J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 170 The Effects of Enamel Protective Agents on Shear Bond Strength After Rebonding of Stainless Steel Orthodontic Bracket (An in Vitro Study) Ruaa Ali K. Al-Sarkhi, B.D.S. (1) Dheaa H. Al-Groosh, B.D.S., M Sc., Ph. D. (2) ABSTRACT Background: Bracket rebonding is a common problem in orthodontics which may result in many drawbacks. The aims of this study were to evaluate the effects of application of two enamel protective agents “Icon” and “ProSeal” on shear bond strength before and after rebonding of stainless steel orthodontic brackets using conventional orthodontic adhesive and to assess the site of bond failure. Materials and methods: Fifty sound extracted human upper first premolar teeth were selected and randomly divided into two equal groups; the first time bonding and the rebonding groups (n=30). Each group was subdivided into control, Icon and ProSeal subgroups. The enamel protective agents were applied after etching (preconditioners). Shear bond strength before and after rebonding of stainless steel brackets were assessed using the Universal testing machine and the adhesive remnant index was used to find out the bond failure site using a stereomicroscope. Then the results were statistically analyzed using one-way ANOVA analysis test and T-test. Results: There were no significant differences in the shear bond strength mean values in either group or their corresponding subgroups. Forty percentage of the bond failure in ProSeal groups occurred away from the enamel where 75% of those were at the enamel protective agents/adhesive interface. Conclusions: The application of Icon and ProSeal did not compromise the shear bond strength and the application of the ProSeal may protect the enamel surface from trauma (cracks, chipping or detachment). Keywords: enamel protective agents; shear bond strength; rebonding.(J Bagh Coll Dentistry 2017; 29(1):170-176) INTRODUCTION One of the greatest problems that occasionally faces the orthodontists during and at the end of the treatment with fixed braces is the appearance of white spot lesions (WSLs) and enamel demineralization which may occur due to plaque accumulation that enhanced by the fixed appliances.(1) Bracket rebonding, on the other hand, is a frequently occurring problem during orthodontic treatment. (2) Mechanical removal of adhesive can cause scarring and alteration of the enamel surface with the removal of the outer enamel layer which contains high minerals compared to the deeper layer. This may eventually lead to an increase in the risk of enamel demineralization. (3) Different methods have been studied to prevent or reduce the occurrence of WSLs during the course of orthodontic treatment such as the use of fluoridated mouth rinse, gel and fluoride containing tooth paste. (1) However, studies have shown that there was a direct association between the patient compliance to oral hygiene programme and the reduction in the development of WSLs. (4) (1)M.Sc Student, Department of Orthodontic, College of Dentistry, University of Baghdad, Iraq (2)Assistant professor, Department of Orthodontics, College of Dentistry, University of Baghdad, Iraq The use of preventive agents that do not depend on the patient’s cooperation has been increased to control the development of WSLs. These preventive agents include topical applications of Casein phosphor-peptide- amorphous Calcium Phosphate or fluoride, (5) glass ionomer cement (6) and adhesive resin with antibacterial agents. (7) During the past decade, the use of fluoridated sealant, which acts as fluoride reservoir that releases fluoride over a long period of time, was proposed. (8) One of these sealants was ProSeal (Reliance Orthodontics). It has been shown that ProSeal provided maximum protection against enamel demineralization and WSLs formation. Additionally ProSeal released fluoride ions in a sustainable way over a period of 17 weeks. Furthermore it can withstand the tooth brush abrasion and acid challenge. (9-11) On the other hand, the effects of low- viscosity resins infiltrant "Icon" on enamel demineralization have been increasingly studied. It has been shown that Icon infiltrant prevented enamel surface demineralization. (12) The Icon infiltrant could be applied after bonding of orthodontic bracket; however, there are some drawbacks which include the difficulties in application procedure in dental crowding cases. Additionally, in order to achieve its effective protective effect, multiple applications are necessary, which is a patient compliance dependent practice. (13) J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 171 Therefore, applying this material before bonding may exert a better effect. It was found that the low viscosity resin infiltrant provided better sealing ability when combined with the conventional bonding agent than alone.(14) There is inconclusive information whether these agents increase or decrease the shear bond strength (SBS).Therefore the use of enamel protective agents may have a great advantageous effect during bracket rebonding situations. The aims of the current study were to evaluate the effects of the application of enamel protective agents (EPA) on the bond strength and the adhesive failure site after rebonding of orthodontic bracket. MATERIALS AND METHODS Fifty samples of freshly extracted sound human upper first premolars teeth were selected after being examined with 10x magnifying lens. (15) Teeth were grossly intact with no restoration or caries; no cracks or any surface irregularities and marked structural or developmental anomalies such as enamel hypoplasia or decalcification. Teeth were stored in a closed container at room temperature in normal saline solution (Panther, UK) containing 0.1% thymol (Sigma, Poole, Dorset, UK) to prevent dehydration and microbial growth. Retentive cuts were made along the sides of the roots of each tooth to increase the retention inside the acrylic. (16) Teeth were then fixed onto a glass slide (Star) in a vertical position using a sticky wax at the apex of the root using a dental surveyor (Dentaurum, Paraline, Germany) so that the force is applied at a right angle to the enamel bracket interface.(17,18) Teeth were mounted in auto polymerised acrylic resin (BMS Dental, Buonarroti, Cappannoli, Italy) in a vertical position with the root embedded in the acrylic block made from a specially designed molds where the crowns of the teeth protruding outside. The powder and liquid of the auto polymerised acrylic resin were then mixed, in a ratio of 2:1 according to the manufacturer’s instructions, and poured around the teeth to the level of cemento- enamel junction. (8,19) After setting has been completed, the samples were stored in a patch containing normal saline solution (Panther) with 0.1% thymol (Sigma) which is regularly changed until bonding procedure.(20) The samples were randomly divided into two groups: the first time bonding group (G1) and the rebonding group (G2). Each group was subdivided into three subgroups: the control, Icon (DMG, Hamburg, Germany), ProSeal (Reliance Orthodontic Products, Itasca, IL, USA) and the control group which received Heliosit orthodontic adhesive (Ivoclar, Vivadent, Schaan, Liechtenstein) only without protective agents. Each subgroup consists of ten samples apart from the control of G1 which contain 30 teeth. Stainless steel orthodontic brackets for upper first premolars (0.022 × 0.030 inch slot standard edge wise, Dentaurum, Inspringen, Germany) were used. The buccal surface of the enamel was cleaned with a rubber cup and non-fluoridated pumice for 10 seconds using a low speed headpiece (NSK, EC, Japan). (21, 22) The enamel surface was then washed for 10 seconds and dried with oil-free steam of air for another 10 seconds. (8, 23, 24) After that, an etching gel 37% phosphoric acid (Ivoclar, Vivadent, Schaan, Liechtenstein) was applied using a disposable brush on the buccal surface of the teeth for 30 seconds according to the manufacturer’s instructions, and then washed with air/water spray and dried with oil-free steam of air until the buccal surface of the etched teeth appeared chalky white. (25) In the control subgroups, the brackets were bonded to the enamel surface of the teeth by applying a thin layer of Heliosit adhesive (Ivoclar) on the middle of the middle third of the buccal surface.(25) Then, a constant load of 200 gm was applied on the bracket for 10 seconds. (26-29) The adhesive material was cured for 40 second (10 seconds curing time was set for each of the four directions; mesial, distal, occlusal and cervical) using Vivadent light cure unit with wave length range 400-500 nm and light intensity more than 500mW/cm2. (16,30) Regarding the Icon subgroups, one coat layer of the low viscosity Icon-Dry (DMG) was applied and left to set for 180 seconds, and then light cured for 60 second. A second layer was applied, left to set for 60 seconds and then light cured for 40 seconds according to the manufacturers' instructions. 31 After that, Heliosit adhesive (Ivoclar) was applied similar to the control subgroup. Regarding ProSeal subgroups, the ProSeal varnish (Reliance Orthodontic) was applied with a micro-brush on the etched tooth surface and light cured for 20 seconds. 32 After that, the adhesive was applied as described in the control subgroup. The samples were then immersed in 0.1% thymol solution and stored in an incubator (Fisher scientific, USA) at 37°C for 24 hours prior to testing procedure. 8, 17, 33 Shear bond strength test was done 24 hours after bonding procedure (8, 17, 33) in a Universal testing machine (H50KT, Tinius Olsen Co., England). Each specimen was placed in the J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 172 machine base parallel to the horizontal plane. A custom made chisel-end rod was fitted inside the upper arm of the testing machine parallel to the middle third of the buccal surface of the tooth and perpendicular to the enamel bracket interface. This was done to provide a force in an occluso- gingival direction. (12, 27, 34) The crosshead speed was 0.5mm/minute (35) and the highest magnitude of the load values were recorded as the load of the bond failure. The failure load (in Newton) was divided by the base bonding area (13mm2 in the current study) to calculate the shear bond strength in MPa (N/mm2). The adhesive remnant index (ARI) was assessed immediately using Stereomicroscope (Hamilton, Italy) with a magnification of 20 x.(36- 39) The ARI was scored according to Artun and Bergland (40) with its modified version (ARIM) which includes scores for enamel protective agents (EPA)/ adhesive bond interface failure and enamel detachment. The scores are as followed: Score 0 indicates no adhesive was left on the enamel surface of the tooth, Score I indicates less than half of the adhesive was left on the tooth surface, Score II indicates more than half of the adhesive was remain on the tooth surface, Score III indicates all the adhesive was left on the tooth surface, with an impression of the bracket mesh, Score IV indicates EPA /Adhesive bond failure, and Score V indicates enamel detachment. After complete assessment, teeth from the control group (n=30) were prepared for rebonding procedure using 12-blade tungsten carbide bur (#7642, Jet carbide burs, Beavers Dental, Morrisburg, Canada) at low speed (30,000 rpm) with copious water cooling system.(42) The samples were then subdivided randomly into the three subgroups as mentioned previously using similar way of EPA /adhesive application. Statistical analysis Descriptive statistics, which includes the means, standard deviation, standard errors, minimum and maximum values of SBS were calculated for each subgroup in the G1 and G2 groups. Analysis of variance (ANOVA) was used to test the differences among the shear bond strength mean values of the subgroups in each group. T test was used to test the differences in the shear bond strength mean values between G1 and G2. Chi-square was used to assess the differences between the groups and within the subgroups regarding the bonding failure site (ARI). RESULTS Descriptive statistics of the SBS of the control, Icon and ProSeal subgroups in G1 and G2 groups are presented in figure 1. The results obtained from the current study showed that the mean shear bond strength values of the tested materials were higher than the optimal limits suggested by Reynolds (41) which is 6-8Mpa, and thus, sufficient for clinical use. For the first time bonding group (G1), the mean SBS of the control group has the highest mean value (16.3±3.9Mpa) followed by that of the ProSeal (14.5±3.3Mpa); whereas the Icon has the lowest value (14.5±4.4Mpa). Whereas ProSeal subgroup in rebonding group (G2) exhibited the highest values (15.8±4.1Mpa) followed by that of the control and the Icon groups which showed almost similar SBS mean values (15.2±4.5Mpa,14.8±3.4Mpa respectively) (Table 1). However, the current study showed that there was statistically non-significant (p˃0.05) difference in SBS between G1 and G2 groups (Table 2) or the subgroups of each group (Table 3) Table 1: Descriptive statistics of the shear bond strength (MPa) of the bonding and rebonding groups State Groups N Mean S.D. S.E. Min. Max. Bonding group Control 10 16.338 3.977 1.258 10.13 23.08 Icon 10 14.507 4.483 1.418 8.08 23.33 Proseal 10 14.580 3.318 1.049 8.08 18.46 Rebonding group Control 10 15.238 4.516 1.428 8.45 23.59 Icon 10 14.847 3.480 1.100 10 21.54 Proseal 10 15.807 4.156 1.314 8.72 23.33 J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 173 Table 2: Comparison of the shear bond strength in the bonding and rebonding groups. State ANOVA Sum of Squares d.f. Mean Square F-test p- value Bonding G Between Groups 21.495 2 10.747 0.687 0.512 (NS) Within Groups 422.294 27 15.641 Total 443.789 29 Rebonding G Between Groups 4.661 2 2.330 0.140 0.870 (NS) Within Groups 447.977 27 16.592 Total 452.638 29 Table 3: Comparison of the shear bond strength between the correspondence subgroups of the bonding and rebonding group. Groups State Descriptive statistics State difference (d.f.=18) N Mean S.D. S.E. Mean Difference t-test p-value Control Bonding 10 16.338 3.977 1.258 1.100 0.578 0.570 (NS) Rebonging 10 15.238 4.516 1.428 Icon Bonding 10 14.507 4.483 1.418 -0.340 -0.189 0.852 (NS) Rebonging 10 14.847 3.480 1.100 ProSeal Bonding 10 14.580 3.318 1.049 -1.227 -0.730 0.475 (NS) Rebonding 10 15.807 4.156 1.314 Figure 1: Shear bond strength of the bonding and rebonding groups. The error bars represent the standard deviation. Regarding the adhesive remnant index (ARI), the predominant failure site of the control and Icon groups were near the enamel surface (scores 0 and I) regardless of the bonding sequence. On the other hand, the ProSeal groups showed that 40% of the samples exhibited a failure sites away from the enamel i.e. scores II and IV. About 75% of those were between the EPA and the adhesive. However, the differences were statistically non-significant (p˃0.05) between G1 and G2 groups and their subgroups (Figures 2 and 3). Figure 2: Bond failure site of the bonding group. 0 3 6 9 12 15 18 21 C-ve Icon ProSeal Bon… Reb… J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 174 Figure 3: Bond failure sites of the rebonding group DISCUSSION During the course of orthodontic treatment with fixed braces, enamel decalcification, caries and gingivitis could occur in 2-96% of the patients depending on the complexity of the complications.(43) Although some demineralized enamel resolved after the removal of the appliance i.e. fixed braces, most remained causing white spot lesions (WSLs) which undermine the treatment outcomes after the treatment has completed.(44) Furthermore, enamel demineralization could occur when the high mineral layer of enamel is lost during bracket rebonding.(3) Different methods have been proposed to reduce enamel demineralization during orthodontic treatment. (1, 7) The use of enamel protective agents and sealants are one of those measures. To the best of our knowledge, the use of Icon as a preconditioner to orthodontic adhesives during rebonding situations has not been investigated with regard to shear bond strength. Data obtained from the current study showed that, in the bonding group, the control subgroup showed the highest SBS mean value compared to Icon and ProSeal subgroups; however, the difference was not significant. Similarly, in rebonding group, the results showed a non-significant difference among the groups and the correspondent subgroups although ProSeal samples showed the highest SBS values. It has been shown that the surface irregularities created during adhesive removal may cause increase in the physical area and provide microscopic holes. (45) This may result in multiple dead spaces that entrap oxygen especially in the deeper pits. It has been suggested that Oxygen may has a plasticizer effect and result in a decline in the physical properties of the polymer. Furthermore, oxygen is known to interfere with the polymerization reaction and, results in an incomplete polymerization of the adhesive (46); this has an adverse effect on the adhesion characteristics and, eventually, results in a reduction in the mechanical properties of the resin. This is especially true in the control group where the adhesive applied without preconditioners. However, when Icon infiltrant and ProSeal applied, the SBS values were enhanced. The low viscosity of Icon resin infiltrant together with the hydrophilic property of Icon encourages a rapid capillary penetration into the pores and irregularities (47), provides a diffusion barrier within the enamel surface created by the rebonding procedure, filled the dead spaces and tags with the microscopic holes created by the adhesive removal procedure (48) and increases the SBS. On the other hand, it has been claimed that ProSeal showed high degree of polymerization (49) which, together with the increase in surface area and the formation of grooves and facets that alter the surface free energy and surface adhesion characteristics, enhance the adhesion.(50) Regarding the ARI scores, there were not marked effect of the application of the ProSeal and Icon on the site of bond failure in either group. However, in ProSeal groups, 40% of the failure sites were away from the enamel surface where 75% of those were at the EPA/adhesive interface. This has the advantage of preventing enamel trauma during debonding procedure As conclusion the application of Icon or ProSeal during rebonding procedure did not compromise the SBS of the adhesive and may provide better protection to the enamel surface. REFERENCE 1. Oesterle LJ, Shellhart WC. Effect of aging on the shear bond strength of orthodontic brackets. Am J Orthod Dentofacial Orthop 2008; 133: 716-20. IVF 2. Montasser MA, Drummond JL, Roth JR, Al-Turkil, Evans CA. Rebonding of orthodontic bracket. Part II, an XPS and SEM study. Angle Orthod 2008; 78: 537-44. 3. Gwinnertt AJ, Goreliek L. Evaluation of enamel after debonding. Am J Orthod 1977; 71(6): 651-65. 4. O’Reilly MM, Featherstone, JDB. Demineralization and remineralization around orthodontic appliances: An in vivo study. Am J Orthod Dentofac Orthop 1987; 92: 33- 40. 5. Cook PA. Direct bonding with glass ionomer cement. J Clin Orthod 1990; 24: 509-11. 6. Geiger AM, Gorelick L, Gwinnett AJ, Benson BJ. Reducing white spot lesions in orthodontic populations with fluoride rinsing. Am J Orthod Dentofac Orthop 1992; 101(5): 403-7. 7. Tabrizi A, Cakirer B. A comparative evaluation of casein phosphopeptide-amorphous calcium phosphate and fluoride on the shear bond strength of orthodontic brackets. Eur J Orthod 2011; 33: 282-7. 8. Tanaka M, Matsunaga K, Kadoma Y. Use of fluoride- containing sealant on proximal surfaces. Med Dent Sci 2000; 47: 49-52. J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 175 9. Bishara SE, Oonsombat C, Soliman MMA, Warren J. Effects of using a new protective Sealant on the bond strength of orthodontic brackets. Angle Orthod 2005; 75: 239- 42. 10. Soliman, MM, Bishara, SE, Wefel, JS, Heilman, J, Warren, JJ. Fluoride release rate from an orthodontic sealant and its clinical implications. Angle Orthod 2006; 76(2): 282-8. 11. Alawami, Hala. Potential inhibition of enamel demineralization in vitro by new filled orthodontic sealant. Tufts university school of dental Medicine 2012; 89: 119- 5. 12. Schmidlin PR, Sener B, Attin T, Wiegand A. Protection of sound enamel and artificial enamel lesions against demineralization: caries infiltrant versus adhesive. J Dent 2012; 40(10): 851-6. 13. Yetkiner E, Wegehaupt FJ, Attin R, Wigand A, Attin T. Stability of two resin combinations used as sealants against toothbrush abrasion and acid challenge in vitro. Acta Odontol Scand. 2014; 72(8): 825-30. 14. AL-Jaibehji MB. The influence of Caries Infiltrant combined with and without conventional adhesives on sealing of sound enamel (In Vitro Study). A master thesis. Department of Orthodontic College of Dentistry University of Baghdad, 2014. 15. D 'Attilio M, Traini T, Dilorio D, Varavara G, Festa F, Tecco S. Shear bond strength, bond failure, and scanning electron microscopy analysis of a new flowable composite for orthodontic use. Angle Orthod 2005; 75: 410-5. 16. Alexander SA. Effects of orthodontic attachments on the gingival health of permanent 2nd molars. Am J Orthod Dentofac Orthop 1991; 199: 337-40. 17. McSherry PF. An in vitro evaluation of the tensile and shear strengths of four adhesives used in orthodontics. Eur J Orthod 1996; 18:31927. 18. Bishara SE, Ostby AW, Laffon JF, Warren JF. A self- conditioner for resin modified glass ionomers in bonding orthodontic brackets. Angle Orthod 2007; 77(4): 711 -15. 19. Rajagopal R, Padmanabhan S, Gnanamani J. A comparison of shear bond strength and debonding characteristics of conventional, moisture-insensitive, and self-etching primers in vitro. Angle Orthod 2004; 74(2): 264-8. 20. Cozza P, Martucci L, De Toffol L, Penco SI. Shear bond strength of metal brackets on enamel. Angle Orthod 2006; 76(5): 851 - 6. 21. Ostby AW, Bishara SE, Laffoon J, Warren JJ. Influence of self-etchant application time on bracket shear bond strength Angle Orthod 2007; 77(5): 885-9. 22. Bishara SE, Ostby AW, Ajlouni R, Laffoon JF, Warren JJ. A new premixed self-etch adhesive for bonding orthodontic brackets. Angle Orthod 2008; 78(6): 1101-4. 23. Bishara SE, Oonsombat C, Soliman MMA, Warren J. Effects of using a new protective sealant on the bond strength of orthodontic brackets. Angle Orthod 2005; 75(2): 239-42. 24. Gronberg K, Rossouw PE, Miller BH, Buschang P. Distance and time effect on shear bond strength of brackets cured with a second-generation light-emitting diode unit. Angle Orthod 2006; 76(4): 682 -8. 25. Bishara SE, VonWald L, Laffoon JF, Warren JJ. The effect of repeated bonding on the shear bond strength of a composite resin orthodontic adhesive. Angle Orthod 2000; 70: 455-441. 26. Bishara SE, Solimann MMA, Oonsombat C, Laffoon JF, Ajlouni R. The effect of variation in mesh-base design on the shear bond strength of orthodontic brackets. Angle Orthod 2004; 74: 400 -4. 27. Bishara SE, Ostby AW, Ajlouni R, Laffon J, Warren JJ. Early shear bond strength of one-step adhesive on orthodontic brackets. Angle Orthod 2006; 76 (4):689-693. 28. Nemeth BR, Wiltshire WA, Lavelle CLB. Shear/ peel bond strength of orthodontic attachments to moist and dry enamel. Am J Orthod Dentofac Orthop 2006; 129: 396- 401. 29. Bishara SE, Ostby AW, Laffoon JF, Warren JJ. Enamel cracks and ceramic brackets failure during debonding in vitro. Angle Orthod 2008; 78 (6): 1178 -83. 30. Ewoldsen N, Beatty M V, Erickson L, Feely D. Effect of enamel conditioning on bond strength with a restorative light cure glass ionomer. J.Clin. Orthod 1995; 29: 621- 4. 31. Paris S, Meyer-Lueckel H, Kielbassa A M. Resin infiltration of natural caries lesions. J Dent Res 2007; 86: 662-666. 32. Wei HU, John D.B, Featherstone. Prevention of enamel demineralization: An in-vitro study using light- cured filled sealant. Am J Orthod Dentofacial Orthop 2005; 128(5): 592-600. 33. Cohen SM, Richard M, Robert EB, Vaidy ATK. Shear bond strength of chemically and light-cured resin- modified ionomers. J Clin Orthod 1998; 32(7): 423-6. 34. Bishara SE, Ostby AW, Laffon JF, Warren JF. The effect of modifying the self-etchant bonding protocol on the shear bond strength of orthodontic brackets. Angle Orthod 2007; 77 (3): 504 -508 35. Sonis AL. Comparison of a light-cured adhesive with an autopolymerisation bonding system. J Clin Orthod 1988; 22 (11): 730 -2. 36. Klocke A, Korbmacher HM, Huck LG, Ghosh J, kahl- Nieke B. Plasma arc curing of ceramic brackets: An evaluation of shear bond strength and debonding characteristics. Am J Orthod Dentofac Orthop 2003; 124: 309-15. 37. Kim MJ, Lim BS, Chang WG, Lee YK, Rhee SH, Yang HC. Phosphoric acid incorporated with acidulated phosphate fluoride gel etchant effects on bracket bonding. Angle Orthod 2005; 75(4): 678 -84. 38. Daub J, Berzins DW, Linn BJ, Bradley TG. Bond strength of direct and indirect bonded brackets after thermo-cycling. Angle Orthod 2006; 76(2): 295-300. 39. Northrup RG, Berzinsb DW, Bradleyc TG, Schuckitd W. Shear bond strength comparison between two orthodontic adhesives and self-ligating and conventional brackets. Angle Orthod 2007; 77(4): 701-6. 40. Artun J, Bergland S. Clinical trial with crystal growth conditioning as an alternative to acid-etch enamel pre- treatment. Am J Orthod Dentofac Orthop 1984; 85: 331- 40. 41. Reynolds JR. A review of direct orthodontic bonding. Br J Orthod 1975; 2: 171-8. 42. Graber TM, Vanarsdall RC. Orthodontics current principles and techniques, 2nd ed, St. Louis: CV Mosby; 1994. 542-626. 43. Gontijo l, Ctruz Rde A, Brandao PR. Dental enamel around fixed orthodontic appliances after fluoride varnish application. Braz Dent J 2007; 18: 49-53. 44. Lundstrom, F. and Krasse, B. Streptococcus mutans and lactobacilli frequency in orthodontic patients. Eur J Orthod 1987; 9: 109-116. 45. Sano H, Shono T, Sonoda H, Tatatsu T, Ciucchi B, Carvallo R, et al. Relationship between surface area for J Bagh College Dentistry Vol. 29(1), March 2017 The effects of enamel Pedodontics, Orthodontics and Preventive Dentistry 176 adhesion and tensile bond strength-Evaluation of a microtensile bond test. Dent Master 1994; 10(4): 236-40. 46. Dall'Oca S, Papacchini F, Chieffi N, Goracci C, Sadek FT, et al. Composite to composite mictotensile bond strength in the repair of a microfilled hybrid resin: effect of surface treatment and oxygen inhibition. J Adhes Dent 2007; 9: 25-31. 47. Chow CK, W CD, Evans CA. In vitro properties of orthodontic adhesive with fluoride or amorphous calcium phosphate. Int Dent 2011; 583521. 48. Paris S, Hopfenmuller W, Meyer-Lueckel H. Resin infiltration of caries lesions: An efficacy randomized trial. Journal of Dental Research 2010; 89(8): 823-826. 49. Eliades GC, Caputo AA. The strength of layering technique in visible light cured composite. J Prosthet. Dent 1989; 61: 31. 50. Radford DR, Sweet SP, Challacombe SJ , Walter J D. Adherence of Candida albicans to denture-base materials with different surface finishes. J Dent 1998; 26: 577-83. الخالصه تكون البقع البيضاء حول حاصراتتقويم االسنان الثابت اثناء وبعد المعالجه التقويميه.انفصال احدى المشاكل الشائعه التي تواجه اخصائي تقويم االسنان هي الخلفية: جراءات عملية ه. خالل االحاصرات التقويميه هي المشكله االخرى التي كثيرا ماتحدث خالل فترة المعالجه التقويميه والتي تستوجب اعادة تثبيت الحاصرة التقويمي لى عيات كبيره من مينا االسنان ممكن ان تفقد بسبب االزاله الميكانيكيه للماده الالصقه مما يؤدي الى خشونة سطح مينا السن و الذي يساعد اعادة تثبيت الحاصره كم البكتريا. تجمع نية بعد عملية اعادة اللصق باستخدام الصقة على القوة القاصة لحاصرات التقويم المعد Icon),(ProSeal)هو تقييم تأثير واقيات مينا االسنان ) الهدف من هذه الدراسة (Heliosit)التقويم التقليدية ( الجراء اختبار القص 03مجموعتين متساويتين )العدد= تم جمع خمسين من الضواحك العلوية االولى من االسنان البشرية وتوزيعها عشوائيا الى الطرق والمواد: ( وهي فرع السيطرة السلبية )والتي استخدمت فيه الماده الالصقه 03قسمت كل مجموعة عشوائيا الى ثالث مجاميع فرعيه )العدد= قبل وبعد اعادة تثبيت الحاصرات. Iconو فرع واقي المينا ProSealفقط(, فرع واقي المينا 42لقياس القوة القاصه لالرتباط وذلك بعد مرور Tinius Olsenتم فك ارتباط الحاصرات التقويمية للمجموعة االولى )مجموعة الربط( باستخدام الة الفحص ال -tungesten ن نوع ساعة على عملية الربط. بعد فك االرتباط تم تحضير العينات لعملية اعادة الربط وذلك بازالة الالصق المتبقي باستخدام محفر التجهيز م carbide( مع نظام 03333باستخدام سرعة منخفضة)التبريد بالماء. بعد عملية اعادة الربط تم اختبار فك االرتباط باستخدام نفس الماكنة وذلك لقياس دورة بالدقيقة قيق خدام مجهر مجسم دالقوة القاصة لالرتباط للمجموعة الثانية )مجموعة اعادة الربط(. بعد فك االرتباط تم فحص كل من قاعدة الحاصر وسطح السن المناظر باست لتصاق المتبقي.وتم تسجيل مشعر اال في كال المجموعتين بالرغم من ان ProSealو,Iconاظهرت النتائج انه ليس هنالك فرق معنوي في القوة القاصة لفك االرتباط بين كل من السيطرة السلبية النتائج: يد مواقع االنفصال بعد عملية الربط واعادة الربط. بعد عمليةبعد اعادة الربط اظهرت زيادة)غير معنوية( قليلة في القوة القاصة لالرتباط. تم تحدProSealمجموعة ال ل سائد على مينا ن االنفصال بشكالربط وجد انه االنفصال كان بشكل سائد بين مينا السن والمادة الالصقة في المجاميع الفرعية الثالث. بينما بعد عملية اعادة الربط كا بين المادة الواقية والمادة الالصقة. 03ان االنفصال بنسبة %ك ProSealالسن. في مجموعة المادة الواقية ال ممكن ان تحمي المينا من االصابة ProSealالتؤثر على القوة القاصة لالرتباط باالضافة الى انه ال IconوالProSeal وضع المواد الواقية لمينا السن ال :االستنتاج بعد فك االرتباط