Pendahuluan: Resin akrilik polimerisasi panas (RAPP) merupakan bahan basis gigi tiruan yang paling banyak digunakan, namun memiliki sifat kekuatan tarik dan tekan yang rendah, sehingga diperlukan modifikasi dengan penambahan bahan penguat pada RAPP berupa aluminium oksida (Al₂O₃) atau alumina. Tujuan penelitian untuk menganalisi pengaruh penambahan aluminium oksida pada bahan basis gigi tiruan RAPP terhadap kekuatan tarik dan tekan. Metode: Jenis penelitian eksperimental laboratoris. Sebanyak 25 sampel berbentuk flat dumbbell shaped berukuran 60x12x3,9 (mm) untuk uji kekuatan tarik dan 25 sampel  berbentuk balok dengan ukuran 10x10x4 (mm) untuk uji kekuatan tekan. Pencampuran bubuk resin-aluminium oksida konsentasi 0,5%, 1,5%, 2,5% dan 3,5% dengan cairan resin dilakukan secara manual. Sampel direndam dalam air dan dimasukkan ke dalam inkubator. Uji dilakukan menggunakan universal testing machine dengan beban 1000N dan kecepatan crosshead 1mm/menit. Data dianalisis dengan uji ANOVA satu arah dan uji LSD. Hasil: Nilai kekuatan tarik kelompok kontrol dan keempat kelompok perlakuan penambahan aluminium oksida 0,5%, 1,5%, 2,5 %, 3,5% berturut turut adalah 50,867 MPa, 47,895 MPa, 45,107 MPa, 42,476 MPa, dan 39,753 MPa; sedangkan nilai kekuatan tekan kelompok kontrol dan keempat kelompok perlakuan penambahan aluminium oksida 0,5%, 1,5%, 2,5%, 3,5% berturut turut adalah 88,267 MPa, 106,085 MPa, 122,283 MPa, 135,367 MPa, dan 156,571 MPa. Penambahan bubuk aluminium oksida pada RAPP dapat menurunkan kekuatan tarik dan meningkatkan kekuatan tekan secara signifikan (p=0,0001 (p<0,05)), seiring dengan meningkatnya jumlah konsentrasi aluminium oksida yang ditambahkan. Simpulan: Penambahan aluminium oksida pada bahan basis gigi tiruan resin akrilik polimerisasi panas berpengaruh terhadap kekuatan tarik dan tekan.

Kata kunci: Resin akrilik polimerisasi panas, aluminium oksida, kekuatan tarik, kekuatan tekan.

ABSTRACT

            Introduction: Heat-polymerised acrylic resin (HPAR) is the most widely used denture base material but has a low tensile and compressive strength thus modification is needed by adding reinforcement in the form of aluminium oxide (Al₂O₃) or alumina. The research objective was to analyse the effect of adding aluminium oxide on the tensile and compressive strength of HPAR denture base material. Methods: An experimental laboratory research was conducted towards the total of 25 samples in the form of flat dumbbell shape sized 60 x 12 x 3.9 mm for the tensile strength test, and 25 samples in the form of blocks with the size of 10 x 10 x 4 mm for the compressive strength test. The mixture of powdered aluminium oxide resin with the concentrations of 0.5%, 1.5%, 2.5%, and 3.5% with a liquid resin was carried out manually. The sample was then immersed in the water and put in an incubator. The test was performed using a universal testing machine with 1000 N loads and 1 mm/minute crosshead speed. Data obtained were analysed using the one-way ANOVA and LSD test. Result: The tensile strength values of the control group and all four treatment groups added with 0.5%, 1.5%, 2.5%, and 3.5% aluminum oxide were 50.867 MPa, 47.895 MPa, 45.107 MPa, 42.4476 MPa and 39.753 MPa respectively, while the compressive strength values were 88.267 MPa, 106.085, 122.283 MPa, 135.367 MPa, and 156.571 MPa consecutively. Addition of aluminium oxide powder to the HPAR can significantly reduce the tensile and compressive strength (p = 0.0001 (p < 0.05)) along with increasing concentration. Conclusion: Addition of aluminium oxide towards the HPAR denture base affected its tensile and compressive strength.

Keywords: Heat-polymerised acrylic resin, aluminium oxide, tensile strength, compressive strength.

R Rahn A, Ivanhoe J, Plummer K. Textbook of complete dentures. 6th ed. China: People’s MEdical Publishing House. 2009: 8-9.

Alhareb A, Ahmad Z. Effect of Al2O3/ZrO2 reinforcement on the mechanical properties of PMMA denture base. J Reinf Plast Compos 2011; 30(1): 86–93.

George A, Kumar G, Pillay S, Rao S, Sangur R. Basic dental material. 2nd ed. New Delhi: Jaypee Brothers Medical Publisher. 2003: 13-7, 100-26.

Anusavice K, Shen C, Rawls H. Phillip's science of dental materials. 12th ed. Philadelphia: Elsevier. 2012: 4, 48-63.

Khindria S, Mittal S, Sukhija U. Evolution of denture base material. J Indian Prost Soc 2009; 9(2): 64–9.

Singh J, Dhiman R, Bedi R. Flexible denture base material: A viable alternative to conventional acrylic denture base material. Contemp Clin Dent 2011; 2(4): 313–7.

Arora P, Singh S, Arora V. Effect of alumina addition on properties of polymethyl methacrylate- A comprehensive review. Int J Biotech Trends Technol 2015; 9(1): 1–7.

Abdulhamed A, Mohammed A. Evaluation of thermal conductivity of alumina reinforced heat cure acrylic resin and some other properties. J Bagh Coll Dent 2010; 22(3): 1–6.

Gad M, Founda S, Al-Harbi F, Napankangas R, Raustia A. PMMA denture base material enhancement: A review of fiber, filler, and nanofiller addition. Int J Nanomedicine 2017; 12: 3801–12.

McCabe J. Applied dental material. 9th ed. UK: Blackwell Publishing Ltc. 2008: 120.

Sakaguchi R, Powers J. Craig’s restorative dental materials. 12nd ed. Texas Elsevier 2009: 84,178.

Pentapati L, Srinivas K, Shankar R, Swetha V, Krishna M. Effects of addition of aluminum oxide on flexural strength and hardness of acrylic resins. IOSR J Dent Med Sci 2017; 16(3): 1–6.

Yadav N, Elkawash H. Flexural strength of denture base resin reinforced with aluminum oxide and processed by different processing techniques. J Adv Dent Res 2011; 2(1): 33–6.

Sehajpal S, Sood V. Effect of metal filler on same physical properties of acrylic resin. J Prosthet Dent 1989; 61(6): 746–51.

Elboraey A, Dehis W, Mousa M. Flexural and tarike strength of acrylic resin denture base materials processed by three different methods. RJPBCS 2016; 7(3): 2556–62.

Alla R, Sajjan S, Alluri V, Ginjupalli K, Upadhya N. Influence of fiber reinforcement on the properties of denture base material. JBNB 2013; 4: 91–7.

Pratama A, Waskito, Syahrul. Pengaruh kekasaran permukaan terhadap kekuatan tarik baja AISI 4140. J Pendidik Teknik Mesin 2016; 1–9.

Hashem M, Alsaleem S, Assery M, Abdeslam E, Vellappally S, Anil S. A comparative study of the mechanical properties of the light-cure and conventional denture base resins. OHDM 2014; 13(2): 311–5.

Salih S, Oleiwi J, Hamad Q. Investigation of fatigue and compression strength for the PMMA reinforced by different system for denture application. Int J Biomed Mater Research 2015; 3(1): 5–13.

Ghaffari T, Hamedirad F, Ezzati B. In vitro comparison of compressive and tensile strengths of acrylic resins reinforced by silver nanoparticles at 2% and 0.2% concentrations. J Dent Res Dent Clin Dent Prospects 2014; 8(4): 204–9.