DOI:

10.37988/1811-153X_2022_1_108

Residual sand particles as a cause of chipping of ceramic cladding

Downloads

Authors

  • L.R. Saleeva 1, assistant at the Prosthetic dentistry Department
    ORCID: 0000-0003-4819-6818
  • R.N. Kashapov 1, 2, PhD in Engineering, assistant professor of the Prosthetic dentistry Department; associate professor and head of the Biomedical engineering and innovation management Department
    ORCID: 0000-0003-2174-4394
  • R.F. Mustakimova 1, PhD in Medical Sciences, associate professor of the Prosthodontics Department
    ORCID: 0000-0003-2988-1262
  • 1 Kazan State Medical University, 420012, Kazan, Russia
  • 2 Kazan Federal University, 420012, Kazan, Russia

Abstract

Despite the fact that the clinical and technological stages of prosthetics with porcelaine fused to metal constructions are deeply grounded with long-term results of their use, complications arise during the operation of these constructions that require their repair or replacement. First of all, this applies to the chipping of ceramic cladding, which are associated with both errors in clinical planning and violations of the laboratory stages of their manufacture, including adhesion of ceramics and metal. The aim was to study the surface of cast alloy samples for the content of sand particles after sandblasting.
Materials and methods.
Experimental studies of the surface of cast cobalt-chromium alloy samples with a scanning electron microscope at various magnifications were carried out, the roughness parameters after sandblasting with a diameter of 250 μm, 50 μm and a dental milling cutter were studied.
Results.
Microscopic analysis of the surface after processing samples with sand with a diameter of 250 μm showed the absence of contamination, the formation of a three-dimensional structure of the surface with ledges and holes. At 1000 magnification, electrocorundum residues ranging in size from 0.5 to 3 μm were observed, at 5000 magnification, contamination with a size less than 1 μm, and at 20,000 magnification, foreign inclusions with an average size of 100 nm. After processing with a milling cutter, a clean surface from foreign inclusions was revealed, the presence of micro-grooves from 1.0 microns to 10 microns. However, with this type of processing, the minimum roughness parameters are achieved: Ra=0.8 μm, Rz=1 μm. When sandblasting with a size of 50 μm, roughness parameters Ra=1.498 μm, Rz=7.237 μm are achieved, microscopic examination shows the formation of a characteristic locally scratched three-dimensional structure. At 20,000 magnification, foreign inclusions with an average size of 200 nm are observed.
Conclusion.
The presence of large holes and ledges during sandblasting with a size of 250 μm under cyclic dynamic load due to transverse compression will lead to different longitudinal stretching. Milling prevents the occurrence of future stress concentrators, however, the specific surface area is three times smaller, which greatly affects the amount of adhesion of ceramics with a metal frame. When sandblasting with an abrasive of 50 μm, sand particles with a size of 150—300 nm remain on the metal surface, large-range particles are also observed in places, imprinted into the metal, and which are quite difficult to remove by existing methods.

Key words:

metal-ceramic dentures, metal framework, sandblasting, profilometry, surface roughness

For Citation

[1]
Saleeva L.R., Kashapov R.N., Mustakimova R.F. Residual sand particles as a cause of chipping of ceramic cladding. Clinical Dentistry (Russia).  2022; 25 (1): 108—114. DOI: 10.37988/1811-153X_2022_1_108

References

  1. Shankar T., Garhnayak M., Garhnayak L., Dhal A., Kar A.K. Comparison of Hypersensitivity in Metal Ceramic Crowns cemented with Zinc Phosphate and Self-adhesive Resin: A Prospective Study. J Contemp Dent Pract. 2017; 18 (10): 923—926. PMID: 28989131
  2. Olley R.C., Andiappan M., Frost P.M. An up to 50-year follow-up of crown and veneer survival in a dental practice. J Prosthet Dent. 2018; 119 (6): 935—941. PMID: 28969914
  3. Afanasyeva M.M., Belyankin I.A., Nelovko T.V., Filippova N.V. Actuality and modern ways of complex correction of tooth wear. Bulletin of Medical Internet Conferences. 2020; 5: 170 (In Russ.). eLIBRARY ID: 43098501
  4. Greţa D.C., Gasparik C., Colosi H.A., Dudea D. Color matching of full ceramic versus metal-ceramic crowns a spectrophotometric study. Med Pharm Rep. 2020; 93 (1): 89—96. PMID: 32133452
  5. Nejatidanesh F., Abbasi M., Savabi G., Bonakdarchian M., Atash R., Savabi O. Five year clinical outcomes of metal ceramic and zirconia-based implant-supported dental prostheses: A retrospective study. J Dent. 2020; 100: 103420. PMID: 32598899
  6. Rammelsberg P., Lorenzo Bermejo J., Kappel S., Meyer A., Zenthöfer A. Long-term performance of implant-supported metal-ceramic and all-ceramic single crowns. J Prosthodont Res. 2020; 64 (3): 332—339. PMID: 31859082
  7. Saker S., Ghazy M., Abo-Madina M., El-Falal A., Al-Zordk W. Ten-Year Clinical Survival of Anterior Cantilever Resin-Bonded Fixed Dental Prostheses: A Retrospective Study. Int J Prosthodont. 2020; 33 (3): 292—296. PMID: 32320182
  8. Parkhomenko A.N., Ageeva Yu.V., Shemonaev V.I., Mikhalchenko D.V., Timacheva T.B. Clinical assesment of the complex of measures for correcting individual oral hygiene during prosthodontic treatment. Volgograd Scientific and Medical Journal. 2021; 3: 43—48 (In Russ.). eLIBRARY ID: 46679168
  9. Koutsoukis T., Zinelis S., Eliades G., Al-Wazzan K., Rifaiy M.A., Al Jabbari Y.S. Selective Laser Melting Technique of Co-Cr Dental Alloys: A Review of Structure and Properties and Comparative Analysis with Other Available Techniques. J Prosthodont. 2015; 24 (4): 303—12. PMID: 26129918
  10. Parunov V., Kolesov P., Bikova M. Evaluation of the results of orthopedic treatment of metal-ceramic dentures with a frameworkof a new Russian-based alloy of gold. Cathedra. Dental education. 2016; 57: 36—39 (In Russ.). eLIBRARY ID: 27495301
  11. Li J., Chen C., Liao J., Liu L., Ye X., Lin S., Ye J. Bond strengths of porcelain to cobalt-chromium alloys made by casting, milling, and selective laser melting. J Prosthet Dent. 2017; 118 (1): 69—75. PMID: 27927283
  12. Saleeva L.R., Kashapov R.N., Kashapov L.N., Kashapov N.F. Changes in the CoCr alloys surface relief during plasma electrolytic treatment. IOP Conference Series: Materials Science and Engineering. 2018; 570: 012087. DOI: 10.1088/1757-899X/570/1/012087
  13. Stepanov V.A., Shemonaev V.I., Buyanov E.A., Grachev D.V., Parkhomenko A.N., Zubreva I.A. Prospects of manufacturing metal-ceramic structures of dentures by selective laser sintering. Medical and pharmaceutical journal Pulse. 2021; 23 (06): 232—239 (In Russ.). eLIBRARY ID: 46113098
  14. Potapchuk A.M., Krulyk V.V. Relevant restoration methods of ceramic coating’s chips of metal-ceramic prostheses using composite materials. Dentistry bulletin. 2015; 4 (93): 66—69 (In Russ.). eLIBRARY ID: 29274432
  15. Iordanishvili A.K., Volodin A.I., Muzikin M.I., Petrov A.A. Evaluation of metal-ceramic non-removable dentures, prosthetic bed and field during warranty periods. Bulletin of the Russian Military Medical Academy. 2018; 4 (64): 91—95 (In Russ.). eLIBRARY ID: 36462889
  16. Mansur Yu.P., Sayamov I.A., Telfach L.I. Prosthetics of teeth and dentition defects with metal-ceramic orthopedic structures: analysis of clinical complications. In: proceedings of “Interaction between science and society: problems and prospects” conference. Kazan, 2018. Pp. 59—62 (In Russ.). eLIBRARY ID: 32524880
  17. Kerimova A. Clinical evaluation of cobalt-chromium-based fixed dentures. Actual Problems in Dentistry. 2019; 3: 146—151 (In Russ.). eLIBRARY ID: 41212358
  18. Vecherkina Zh.V., Shalimova N.A., Smolina A.A., Kalinichenko T.P., Morozov N.V. Results of evaluation of oral dysbiosis after orthopedic treatment with removable dentures. System Analysis and Management in Biomedical Systems. 2021; 1: 24—29 (In Russ.). eLIBRARY ID: 45588794
  19. Sobir R.K. Mistakes made in the manufacture of metal-ceramic dentures, methods of their elimination and restoration. In proceedings of “Digitalization of education: theoretical and applied research of modern science” conference. Rostov-on-Don: Southern University, VVM, 2021. Pp. 76—80 (In Russ.). eLIBRARY ID: 44740585
  20. Han X., Sawada T., Schille C., Schweizer E., Scheideler L., Geis-Gerstorfer J., Rupp F., Spintzyk S. Comparative analysis of mechanical properties and metal-ceramic bond strength of Co-Cr dental alloy fabricated by different manufacturing processes. Materials (Basel). 2018; 11 (10): E1801. PMID: 30249000
  21. Pjetursson B.E., Valente N.A., Strasding M., Zwahlen M., Liu S., Sailer I. A systematic review of the survival and complication rates of zirconia-ceramic and metal-ceramic single crowns. Clin Oral Implants Res. 2018; 29 Suppl 16: 199—214. PMID: 30328190
  22. Vaska K.R., Nakka C., Reddy K.M., Chintalapudi S.K. Comparative evaluation of shear bond strength between titanium-ceramic and cobalt-chromium-ceramic: An in vitro study. J Indian Prosthodont Soc. 2021; 21 (3): 276—280. PMID: 34380815
  23. Kursoglu P., Karagoz Motro P.F., Kazazoglu E. Correlation of surface texture with the stainability of ceramics. J Prosthet Dent. 2014; 112 (2): 306—13. PMID: 24484857
  24. Galiatsatos A.A., Galiatsatos P.A. Clinical evaluation of fractured metal-ceramic fixed dental prostheses repaired with indirect technique. Quintessence Int. 2015; 46 (3): 229—36. PMID: 25485316
  25. Sakanyan S.S. Complications in the application of metal-ceramic prostheses. Scientific Review. Medical sciences. 2017; 4: 84—87 (In Russ.). eLIBRARY ID: 28781658
  26. Turusova E.V., Bulkina N.V., Firsova I.V., Lebedeva S.N., Kazakova L.N. Influence of prosthetic rehabilitation methods on quality of life of patients with inflammatory periodontal diseases. Clinical Dentistry (Russia). 2018; 2 (86): 81—83 (In Russ.). eLIBRARY ID: 35154638
  27. Radchuk V.B., Hasiuk N.V., Yeroshenko G.A. Analysis of the orthopedic pathology structure and the frequency of repeated visits after dental prosthetics with metal-ceramic structures. World of Medicine and Biology. 2019; 4 (70): 138—142 (In Russ.). eLIBRARY ID: 41493645
  28. Wong C.K.K., Narvekar U., Petridis H. Prosthodontic Complications of Metal-Ceramic and All-Ceramic, Complete-Arch Fixed Implant Prostheses with Minimum 5 Years Mean Follow-Up Period. A Systematic Review and Meta-Analysis. J Prosthodont. 2019; 28 (2): e722-e735. PMID: 29665177
  29. Gogushev K.G., Valcheva Z.S. Clinical and laboratory workflow with fixed partial dentures a survey among dentists and dental technicians. Eurasian Union of Scientists . 2021; 3—2 (84): 22—7 (In Russ.). eLIBRARY ID: 45688677.

Downloads

Received

December 27, 2021

Accepted

March 10, 2022

Published on

March 1, 2022