INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH
Ramadan, M., Abu Elainin, H., Mazen, A., Ali, W. (2011). INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH. EKB Journal Management System, 8(4), 48-59. doi: 10.21608/jest.2011.81023
M. A. Ramadan; H. M. Abu Elainin; A. A. Mazen; W. Y. Ali. "INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH". EKB Journal Management System, 8, 4, 2011, 48-59. doi: 10.21608/jest.2011.81023
Ramadan, M., Abu Elainin, H., Mazen, A., Ali, W. (2011). 'INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH', EKB Journal Management System, 8(4), pp. 48-59. doi: 10.21608/jest.2011.81023
Ramadan, M., Abu Elainin, H., Mazen, A., Ali, W. INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH. EKB Journal Management System, 2011; 8(4): 48-59. doi: 10.21608/jest.2011.81023

INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH

Journal of the Egyptian Society of Tribology
Article 5, Volume 8, Issue 4, October 2011, Page 48-59  XML PDF (379.66 K)
Document Type: Original Article
DOI: 10.21608/jest.2011.81023
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Authors
M. A. Ramadan1; H. M. Abu Elainin2; A. A. Mazen2; W. Y. Ali2, 3
1Faculty of Engineering, Helwan University, Helwan, EGYPT.
2Faculty of Engineering, Minia University, P. N. 61111, El-Minia, EGYPT.
3Current Address: Faculty of Engineering, Taif University, Al –Taif, K. S. A.
Abstract
ABSTRACT
The present work aims to study the effect of the brushing force on the mechanical wear of teeth during polishing. Teeth specimens were brushed using three different types of tooth pastes. Tooth paste A contained pumice of (30 – 40) μm particle size. Paste B contained 8 wt % of hydrated silica abrasive of (10 – 12) μm particle size. Type C paste is an abrasive-free paste. The abrasives used were standard Arizona sand (ACFTD) of 0 - 80 μm and (ACCTD) of 0 - 200 μm particle size. Alumina particles of (1 - 3 μm) and sand with particle sizes of (11 – 13 μm, 15 – 20 μm, 20 – 24 μm, 28 – 32 μm and 42 – 52 μm) were used to fabricate eight different pastes. The abrasives were added at a 10 wt. % concentration. The brushing speed used in the experiments was 150 strokes/min. The contact forces used were 3 and 5 N in the presence of water.
Based on the observations in the present work, it was found that the influence of the force on the abrasive wear of the teeth increased with increasing abrasive particle size. The most pronounced influence was displayed by paste A that contaminated by abrasive of 30 – 40 μm particle size. Paste B displayed slight wear increase with increasing the acting load. Besides, abrasives of wide range of particle sizes such as air cleaner fine test dust (0 – 80 μm) and air cleaner coarse test dust (0 – 200 μm) showed lower wear than paste A. In condition of adhesion, significant wear increase was observed for paste-free abrasives. When adding abrasive to tooth paste, it is recommended to avoid the abrasive particle sizes ranging from 20 - 50 μm to reduce the excessive abrasive wear occurred during polishing the teeth.
Keywords
abrasive wear; acrylic teeth; tooth paste; abrasive; brushing force
Full Text

84
EGTRIB Journal
JOURNAL OF
THE EGYPTIAN SOCIETY OF TRIBOLOGY
VOLUME 8, NO. 4, OCTOBER 2011, 48 - 59
INFLUENCE OF BRUSHING FORCE ON ABRASIVE WEAR OF TEETH
Ramadan M. A.*, Abu Elainin H. M.**, Mazen A. A.**, Ali W. Y.**1
* Faculty of Engineering, Helwan University, Helwan, EGYPT.
** Faculty of Engineering, Minia University, P. N. 61111, El-Minia, EGYPT.
1 Current Address: Faculty of Engineering, Taif University, Al –Taif, K. S. A.
ABSTRACT
The present work aims to study the effect of the brushing force on the mechanical wear of teeth during polishing. Teeth specimens were brushed using three different types of tooth pastes. Tooth paste A contained pumice of (30 – 40) μm particle size. Paste B contained 8 wt % of hydrated silica abrasive of (10 – 12) μm particle size. Type C paste is an abrasive-free paste. The abrasives used were standard Arizona sand (ACFTD) of 0 - 80 μm and (ACCTD) of 0 - 200 μm particle size. Alumina particles of (1 - 3 μm) and sand with particle sizes of (11 – 13 μm, 15 – 20 μm, 20 – 24 μm, 28 – 32 μm and 42 – 52 μm) were used to fabricate eight different pastes. The abrasives were added at a 10 wt. % concentration. The brushing speed used in the experiments was 150 strokes/min. The contact forces used were 3 and 5 N in the presence of water.
Based on the observations in the present work, it was found that the influence of the force on the abrasive wear of the teeth increased with increasing abrasive particle size. The most pronounced influence was displayed by paste A that contaminated by abrasive of 30 – 40 μm particle size. Paste B displayed slight wear increase with increasing the acting load. Besides, abrasives of wide range of particle sizes such as air cleaner fine test dust (0 – 80 μm) and air cleaner coarse test dust (0 – 200 μm) showed lower wear than paste A. In condition of adhesion, significant wear increase was observed for paste-free abrasives. When adding abrasive to tooth paste, it is recommended to avoid the abrasive particle sizes ranging from 20 - 50 μm to reduce the excessive abrasive wear occurred during polishing the teeth.
KEYWORDS
Abrasive wear, acrylic teeth, tooth paste, abrasive, brushing force.
INTRODUCTION
Tooth wear has a multi-factorial etiology involving the interplay of attrition, erosion and abrasion, [1, 2]. When two-body abrasion occurs in the mouth whenever there is tooth-to-tooth contact, this is what most dentists call attrition. Abrasion wear may also occur when there is an abrasive slurry interposed between two surfaces, such that the two solid surfaces are not actually in contact, this is called three-body abrasion, with food acting as the abrasive agent, and occurs in the mouth during mastication. Abrasion is the key physiological wear mechanism that is present in dental materials during normal masticatory function, [3, 4]. But erosion is defined as loss of tooth structure by chemical dissolution without involvement of bacteria.

References
REFERENCES
1. Eisenburger M., Addy M.,“Errosion of Human Enamel in vitro, part I: Interaction Effects”, Journal of Dentistry,30, pp. 341-347, (2002).
2. Mair L. H., Stolarski T. A., Vowles R. W., Lloyd C. H., “Wear: Mechanisms, Manifestation and Measurement”, Report of A workshop, Journal of Dentistry, 24, pp. 141-148, (1996).
3. Borwell J. T., “Survey of Possible Wear Mechanisms”, Wear, 1, pp. 119-141, (1957).
4. Antunes P. V., Ramalho A., “Study of Abrasive Resistance of Composites for Dental Restoration by Ball-Cratering”, Wear, 255, pp. 990-998, (2003).
5. Abrahamsen T. C., “The Worn Dentition-Pathognomonic Patterns of Abrasion and Erosion”, International Dental Journal, 55, pp. 268-276, (2005).
6. Al-Malik M. T., Holt R. D., Bedi R., Speight P. M., “Investigation of an Index to Measure Tooth Wear in Primary Teeth”, Journal of Dentistry, 29, pp. 103-107, (2001).
7. Moss S. J., “Dental Erosion”, International Dental Journal, 48, pp. 529-539, (1998).
8. Ramalho A., Antunes P. V., “Reciprocating Wear Test of Dental Composites: Effect on the Antagonist”, Wear, 259, pp. 1005-1011, (2005).
9. Callaghan D. J., Vaziri A., Nayeb-Hashemi H., “Effect of Fiber Volume Fraction and Length on the Wear Characteristics of Glass Fiber-Reinforced Dental Composites”, Dental Materials, 22, pp. 84-93, (2006).
10. Manly R. S., “Factors influencing tests on abrasion of dentin by brushing with dentifrice”, Journal of Dental Research, 23, pp.59-72, (1944).
11. Heath J. R., Wilson H. J., “Abrasion of restorative materials by toothpaste”, Journal of Oral Rehabilitation, 3, pp. 121-138, (1976).
12. Harrington E., Jones P. A., Fisher S. E., Wilson H. J., “Toothbrush – dentifrice abrasion - a suggested standard method”, British Dental Journal, 153, pp. 135-38, (1982).
13. Condon J. R., Ferracane J. F., “A new multi-mode oral wear simulator”, Dental Materials, 12, pp. 218-26, (1996).
14. Bal G., Üçtaşli S., Bekiroğlu E., “PC Controlled Toothbrush/Dentifrice Abrasion Machine”, Journal of Medical System, 23, pp.27-33, (1999).
15. Lambrechts P., Debels E., Landuyt K. V., Peumans M., Meerbeek B. V., “How to Simulate Wear”, Dental Materials, 22, pp. 693-701, (2006).
16. Heintze, S. D., How to qualify and validate wear simulation devices and methods. Dent. Mater. 22, pp. 712 - 734, (2006).
17. Santos P. H., Pavan S., Suzukia Y. U., Briso L. F., Assunço W. G., Sinhoretic M. A. C., Sobrinho L. C., Consani S., “Effect of fluid resins on the surface roughness and topography of resin composite restorations analyzed by atomic force microscope”, Journal of the mechanical behavior of biomedical materials 4, pp. 433 – 439, (2011).
18. Gedik R., Hürmüzlü F., Coskun A., Bektas A. K., “Surface roughness of new microhybrid resin-based composites”, J. Am. Dent. Assoc. 136, pp. 1106 - 1112, (2005).

19. Ramadan M. A., Abu Elainin H. M., Mazen A. A., Ali W. Y., "Abrasive Wear of Teeth", Journal of the Egyptian Society of Tribology Vol. 8, No. 2, April 2011, pp. 56 – 66, (2011).

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