braketlerin Basma Dayanıklılığı Üzerine Etkileri. Bitirme Tezi, İstanbul Üniversitesi, Diş Hekimliği Fakültesi, İstanbul. Valizadeh S, Alimohammadi G, Nik TH, Etemadi A, Tanbakuchi B. (2020). In vitro evaluation of shear bond strength of orthodontic metal brackets to aged composite using a self-adhesive composite: Effect of surface conditioning and different bonding agents. International Orthodontics, 18(3), 528-537.
  • Vattaparambil S, Shaloob M, Antony V, Roshan G, Parayaruthottam P, Odayappurath MJ. (2022). Influence of primer pre-curing and co-curing on shear bond strength of orthodontic brackets using three light-cure. The Journal of Contemporary Dental Practice, 23(9), 900–906.
  • Toodehzaeim MH, Kazemi, AD, Aghili, HA, Barzegar K, Fallahtafti T. (2012). Comparison of shear bond strength of orthodontic brackets bonded with halogen and plasma arc light curing. Dental Research Journal, 9(3), 361-367.
  • Yap AU, Ng SC, Siow KS. (2001). Soft-start polymerization: influence on effectiveness of cure and post-gel shrinkage. Operative Dentistry, 26(3), 260-266

Işık Uygulama Tekniklerinin Braket-Kompozit Bağlanma Dayanımına Etkisinin Değerlendirilmesi

Yıl 2024, , 89 - 96, 30.08.2024
https://doi.org/10.52976/vansaglik.1431605

Öz

Amaç: Sabit ortodontik tedavi yaklaşımı, dişlere yapıştırılan braketler aracılığıyla tedavi için istenen kuvvetlerin dişlere iletilmesi esasına dayanır. Ortodontik braketlerin tedavi süresince maruz kalacağı kuvvetlere karşı kopmadan direnç göstermesi başarılı sonuçlar elde etmek açısından önemlidir. Braketlerin dişlere yapıştırılmasında kullanılan kompozitlerin polimerizasyona bağlı büzülme ve stres oluşumu bağlanma dayanımını olumsuz etkilemektedir. Çalışmamız, polimerizasyon ışık kaynağının farklı uygulama tekniklerini kullanarak braket ile kompozit arasındaki bağlanma dayanımına etkisini değerlendirmeyi amaçlamaktadır.
Materyal ve Metot: Çalışma için premolar metal ortodontik braketler (Leone 0, 0018’slot, İtalya) taban kısmı 1mm yukarıda kalacak şekilde akrilik bloklara gömülmüştür. Braket taban yüzeyine 3mm yükseklikte Transbond XT (3M Unitek Monrovia, CA, ABD) yapıştırıcı kompozit yerleştirilmiştir. Polimerizasyon için LED (Eighteeth CuringPen-E) ışık kaynağının mevcut üç ışık uygulama modu; P1 normal mod (sürekli ve sabit bir ışık yayma durumu), P4 pulse mod (ışık, belirli aralıklarla kesintili uygulanır) ve P5 ramp modu (düşük bir ışık şiddetiyle başlar ve zamanla bu şiddeti artar) seçilerek 20 saniye boyunca ışık uygulanmıştır. Böylece bu üç ışık uygulama modunda 15’er örnek olmak üzere toplamda 45 örnek hazırlanmıştır. Tüm gruplar 24 saat 37°C’de distile suda etüvde bekletilmiştir. Kesme bağlanım kuvvetlerini ölçmek için test cihazına (Bisco, Inc. Schaumburg, A.B.D) yerleştirilen örneklerin kopma anındaki değerleri kaydedilmiştir. Kopan braketlerin yüzeyi bir mikroskop (Mitutoyo, Japonya) altında incelenerek Artık Adeziv İndeksine (AAİ) göre kalan kompozit miktarları skorlanmıştır.
Bulgular: P1, P4 ve P5 ışık uygulama modlarında kesme bağlanma kuvvetleri arasında istatistiksel olarak anlamlı farklılık saptanmıştır (p=0,011; p<0,05). P1 ışık moduna göre P4 ışık modu değerleri istatistiksel olarak anlamlı bulunmamıştır (p=0,542; p>0,05). P5 ramp modu diğer iki gruptan daha yüksek bağlanma değeri göstermiştir. Adeziv Artık İndeksine göre incelen braket yüzeylerinde her üç grupta da kompozitin %50 sinden fazlası braket yüzeyinde kalmıştır.
Sonuç: P5 ramp modu ışık şiddetinin giderek arttığı polimerizasyon tekniğinde braket-kompozit arasında daha iyi bir bağlantı sağlanması ile klinik olarak sabit ortodontik tedavilerde sık karşılaşılan braketlerin kopmasının önüne geçilerek daha başarılı tedaviler sürdürülebilir.

Kaynakça

  • Aksoy A, Şahin Ş. (2018). Ortodontide kullanılan materyallerin ve adeziv sistemlerin tutuculuklarına genel bir bakış. Black Sea Journal of Health Science, 1(3), 58-69.
  • Aktürk H, Gür G, Baltacıoğlu İH. (2014). Kompozit rezinin yüzey sertlik değerleri üzerine farklı ışık cihazlarının etkisi. Ankara Üniversitesi Diş Hekimliği Fakültesi Dergisi, 41(3), 139-144.
  • Arash V, Naghipour F, Ravadgar M, Karkhah A, Barati MS. (2017). Shear bond strength of ceramic and metallic orthodontic brackets bonded with self-etching primer and conventional bonding adhesives. Electron Physician, 9(1), 3584–3591.
  • Armellin E, Bovesecchi G, Coppa P, Pasquantonio G, Cerroni L. (2016). LED curing lights and temperature changes in diferent tooth sites. Biomedical Research International, 2016:1894672.
  • Årtun J, Bergland S. (1984). Clinical trials with crystal growth conditioning as an alternative to acid-etch enamel pretreatment. American Journal of Orthodontics, 85(4), 333-40.
  • Balakrishnan A, Antony V, Shaloob M, Roshan G, Nayaz M, Parayaruthottam P et al. (2022). Effect of different light-tip distances on shear bond strength of orthodontic brackets cured with light-emitting diode and highintensity light-emitting diode. Journal of Contemporary Dental Practice, 23(8), 775–780.
  • Bektaş ÖÖ. (2006). Farklı Işık Kaynaklarının Ve Işık Uygulama Tekniklerinin Kompozit Rezinlerdeki Polimerizasyon Büzülmesi ve Dentine Bağlanma Dayanımlarına Etkisinin İncelenmesi. Doktora Tezi, Cumhuriyet Üniversitesi, Sağlık Bilimleri Enstitüsü, Sivas.
  • Bektas Ö, Eren D, Herguner Siso S, Akin GE. (2012). Effect of thermocycling on the bond strength of composite resin to bur and laser treated composite resin. Lasers in Medical Science, 27(4), 723-728.
  • Bektaş Ö, Siso ŞH, Eren D. (2006). Işık kaynakları polimerizasyon ve klinik uygulamalar. Ege Üniversitesi Diş Hekimliği Fakültesi Dergisi, 27(2), 117-124.
  • Caughman WF, Rueggeberg FA. (2002). Shedding new light on composite polymerization. Operative Dentistry, 27(6), 636-8.
  • Chapman JL. (2011). Bond failure rates of two self-ligating brackets: a randomised clinical trial. Australasian Orthodontic Journal, 27(2), 139–144.
  • Condo R, Mampieri G, Ciof A, Cataldi ME, Frustaci I, Giancotti A et al. (2021). Physical and chemical mechanisms involved in adhesion of orthodontic bonding composites: in vitro evaluations. BMC Oral Health, 21,350
  • Finnema KJ, Özcan M, Post WJ, Ren Y, Dijkstra PU. (2010). In-vitro orthodontic bond strength testing: a systematic review and meta-analysis. American Journal of Orthodontics and Dentofacial Orthopedics, 137(5), 615-622.
  • Gonçalves F, Azevedo CL, Ferracane JL, Braga RR. (2011). BisGMA/TEGDMA ratio and filler content effects on shrinkage stress. Dental Materials, 27(6), 520-526.
  • Hajrassie MK, Kheir SE. (2007). In-vivo and in-vitro comparison of bond strengths of orthodontic brackets bonded to enamel and debonded at various times. American Journal of Orthodontics and Dentofacial Orthopedics, 131, 384-390.
  • Harari D, Aunni E, Gillis I, Redlich M. (2000). A new multipurpose dental adhesive for orthodontic use: in vitro bond-strength study. American Journal of Orthodontics Dentofacial Orthopedics, 118(3), 307-310.
  • Heintze SD. (2013). Clinical relevance of tests on bond strength, microleakage and marginal adaptation. Dental Material, 29(1), 59–84.
  • Hellak A, Ebeling J, Schauseil M, Stein S, Roggendorf M, Korbmacher Steiner H. (2016). Shear bond strength of three orthodontic bonding systems on enamel and restorative materials. Biomedical Research International, 6307107. 27
  • Hu B, Hu Y, Li X, Gao J, Sun R, Zhan D et al. (2022). Shear bond strength of different bonding agents to orthodontic metal bracket and zirconia. Dental Materials Journal, 41(5), 749–756.
  • Ilie N, Kunzelmann KH, Hickel R. (2006). Evaluation of micro-tensile bond strengths of composite materials in comparison to their polymerization shrinkage. Dental Materials, 22(7), 593-601.
  • Ishida K, Endo T, Shinkai K, Katoh Y. (2011). Shear bond strength of rebonded brackets after removal of adhesives with Er, Cr:YSGG. Laser. Odontology, 99(2), 129–134.
  • Jafarzadeh Kashi TS, Erfan M, Rakhshan V, Aghabaigi N, Tabatabaei FS. (2011). An in vitro assessment of the effects of three surface treatments on repair bond strength of aged composites. Operative Dentistry, 36(6), 608-17.
  • Kanashiro LK, Robles-Ruíz JJ, Ciamponi AL, Medeiros IS, Tortamano A, JB Paiva. (2014). Infuence of diferent methods of cleaning custom bases on the shear bond strength of indirectly bonded brackets. Journal of Orthodontics, 41(3), 175–180.
  • Katona TR, Chen J. (1994). Engineering and experimental analyses of the tensile loads applied during strength testing of direct bonded orthodontic brackets. American Journal of Orthodontics Dentofacial Orthopedics, 106(2), 167–174.
  • Katona TR, Moore BK. (1994). The efects of load misalignment on tensile load testing of direct bonded orthodontic brackets–a fnite element model. American Journal of Orthodontics Dentofacial Orthopedics, 105(6), 543–551
  • Katona TR. (1997). A comparison of the stresses developed in tension, shear peel, and torsion strength testing of direct bonded orthodontic brackets. American Journal of Orthodontics Dentofacial Orthopedics, 112(3), 244–251.
  • Keim RG, Gottlieb EL, Nelson AH. (2002). JCO study of orthodontic diagnosis and treatment procedures. Journal of Clinical Orhodontics, 36(10), 553-568.
  • Kiomarsi N, Saburian P, Chiniforush N, Karazifard MJ, Hashemikamangar SS. (2017). Effect of thermocycling and surface treatment on repair bond strength of composite. Journal of Clinical and Experimental Dentistry, 9(8), 945-951.
  • Knox J, Hubsch P, Jones ML, Middleton J. (2000). The influence of bracket base design on the strength of the bracket cement interface. Journal of Orthodontics, 27(3), 249-54.
  • Koran P, Kurschner R. (1998). Effect of sequential versus continuous irradiation of a light-cured resin composite on shrinkage, viscosity, adhesion, and degree of polymerization. American Journal of Dentistry, 11(1), 17-22.
  • Kwon Y, Ferracane J, Lee IB. (2012). Effect of layering methods, composite type, and flowable liner on the polymerization shrinkage stress of light cured composites. Dental Materials, 28(7), 801-809.
  • Mc Court JW, Cooley RL, Barnwell S. (1991). Bond strength of light cure fluoride-releasing base- liners as orthodontic bracket adhesives. American Journal of Orthodontics and Dentofacial Orthopedics, 100, 47-52.
  • Mehl A, Hickel R, Kunzelmann KH (1997). Physical properties and gap formation of light-cured composites with and without 'softstart-polymerization. Journal of Dentistry, 25(3-4), 321-330.
  • Obici AC, Sinhoreti MA, de Goes MF, Consani S, Sobrinho LC. (2002). Effect of the photo-activation method on polymerization shrinkage of restorative composites. Operative Dentistry, 27(2), 192-198.
  • Pakshir HR, Zarif Najaf H, Hajipour S. (2012). Efect of enamel surface treatment on the bond strength of metallic brackets in rebonding process. European Journal of Orthodontics, 34(6), 773–777.
  • Pamukcu H, Ozsoy OP, Dagalp R. (2018). In vitro and in vivo comparison of orthodontic indirect bonding resins: a prospective study. Niger Journal of Clinical Practice. 21(5), 614–623.
  • Porto IC, Soares LE, Martin AA, Cavalli V, Liporoni PC. (2010). Infuence of the photoinitiator system and light photoactivation units on the degree of conversion of dental composites. Brazilian Oral Research, 24(4), 475–481
  • Prylińska-Czyżewska A, Maciejewska-Szaniec Z, Olszewska A, Polichnowska M, Grabarek BO, Dudek D et al. (2022). Comparison of bond strength of orthodontic brackets onto the tooth enamel of 120 freshly extracted adult bovine medial lower incisors using 4 adhesives: A resin-modified glass ionomer adhesive, a composite adhesive, a liquid composite adhesive, and a one-step light-cured adhesive. Medical Science Monitor, 28, e938867
  • Romano FL, Valério RA, Gomes-Silva JM, Ferreira JT, Faria G, Borsatto MC. (2012). Clinical evaluation of the failure rate of metallic brackets bonded with orthodontic composites. Brazilian Dental Journal, 23(4), 399–402.
  • Rueggeberg FA, Jordan DM. (1993). Effect of light-tip distance on polymerization of resin composite. International Journal of Prosthodontics, 6(4), 364–370.
  • Sakaguchi RL, Berge HX. (1998). Reduced light energy density decreases post-gel contraction while maintaining degree of conversion in composites. Journal of Dentistry, 26(8), 695-700.
  • Sakaguchi R. (2012). Fundamentals of materials science. In: Sakaguchi RL, Powers JM (Editors). Craigs’s Restorative Dental Materials. 13th edition, Philadelphia, Mosby, 33-81.
  • Schneider LF, Cavalcante, LM, Silikas N. (2010). Shrinkage Stresses Generated during Resin-Composite Applications: A Review. Journal of Dental Biomechanics, 1-14.
  • Sturdevant C, Roberson T, Heuman H, Sturdevant J. (1995). The art and science of operative dentistry. Mosby: St. Louis.
  • Sunna S, Rock WP. (1998). Clinical performance of orthodontic brackets and adhesive systems: a randomized clinical trial. British Journal of Orthodontics, 25, 283-287.
  • Tezcanlı O. (2022). Ortodontide Kompozit Yüzeylere Bağlanma: Farklı Materyal ve Yüzey Değişikliği Uygulamalarının Metal ve Seramik Braketlerin Basma Dayanıklılığı Üzerine Etkileri. Bitirme Tezi, İstanbul Üniversitesi, Diş Hekimliği Fakültesi, İstanbul. Valizadeh S, Alimohammadi G, Nik TH, Etemadi A, Tanbakuchi B. (2020). In vitro evaluation of shear bond strength of orthodontic metal brackets to aged composite using a self-adhesive composite: Effect of surface conditioning and different bonding agents. International Orthodontics, 18(3), 528-537.
  • Vattaparambil S, Shaloob M, Antony V, Roshan G, Parayaruthottam P, Odayappurath MJ. (2022). Influence of primer pre-curing and co-curing on shear bond strength of orthodontic brackets using three light-cure. The Journal of Contemporary Dental Practice, 23(9), 900–906.
  • Toodehzaeim MH, Kazemi, AD, Aghili, HA, Barzegar K, Fallahtafti T. (2012). Comparison of shear bond strength of orthodontic brackets bonded with halogen and plasma arc light curing. Dental Research Journal, 9(3), 361-367.
  • Yap AU, Ng SC, Siow KS. (2001). Soft-start polymerization: influence on effectiveness of cure and post-gel shrinkage. Operative Dentistry, 26(3), 260-266
Toplam 49 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Ortodonti ve Dentofasiyal Ortopedi, Protez
Bölüm Orijinal Araştırma Makaleleri
Yazarlar

Kader Tatar 0000-0002-9320-1500

Saadet Çınarsoy Ciğerim 0000-0002-4384-0929

Hüseyin Melik Böyük 0000-0002-5846-3177

Gönül Dinç 0000-0003-4699-1543

Jamil Bayzed 0000-0003-2102-2017

Yayımlanma Tarihi 30 Ağustos 2024
Gönderilme Tarihi 4 Şubat 2024
Kabul Tarihi 15 Haziran 2024
Yayımlandığı Sayı Yıl 2024

Kaynak Göster

APA Tatar, K., Çınarsoy Ciğerim, S., Böyük, H. M., Dinç, G., vd. (2024). Işık Uygulama Tekniklerinin Braket-Kompozit Bağlanma Dayanımına Etkisinin Değerlendirilmesi. Van Sağlık Bilimleri Dergisi, 17(2), 89-96. https://doi.org/10.52976/vansaglik.1431605

ISSN 

images?q=tbn:ANd9GcQBnZPknmjKO2vn7ExYwjsL0g4cijty6VTFQQ&usqp=CAU CABI-Logo_Accessible_RGB.png  logo-e1506365530266.png ici2.png 

8c492a0a466f9b2cd59ec89595639a5c?AccessKeyId=245B99561176BAE11FEB&disposition=0&alloworigin=1asos-index.png  Root Indexing    ResearchBib BASE Logo      


Creative Commons Lisansı

Van Health Sciences Journal (Van Sağlık Bilimleri Dergisi) başlıklı eser bu Creative Commons Atıf-Gayri Ticari 4.0 Uluslararası Lisansı ile lisanslanmıştır.

  open-access-logo.png  search-result-logo-horizontal-TEST.jpg