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ORIGINAL ARTICLE Table of Contents   
Year : 2010  |  Volume : 13  |  Issue : 2  |  Page : 71-75
Effects of saliva contamination and decontamination procedures on shear bond strength of self-etch dentine bonding systems: An in vitro study


1 Department of Conservative Dentistry and Endodontics, Manipal College of Dental Sciences, Manipal, India
2 Department of Conservative Dentistry and Endodontics, Manipal College of Dental Sciences, Mangalore, Karnataka, India

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Date of Submission11-Sep-2009
Date of Decision06-Jan-2009
Date of Acceptance23-Jan-2010
Date of Web Publication23-Jul-2010
 

   Abstract 

Objective: This study aims to evaluate the effect of saliva contamination on the shear bond strength of two self-etch dentine bonding systems and also investigate the effect of decontamination procedure on the recovery of bond strength.
Materials and Methods: Sixty premolars extracted for orthodontic reason were obtained and the buccal surfaces of teeth were reduced to create a flat dentine surface. The samples were randomly divided into three sub-groups for AdheSE (ASE) (Ivoclar - Vivadent, Schaan, Liechtenstein) and three sub-groups for Adper Prompt Self-Etch Adhesive (ADP) (3M ESPE, St Paul, MN, USA) of 10 each. For AdheSE (ASE); ASE-I was the control group (primer applied to fresh dentine surface), ASE-II was the contamination group (primer applied, followed by saliva contamination and then air dried) and ASE-III was the decontamination group (primer applied, followed by saliva contamination, air dried and then primer reapplied). For Adper Prompt (ADP); ADP-I was the control group (self-etch adhesive applied to fresh dentine surface), ADP-II was the contamination group (self-etch adhesive applied, followed by saliva contamination and then air dried) and ADP-III was the decontamination group (self-etch adhesive applied, followed by saliva contamination, air dried and then self-etch adhesive reapplied). Followed by the bonding procedure, a 5 mm composite resin block with Filtek P-60 (3M ESPE, St Paul, MN, USA) was built on the substrate. Shear bond strength (SBS) was tested with Instron Universal testing machine (Instron Corporation, Canton, MA, USA) with a cross head speed of 1 mm per minute. Data obtained was subjected to one way ANOVA test, while the inter group comparison was made using Tukey's multiple comparison and Unpaired t-test.
Results: In AdhSE group (ASE), the sub-group ASE-II (contamination group) [5.4 ± 2.2 MPa] showed lower SBS than ASE-I [11.8 ± 2.6 MPa] and ASE-III [8.9 ± 3.3 MPa], which was statistically significant. There was no significant difference in the bond strength between the ASE-I (control group) and ASE-III (decontamination group). In Adper Prompt group (ADP), there was a severe decrease of bond strength in ADP-II (contamination group) [4.6 ± 1.1 MPa] when compared to ADP-I (control group) [7.4 ΁ 1.4 MPa] and ADP-III (decontamination subgroup) [14.1 ± 2.2 MPa] which was statistically significant. The bond strength of ADP-III wherein Adper Prompt bonding agent was reapplied after salivary contamination was found to be statistically significant than ADP-I and ADP-II.
Conclusion: Saliva contamination reduces the dentine bond strength of both the self-etch systems; AdheSE and Adper Prompt. Re-application of the primer for the AdheSE and re-application of the adhesive for the Adper Prompt after air drying the saliva off can recover the dentine bond strength. In the Adper Prompt group, the added application of adhesives to decontaminate saliva not only recovered the bond strength but also improved it significantly.

Keywords: Decontamination procedure; salivary contamination; self-etch adhesive system; shear bond strength

How to cite this article:
Neelagiri K, Kundabala M, Shashi RA, Thomas MS, Parolia A. Effects of saliva contamination and decontamination procedures on shear bond strength of self-etch dentine bonding systems: An in vitro study. J Conserv Dent 2010;13:71-5

How to cite this URL:
Neelagiri K, Kundabala M, Shashi RA, Thomas MS, Parolia A. Effects of saliva contamination and decontamination procedures on shear bond strength of self-etch dentine bonding systems: An in vitro study. J Conserv Dent [serial online] 2010 [cited 2019 Oct 22];13:71-5. Available from: http://www.jcd.org.in/text.asp?2010/13/2/71/66714

   Introduction Top


Adhesion to dentine has been a subject of considerable interest because it is a more heterogeneous substrate with much higher organic and water content than enamel. [1] The condition of the tooth structure and the chemical composition of the adhesive agent have shown to affect the bond strength. [2] Hence, improving adhesive restorative materials has been the objective of research in the recent years.

Clinically, there are many factors that affect adhesion and retention of resin-containing restorative materials. Moisture such as gingival fluid, blood, hand-piece oil [3] and, in particular saliva, can affect the quality of the bond, leading to micro-leakage at the tooth restoration interface. This may result in the loss of restoration, recurrent caries, postoperative sensitivity and discoloration. [4] Therefore the bonding procedure requires proper isolation and prevention of contamination. However, many carious lesions which require the use of dentine bonding agents are found in the areas that are difficult to isolate, especially when the site is near or at the gingival margin where saliva contamination is more likely to occur. [5]

Silverstone et al.[6] have reported that saliva contamination of etched enamel caused a significant decrease in bond strength between the resin and enamel surface. It was suggested that the contamination of etched enamel by salivary proteins prevented monomers from penetrating the pores in enamel, which reduced the bond strength. [3] Microscopic examination of saliva contaminated acid-etched enamel showed the formation of an organic pellicle that could not be removed with water. [6] The organic pellicle coating masked the underlying enamel pores, decreased resin accessibility and impaired mechanical adhesion. However, the contaminated enamel could be reconditioned by an additional 10 seconds of acid etching. [7]

Dentine adhesion is extremely complex when compared to enamel bonding. The micromechanical resin adhesion to dentine differs fundamentally from the relatively simple interlocking of bonding agents with enamel. Therefore the result of many studies related to the bonding efficacy of saliva contaminated dentine bonding agents has varied. [1] Fritz, Finger and Stean [8] found that saliva contamination of cured one-bottle type adhesive resulted in low shear bond strengths and wide marginal gaps. On the contrary, others reported that the saliva contamination of dentine had no adverse effect on the bonding efficiency of one-bottle adhesive systems. [9],[10],[11]

Recently developed adhesive systems such as the "self-etching primers" and the "self-etch adhesives" have shown to be resistant to salivary contamination. [4],[12] Self-etch systems eliminate the rinsing and drying steps which simplifies the bonding procedure. In addition to this, the possibility of over wetting or over drying is reduced, which in turn helps in better adhesion. [13],[14],[15] These dentine bonding agents have a reduced number of components and application steps and this reduces the risk of saliva contamination in the field of operation. [16]

Hence this study was conducted to evaluate the influence of saliva contamination of dentine during the bonding procedure on shear bond strength and to investigate the effect of contamination removing treatment on the recovery of bond strength of two self-etch dentine bonding systems.


   Materials and Methods Top


We tested two dentine adhesives in the study: AdheSE (Ivoclar - Vivadent, Schaan, Liechtenstein) and Adper Prompt Self-Etch Adhesive (3M ESPE, St Paul, MN, USA) [Table 1]. Filtek P-60 posterior restorative composite resin (3M ESPE, St Paul, MN, USA) was used in both the groups. Sixty premolars extracted for orthodontic reasons were obtained for the shear bond test. The teeth were debrided, cleaned and stored in isotonic saline, until use. The teeth were sectioned at the cementodentinal junction and the coronal portion of the teeth was embedded in acrylic with the buccal surface facing outwards. The buccal surface of the teeth was reduced to create flat dentine surface with a medium grit diamond bur using high-speed handpiece under air water spray. The specimens were then randomly divided into two groups (AdheSE (ASE) group and Adper Prompt (ADP) group) of 30 samples each.

For each adhesive, the specimens were divided into non-contaminated (which was the control group), contaminated and decontaminated sub-groups (which were the experimental groups). Ten specimens were made for each procedure. In the experimental groups, fresh whole saliva was applied to the surface of the specimens with a disposable brush for 5 seconds, followed by the contaminant removing treatment, if applicable. Details of the bonding procedure for each adhesive are presented. Following the bonding procedure, a 5 mm composite resin block was built on the substrate using a plastic tube having an internal diameter of 4.9 mm by progressively adding 1.5 to 2 mm thick increments. In order to ensure the proper polymerization of each added layer of composite resin, the light tip was positioned as close as possible to the surface.

After polymerization, the teeth were sectioned 1 mm apical to cemento-enamel junction and the specimens were mounted in cylindrical molds with self-curing acrylic resins. Shear bond strength was tested with an Instron Universal testing machine (Instron Corporation, Canton, MA, USA). Each specimen was mounted in a shear testing apparatus and a chisel shaped shearing rod with a cross-head speed of 1 mm per minute was used to load the specimens at the dentine-composite interface. The shear bond strength data was subjected to One-way ANOVA test, while the intergroup comparison was made using Tukey multiple comparison and Unpaired t-test.


   Results Top


The results of the shear bond strength test to AdheSE (ASE) and Adper Prompt (ADP) are shown in [Table 2] and [Table 3] and [Figure 1]. One-way ANOVA test revealed a significant difference at P <0.05. Comparisons within the groups ASE and ADP are shown in [Table 4] and [Table 5].

In the AdheSE group (ASE), the difference was very highly significant (P = 0.001) between the control (ASE-I) and the contamination sub-group (ASE-II). The shear bond strength decreased to 5.4 ± 2.2 MPa when compared to 11.8 ± 2.6 MPa of control group. However, when the self -etch primer was reapplied after the salivary contamination (ASE-III), the bond strength increased to 8.9 ± 3.3 MPa (P = 0.019). There was no significant difference in the bond strength between the control and the decontamination group (P = 0.064).

In Adper Prompt group (ADP), when the dentine was not contaminated (ADP-I), the shear bond strength was 7.4 ± 1.5 MPa. When the salivary contamination occurred after the curing of the bonding agent (ADP-II), the bond strength decreased to 4.6 ± 1.1 MPa. This decrease in bond strength was highly significant (P= 0.003). The bond strength of ADP-III where Adper Prompt bonding agent was reapplied after salivary contamination was 14.1 ± 2.2 MPa. This was statistically very highly significant than the control group and the group where salivary contamination was done (P= 0.001).

Intergroup comparisons between ASE and ADP were done using Unpaired t-test. [Table 6] shows the comparison of bond strength when the specimens were not contaminated with saliva. There was statistically very highly significant difference between the mean bond strengths of ASE-I and ADP-I (P=0.001). The control specimens of AdheSE group showed higher bond strength than that of Adper Prompt group.


   Discussion Top


The laboratory parameter most often measured in dentine adhesion is shear bond strength. Flat dentine surfaces are prepared in the extracted tooth, the adhesive system is applied and the composite resin cylinder is bonded over the adhesive. A shear force is then applied at the resin-dentine interface, using a knife-edge probe. The shear bond strength test is only a rough tool for evaluating the relative efficacy of bonding materials. Never the less, they are excellent for screening new materials and for comparing the same parameter among different adhesive systems. [17]

Saliva contamination of operating field is a frequent problem in restorative procedures, especially when rubber dam isolation is difficult or impossible, such as in the case of deep cervical lesions or to seat an indirect restoration or even in patients having problem in opening their mouth. In the present study natural saliva was chosen as the contaminant because artificial saliva may confound the results. In addition, many studies have accepted whole healthy human saliva as an acceptable contaminating medium. An in vitro model to mimic clinical conditions proved that saliva and plasma to be detrimental to hybrid layer formation. [8]

Effect of saliva contamination is a matter of great controversy. Few studies have reported that the use of dentine bonding agents under fissure sealants has reduced their sensitivity to saliva contamination and provided high bond strengths. [18],[19] Some have reported that the saliva contamination of dentine had no adverse effect on the bonding efficiency of one-bottle adhesive systems. [9],[10],[11] Others have shown that the saliva contamination of the dentine surface produced a significant decrease in the bond strength. [3],[8],[17],[20]

The factors that can be hypothesized as the cause for reduction in the bond strength in saliva contaminated dentine are as follows: [8],[21]

  1. Adsorption of glycoprotein to the poorly polymerized adhesive surface where they might act as a barrier that prevents complete wetting with the next increment of resin and thus prevent adequate co-polymerization.
  2. Salivary proteins might prevent monomers from penetrating the collagen network of dentine or there can be an increase in the contact angle which could decrease the bond strength.
  3. Excess saliva may dilute the primer and thus produce a weak hybrid layer.
  4. Co-polymerization with the subsequent resin layer could be compromised by the removal of the oxygen inhibited unpolymerized surface layer. This hypothesis is not likely as investigators have shown that there is no difference in bond strength when resin composite is added and polymerized on cured adhesive with or without an unpolymerized surface layer.


Ghavam and Pour [20] showed that there was no significant difference when the contaminated dentine was either washed or washed and re-etched. Fritz et al[8] showed that re-etching is not necessary when contamination with the saliva happens. EL -Kalla and Godoy [12] believed that when saliva contamination happens after etching the dentine, blot drying the surface achieves bond strength equal to that of the uncontaminated group. Studies have also shown that the reapplication of primer/ adhesive to improve the bonding efficiency after saliva contamination. [22],[23]

The hydrophilic nature of the newer dentine bonding agents may allow them to function to some degree in the presence of saliva contamination by displacing or diffusing through it and then they infiltrate and polymerize within the exposed collagen bundles of demineralized superficial dentine. AdheSE is a relatively new self- etching system containing a primer composed of phosphonic acid acrylate, bis-acrylamide, water, initiators and stabilizers. It also contains a bonding component composed of dimethacrylate, HEMA and highly dispersed silicon-di-oxide, initiators and stabilizers. In the AdheSE group, when the saliva contamination was done after the application of self etching primer, bond strength decreased significantly. However, the bond strength could be recovered after reapplication of the primer. This result was in agreement with the study done by Park and Lee. [17]

Adper Prompt Self-Etch Adhesive is based on the original Prompt-L-Pop adhesive and is composed of methacrylated phosphonic esters, BisGMA, initiators, stabilizers, water, HEMA and poly alkenoic acid. In Adper Prompt group, there was a significant decrease in bond strength when saliva contamination occurred after curing the bonding agent. This finding confirms the observation of Fritz and others [8] who have shown that saliva contamination of the cured adhesive layer of one-bottle adhesive system has a detrimental effect on bond strength.

Studies have shown that saliva contamination reduces the dentine bond strengths of all-in-one adhesives and supplementary application of the adhesive after cleaning the saliva from the dentine surface is an empirical recommendation for restoring bond strength. [22],[23] In contrast to the results of this study, Ghavan and Pour [20] have shown that contamination of a single bottle system after curing of the adhesive did not decrease the bond strength compared to the control group.

An interesting finding in Adper Prompt group was that the bond strength obtained in the sub-group where the bonding agent was reapplied after saliva contamination was higher than the control group. This increase in bond strength was very highly significant (P= 0.001). The increased bond strength could be due to the effect of multiple adhesive coatings. The increased resin-dentine bond strength under multiple applications could be due to several mechanisms operating simultaneously. As the solvent is evaporated the concentration of the co-monomers that exists after each coating increases. This improves the hybrid layer and the ratio of the polymerized vs. unpolymerized adhesive layer due to oxygen inhibition. Hashimoto and others [24],[25],[26] have hypothesized that when multiple coats of hydrophilic adhesive solutions are applied, it can displace or diffuse through the film to reach the underlying layer and improve the bond strength.

Intergroup comparison of ASE-I (control) and ADP-I (control) showed that AdheSE has higher bond strength to that of Adper Prompt. This difference in the bond strength was very highly significant (P= 0.001). The low bond strength obtained with this system may be due to an incomplete infiltration of the acidic monomers and subsequent partial dissolution of the smear layer, suggesting inconsistent performance in terms of achieving a quality bond. [27]

Further studies have to be conducted to prove these results.


   Conclusions Top


The following conclusions can be drawn within the limitations of this in vitro study;

  1. The self etch primer [AdhSE (ASE-I)] showed better bond strength than self-etch adhesive [Adper Prompt (ADP-I)] when not contaminated with saliva.
  2. Salivary contamination reduced the dentine bond strength of both the self-etch primer (ASE-II) and adhesives (ADP-II).
  3. Re-application of the primer for the AdhSE group (ASE-III) and re-application of the adhesive for the Adper Prompt group (ADP-III), after air drying the saliva off, can recover the dentine bond strength.
  4. In the Adper Prompt group, the added application of adhesives to decontaminate (ADP-III), not only recovered the bond strength but also improved it significantly, which could be attributed to the effect of multiple adhesive coatings


 
   References Top

1.Jhonson ME, Burgess JO, Hermesch CB, Buikema DJ. Saliva contamination of Dentine bonding agents. Oper Dent 1994;19:205-10.  Back to cited text no. 1      
2.Van Meerbeck BV, Inoue S, Perdigao S, Lambrechts P, Vanherle G. Enamel and dentin adhesion. In: Summitt JB, Robbins JW, Schwartz RS, editors. Fundamentals of Operative Dentistry 2nd ed. Chicago: Illinios Quintessence Publishing Co, Inc; 2000. p. 178-221.   Back to cited text no. 2      
3.Xie J, Powers JM, McGuckin RS. In vitro bond strength of two non-adhesives to enamel and dentin under normal and contaminated conditions. Dent Materials 1993;9:295-9.  Back to cited text no. 3      
4.Hitmi L, Attal JP, Degrange M. Influence of the time point of salivary contamination on dentin shear bond strength of 3 dentin adhesive systems. J Adhes Dent 1999;1:219-32.  Back to cited text no. 4      
5.Mojon P, Kaltio R, Feduik D, Hawbolt EB, McEntee MI. Short term contamination of luting cements by water and saliva. Dent Materials 1996;12:83-7.   Back to cited text no. 5      
6.Silverstone LM, Hicks MJ, Featherstone MJ. Oral fluid contamination of etched enamel surfaces: An SEM study. J Am Dent Assoc 1985;110:329-32.  Back to cited text no. 6      
7.Hormati AA, Fuller JL, Deney JE. Effects of contamination and mechanical disturbance on the quality of acid-etched enamel. J Am Dent Assoc 1980;100:34-8.  Back to cited text no. 7      
8.Fritz UB, Finger WJ, Stean H. Salivary contamination during bonding procedures with a one-bottle adhesive system. Quintessence Int 1998;29:567-72.  Back to cited text no. 8      
9.Taskonak B, Sertgoz A. Shear bond strengths of saliva contaminated "one- bottle" adhesives. J Oral Rehabil 2002;29:559-64.  Back to cited text no. 9      
10.Yoo HM, Oh TS, Pereira PN. Effect of saliva contamination on the microshear bond strength of one-step self-etching adhesive systems to dentin. Oper Dent 2006;31:127-34.   Back to cited text no. 10      
11.Yazici AR, Tuncer D, Dayangaη B, Ozgόnaltay G, Onen A. The effect of saliva contamination on microleakage of an etch-and-rinse and a self-etching adhesive. J Adhes Dent 2007;9:305-9.   Back to cited text no. 11      
12.EL- Kalla IH, Gracia- Godoy F. Saliva contamination of bond strength of single bottle adhesives to enamel and dentin. Am J Dent 1997;10:83-7.  Back to cited text no. 12      
13.Milia E, Lallai MB, Gracia- Godoy F. In vitro effect of a self etching primer on dentin. Am J Dent 1999;12:167-71.  Back to cited text no. 13      
14.Brackett WW, Tay FR, Looney SW, Ito S, Haisch LD, Pashley DH. Microtensile dentin and enamel bond strengths of recent self-etching resins. Oper Dent 2008;33:89-95.   Back to cited text no. 14      
15.Hόrmόzlό F, Ozdemir AK, Hubbezoglu I, Coskun A, Siso SH. Bond strength of adhesives to dentin involving total and self-etch adhesives. Quintessence Int 2007;38:e206-12.  Back to cited text no. 15      
16.Perdigγo J. New developments in dental adhesion. Dent Clin North Am 2007;51:333-57.  Back to cited text no. 16      
17.Park J, Lee KC. The influence of salivary contamination on shear bond strength of dentin adhesive systems. Oper Dent 2004;29:437-42.  Back to cited text no. 17      
18.Boren LM, Fiegal RJ. Reducing microleakage of sealants under salivary contamination. Quintessence Int 1994;25:283-9.  Back to cited text no. 18      
19.Fiegal RJ, Hilt J, Spleith C. Retaining sealant on salivary contaminated enamel. J Am Dent Assoc 1993;124:88-97.   Back to cited text no. 19      
20.Ghavam M, Pour Sh K. Effect of different salivary decontamination procedures on bond strength to dentin in single bottle systems. J Dent Tehran University of Medical Sciences 2004;1:5-10.  Back to cited text no. 20      
21.Oztoprak MO, Isik F, Sayinsu K, Arun T, Aydemir B. Effect of blood and saliva contamination on shear bond strength of brackets bonded with 4 adhesives. Am J Orthod Dentofac Orthop 2007;131:238-42.  Back to cited text no. 21      
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23.Eiriksson SO, Pereira PN, Swift EJ Jr, Heymann HO, Sigurdsson A. Effects of saliva contamination on resin-resin bond strength. Dent Materials 2004;20:37-44.  Back to cited text no. 23      
24.Hashimoto M, Sano H, Yoshida E, Hori M, Kaga M, Oguchi H, et al. Effects of multiple adhesive coatings on Dentin bonding. Oper Dent 2004;29:416-23.  Back to cited text no. 24      
25.Albuquerque M, Pegoraro M, Mattei G, Reis A, Loguercio AD. Effect of double application of a hydrophobic layer for improved efficacy of One-step Self-etch system in enamel and dentin. Oper Dent 2008;33:564-70.   Back to cited text no. 25      
26.Ito S, Tay FR, Hashimoto M, Yoshiyama M, Saito T, Brackett WW, et al. Effects of multiple coatings of two all-in-one adhesives on dentin bonding. J Adhes Dent 2005;7:133-41.   Back to cited text no. 26      
27.Sensi LG, Lopes GC, Monteoro S, Baratieri LN, Vieira LCC. Dentin bond strength of self- etching primers / adhesives. Oper Dent 2005;30:63-8.  Back to cited text no. 27      

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Correspondence Address:
Manuel S Thomas
Department of Conservative Dentistry and Endodontics, Manipal College of Dental Sciences, Light House Hill Road, Mangalore, Karnataka-575 001
India
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/0972-0707.66714

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    Figures

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    Tables

  [Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6]

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[Pubmed] | [DOI]



 

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