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Sains Malaysiana 50(10)(2021): 3059-3065
http://doi.org/10.17576/jsm-2021-5010-18
The
Digitalisation in Cobalt-Chromium Framework Fabrication. Surface Roughness
Analysis: A Pilot Study
(Pendigitan dalam Fabrikasi Kerangka Kobalt-Kromium. Analisis Kekasaran Permukaan: Suatu Kajian Rintis)
AINI HAYATI ABDUL RAHIM1,2*, ZUBAIDAH ZANUL
ABIDIN2 & NORSIAH YUNUS2
1Faculty of
Dentistry, Universiti Teknologi MARA (UiTM), 47000 Sungai Buloh, Selangor Darul Ehsan, Malaysia
2Faculty of
Dentistry, University of Malaya (UM), 50603 Kuala Lumpur, Federal Territory,
Malaysia
Diserahkan: 13 Mac 2020/Diterima: 10 Februari 2021
ABSTRACT
Selective laser melting (SLM) is a
new technique in fabricating cobalt-chromium denture framework. However, the
surface properties of cobalt-chromium denture framework fabricated using the
aforementioned technique have not been widely investigated. The aim of this
paper was to investigate the surface roughness of cobalt-chromium alloy in
removable partial denture fabricated with SLM technique. Cobalt-chromium
denture frameworks were fabricated with two techniques (n = 10); the
conventional lost-wax casting (conventional group) and SLM techniques (SLM
group). Specimens from the conventional group were subjected to the standard
cobalt-chromium denture polishing protocols. No treatment was employed for
specimens from the SLM group. All specimens were subjected to surface roughness
measurement on polished and fitting surfaces using non-contact optical
three-dimensional metrology and surface roughness analysis machine (Infinite
Focus Real 3D Alicona). Statistical analysis showed
no significant difference in surface roughness between the specimens from
conventional and SLM groups (p > 0.05). There was no statistically
significant difference in surface roughness between the polished and fitting
surfaces of SLM specimens (p >
0.05). Surface roughness quality of the cobalt-chromium denture framework
fabricated with the SLM technique is comparable to that fabricated with the
conventional lost-wax casting technique. The surface roughness of SLM
fabricated cobalt-chromium denture frameworks carries the same surface
roughness quality between the polished and fitting surfaces.
Keywords: Cobalt chromium; denture;
selective laser melting; surface roughness
ABSTRAK
Lebur laser terpilih (SLM) adalah teknik terkini yang digunakan dalam menghasilkan dentur kobalt-kromium. Walau bagaimanapun, masih kurang kajian yang dihasilkan berkaitan permukaaan dentur yang dihasilkan melalui teknik ini. Tujuan penyelidikan ini ialah untuk mengkaji kekasaran permukaan dentur yang dihasilkan melalui teknik SLM. Dentur kobalt-kromium dihasilkan menggunakan teknik konvensional dan teknik SLM (n = 10). Permukaan spesimen konvensional dirawat menggunakan protokol asas penggilapan dentur kobalt-kromium. Tiada rawatan dilakukan untuk spesimen daripada kumpulan SLM. Semua spesimen diimbas dengan mesin optikal pembacaan kekasaran permukaan (Infinite Focus Real 3D Alicona). Tiada perbezaan nyata statistik didapati antara spesimen konvensional dan SLM (p > 0.05). Tiada perbezaan nyata statistik antara permukaan licin dan permukaan adaptasi tisu untuk spesimen SLM (p > 0.05). Kualiti permukaan untuk dentur kobalt-kromium yang dihasilkan melalui proses SLM adalah sama dengan dentur yang dihasilkan melalui proses konvensional. Kualiti permukaan dentur kobalt-kromium yang dihasilkan melalui proses SLM adalah sama antara permukaan licin dan permukaan adaptasi tisu.
Kata kunci: Dentur; kekasaran permukaan; kobalt-kromium; lebur laser terpilih
RUJUKAN
Alageel, O., Abdallah, M.N., Alsheghri,
A., Song, J., Caron, E. & Tamimi, F. 2018. Removable partial denture alloys
processed by laser‐sintering technique. Journal of Biomedical Materials Research Part B: Applied Biomaterials 106(3):
1174-1185.
Anusavice, K.J. 2003. Philip’s
Science of Dental Materials. 11th ed. St. Louis: Elsevier Science. p. 96.
Aydin, A.K. 1991. Evaluation of finishing and
polishing techniques on surface roughness of chromium-cobalt castings. The Journal of Prosthetic Dentistry 65(6):
763-767.
Bartolomeu, F., Costa, M., Gomes, J., Alves, N.,
Abreu, C., Silva, F. & Miranda, G. 2019. Implant surface design for
improved implant stability - A study on Ti6Al4V dense and cellular structures
produced by selective laser melting. Tribology
International 129: 272-282.
Blunt, L. & Jiang, X. 2003. Advanced Techniques for Assessment Surface
Topography: Development of a Basis for 3D Surface Texture Standards SURFSTAND.
Oxford: Butterworth-Heinemann.
Bollen, C.M., Papaioanno,
W., Van Eldere, J., Schepers,
E., Quirynen, M. & Van Steenberghe,
D. 1996. The influence of abutment surface roughness on plaque accumulation and
peri‐implant mucositis. Clinical
Oral Implants Research 7(3): 201-211.
Bremen, S., Meiners, W. & Diatlov, A. 2012. Selective laser melting: A manufacturing
technology for the future? Laser Technik
Journal 9(2): 33-38.
Budak, I., Kosec, B.
& Sokovic, M. 2012. Application of contemporary
engineering techniques and technologies in the field of dental prosthetics. Journal of Achievements in Materials and
Manufacturing Engineering 54(2): 233-241.
Budtz‐Jörgensen, E. 1974. The significance of Candida albicans in denture stomatitis. European Journal of Oral Sciences 82(2):
151-190.
Dickens, P. 1995. Research developments in rapid
prototyping. Proceedings of the
Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 209(4): 261-266.
Hong, M.H., Son, J.S. & Kwon, T.Y. 2018.
Surface roughness of a 3D-printed Ni–Cr alloy produced by selective laser
melting: Effect of process parameters. Journal
of Nanoscience and Nanotechnology 18(3): 2037-2040.
Hong, M.H., Min, B.K. & Kwon, T.Y. 2016. The
influence of process parameters on the surface roughness of a 3D-printed Co–Cr
dental alloy produced via selective laser melting. Applied Sciences 6(12): 401.
Jang, K.S., Youn, S.J.
& Kim, Y.S. 2001. Comparison of castability and
surface roughness of commercially pure titanium and cobalt-chromium denture
frameworks. The Journal of Prosthetic
Dentistry 86(1): 93-98.
Jevremovic, D., Puskar, T., Kosec,
B., Vukelic, Đ., Budak, I., Aleksandrovic,
S., Egbeer, D. & Williams, R. 2012. The analysis
of the mechanical properties of F75 Co-Cr alloy for use in selective laser
melting (SLM) manufacturing of removable partial dentures (RPD). Metalurgija-Zagreb 51(2): 171.
Kajima, Y., Takaichi,
A., Nakamoto, T., Kimura, T., Yogo, Y., Ashida, M., Doi, H., Nomura, N., Takahashi, H., Hanawa, T. & Wakabayashi, N. 2016. Fatigue strength of
Co–Cr–Mo alloy clasps prepared by selective laser melting. Journal of the Mechanical Behavior of
Biomedical Materials 59: 446-458.
Koutsoukis, T., Zinelis, S., Eliades, G., Al-Wazzan, K., Al Rifaiy, M.
& Al
Jabbari, Y.S. 2015. Selective laser melting
technique of Co-Cr dental alloys: A review of structure and properties and
comparative analysis with other available techniques. Journal of Prosthodontics 24(4): 303-312.
Leach, R. 2011. Optical Measurement of Surface Topography (Vol. 14). Berlin,
Heidelberg: Springer.
Liu, B., Kuai, Z., Li, Z., Tong, J., Bai, P.,
Li, B. & Nie, Y. 2018. Performance consistency of
AlSi10Mg alloy manufactured by simulating multi laser beam selective laser
melting (SLM): Microstructures and mechanical properties. Materials 11(12): 2354.
Pupo, Y., Monroy, K.P. & Ciurana,
J. 2015. Influence of process parameters on surface quality of cocrmo produced by selective laser melting. The International Journal of Advanced
Manufacturing Technology 80(5-8): 985-995.
Quirynen, M., Marechal, M., Busscher,
H., Weerkamp, A., Darius, P. & Van Steenberghe, D. 1990. The influence of surface free energy
and surface roughness on early plaque formation: An in vivo study in man. Journal
of Clinical Periodontology 17(3): 138-144.
Revilla-León, M., Ceballos, L., Martínez-Klemm,
I. & Özcan, M. 2018. Discrepancy of complete-arch
titanium frameworks manufactured using selective laser melting and electron
beam melting additive manufacturing technologies. The Journal of Prosthetic Dentistry 120(6): 942-947.
Swelem, A.A., Abdelnabi,
M.H., Al-Dharrab, A.A. & Abdelmaguid,
H.F. 2014. Surface roughness and internal porosity of partial removable dental
prosthesis frameworks fabricated from conventional wax and light-polymerized
patterns: A comparative study. The
Journal of Prosthetic Dentistry 111(4): 335-341.
Takaichi, A., Suyalatu, Nakamoto, T., Joko, N., Nomura, N., Tsutsumi, Y., Migita, S., Doi, H., Kurosu, S., Chiba, A., Wakabayashi, N., Igarashi, Y. & Hanawa, T. 2013. Microstructures and mechanical properties
of Co–29Cr–6Mo alloy fabricated by selective laser melting process for dental
applications. Journal of the Mechanical Behavior of Biomedical Materials 21: 67-76.
Taylor, R., Maryan, C.
& Verran, J. 1998. Retention of oral
microorganisms on cobalt-chromium alloy and dental acrylic resin with different
surface finishes. The Journal of
Prosthetic Dentistry 80(5): 592-597.
Verran, J., Lees, G. & Shakespeare, A.P. 1991. The
effect of surface roughness on the adhesion of Candida albicans to acrylic. Biofouling 3(3): 183-191.
Vorburger, T.V., Rhee, H.G., Renegar,
T.B., Song, J.F. & Zheng, A. 2007. Comparison of optical and stylus methods
for measurement of surface texture. The
International Journal of Advanced Manufacturing Technology 33(1-2):
110-118.
Whitehouse, D.J. 2004. Surfaces and Their Measurement. Oxford: Butterworth-Heinemann.
*Pengarang untuk surat-menyurat; email: hayati1967@uitm.edu.my
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