In Vitro Analysis of Quality of Dental Adhesive Bond Systems Applied in Various Conditions
by
, , , , and
Agata Trzcionka
1,*
,
Ruta Narbutaite
2, 
Alma Pranckeviciene
2,
Rytis Maskeliūnas
3,
Robertas Damaševičius
4,
Gintautas Narvydas
5,
Dawid Połap
6
,
Katarzyna Mocny-Pachońska
1,
Marcin Wozniak
6 and
Marta Tanasiewicz
1 1
Faculty of Mediacl Sciences in Zabrze, Department of Conservative Dentistry with Endodontics, Medical University of Silesia, Plac Akademicki 17, 41-902 Bytom, Poland
2
Faculty of Odontology, Department of Dental and Oral Pathology, Lithuanian University of Health Sciences, Eivenių g. 2, 50103 Kaunas, Lithuania
3
Faculty of Informatics, Department of Multimedia Engineering, Kaunas University of Technology, K. Baršausko 59-A338, LT-51423 Kaunas, Lithuania
4
Department of Applied Informatics, Vytautas Magnus University, LT-44404 Kaunas, Lithuania
5
Faculty of Electrical Engineering, Department of Control Systems, Kaunas University of Technology, K. Baršausko 59-A338, LT-51423 Kaunas, Lithuania
6
Faculty of Applied Mathematics, Silesian University of Technology, 44-100 Gliwice, Poland
*
Author to whom correspondence should be addressed.
Coatings 2020, 10(9), 891; https://doi.org/10.3390/coatings10090891
Submission received: 26 August 2020
/
Revised: 10 September 2020
/
Accepted: 15 September 2020
/
Published: 17 September 2020
(This article belongs to the Special Issue Surface Properties of Dental Materials and Instruments)
Abstract
:Introduction: There are several methods of reducing a microleakage, and one of them is choosing appropriate adhesive material. The aim of the work was the in vitro analysis of 4 bonds: 3M ESPE “Single bond”, Dentsply “Prime and Bond Active”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”. Material and methods: 136 healthy molar teeth were collected and randomly split into 4 groups and Vth Class cavities were prepared. Chosen adhesives were used in four groups of teeth with the same composite. Teeth were the thermocycled, sealed, covered with lacquer, and submerged in 1% methylene blue solution for 24 h. After the thermocycling, the vertices of each tooth were sealed using dental wax. Each tooth was then fully covered with lacquer. All teeth were then submerged into 1% methylene blue solution for 24 h in room temperature. In the next step they were transversely cut through a center of restoration. The Olympus BX43 microscope was used to photograph each cut tooth. With the usage of Olympus stream software, measurement of the dye’s leakage was performed. Results. The statistical analysis proved that the most effective material when applied to ideally prepared cavity surface was Dentsply “Prime and Bond Active”. The second material was 3M ESPE “Single Bond”, third—Coltene “One Coat 7 Universal” and fourth—Kuraray “Clearfil Universal Bond Quick”. The most effective material applied to a too-dry surface was Dentsply “Prime and Bond Active”, second—3M ESPE “Single Bond”, third—Coltene “One Coat 7 Universal” and fourth—Kuraray “Clearfil Universal Bond Quick”. When it comes to too damp surfaces the best results were obtained with Dentsply “Prime and Bond Active” then Coltene “One Coat 7 Universal”, 3M ESPE “Single Bond” and Kuraray “Clearfil Universal Bond Quick”. Conclusion: The level of cavity dampness influences the quality of adhesives. Better results are obtained with over-dried surfaces than over-damp, which is connected with the dilution of the material.
1. Introduction
Microleakage is a result of imperfect bonding that allows the passage of bacteria and fluids between the restorative material and the tooth [1]. Microleakage can cause negative effects, such as higher sensitivity of the restored tooth, and secondary caries [2]. Whilst microleakage in clinical conditions is unavoidable, microleakage can be reduced by selecting proper combinations of adhesive materials, application techniques and curing strategies [3]. Research on microleakage provides useful information on the characteristics of adhesive materials [4]. Previously, the relationship between bond strength and microleakage of dentistry adhesives has been an object of several studies [5,6,7,8,9]. The failure of adhesive materials has been identified as the main cause of secondary caries and dental fracturing [10]. A wide variety of bonding materials currently available makes it difficult for dentists to choose the best alternative in terms of adhesive materials [11]. While in vitro testing of dental material may not accurately replicate the clinical situation in vivo, in vitro research for assessing performance and properties of dental materials is an important aspect of dentistry that enables researchers to perform experiments under controlled conditions [12]. It is common in restorative dentistry to research dental materials using extracted animal or human teeth. For example, image-processing methods were applied on the images of extracted teeth for detection of dental filling size and its gap [13]. This study, while still correlating with those researching the effects of microleakage is very novel in its purpose not only to analyze the adhesive or bonding strength in vitro, as was the original goal of other researchers and/or manufacturers of such materials, but also to study the microleakage of the adhesive materials, which is one of the less-trialed factors, directly concerning long-term reliability, often leading to multiple dental diseases [14]. It is important to note that other dye-leakage studies have mostly evaluated the leakage level by degrees only [15,16,17,18], while Phanombualert et al. [19] also offered measurements in micrometers. This study combines both. In practical terms, the real value presented here is to allow less experienced dentists to predict/estimate a quality of repair, as reaching the ideal working field conditions when restoring extensive cavities is one of the more skill based tasks. The results of this evaluation study offer a suggestion on choosing a specific material for a specific dampness level within a cavity. In this study, authors follow the guidelines for reporting pre-clinical in vitro studies on dental materials [12].
The aim of the work was the analysis bonding quality of dental adhesive bonds 3M ESPE “Single bond”, Dentsply “Prime and Bond Active”, Coltene “One Coat 7 Universal”, Kuraray “Clearfil Universal Bond Quick” by studying the microleakage of leading adhesive materials in vitro.
2. Materials and Methods
We collected 136 healthy (caries free) molar teeth extracted due to prosthetic and orthodontic indications from Lithuania (121) and Poland (15) All teeth were immediately submerged into a physiological liquid after extraction. Next, all teeth were cleaned from any calculus, dental plaque and remains of soft body tissues. All teeth were randomly split into 4 groups of 34 teeth (nM = 34). Each group was then subdivided into 3 subgroups representing ideal, damp or too-dry conditions the cavity.
All class V cavities due to Black’s classification were prepared using the same approach on lingual or vestibular tooth surface among the line of cement enamel joint (CEJ), targeting the cavity reach towards both surfaces of enamel and dentin. Upper cavity boundary was always in the enamel zone and lower cavity boundary was always in the cement (dentin) zone. All cavities were prepared using the same type of green diamond rose burrs (using a fast speed tips) and external shape was formulated with a cylinder tool as was determined to be most effective restoration quality-wise by [20]. Each sample was prepared with the use of cooling water spray. The drill bit was changed to identical new bits after drilling each of the subgroups (after 10 teeth). Each cavity was made to exactly these dimensions: 3 mm × 3 mm × 1.5 mm (depth) ± 0.3 mm. The accuracy was verified and adjusted using a periodontal probe, following recommendations from [21]. Each cavity was carefully washed and dried.
To explore the adhesive qualities in varying conditions (ideal, damp or too dry dentin) 4 leading brands of universal dental adhesive bonds were selected for our evaluation: 3M ESPE “Single bond”, Dentsply “Prime and Bond Active”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”. The chemical properties of each material are summarized in Table 1.
All cavities were prepared according to these three conditions of each subgroup:
A is ideal conditions as specified by each manufacturer,
B are over-dried conditions,
C are too-damp conditions.
Each adhesive was added (in the amount and application method specified) as per original instruction. A curing lamp of the same strength (GC/Mectron Silverlight, average intensity of 1350 mW/cm2) was used to activate all materials. All teeth were filled using the same Dentsply “Ceram X” composite, strictly following manufacturer’s instructions. The same lamp was used for curing process. Restoration was undertaken carefully, polishing with Dentsply “Ceram X gloss” polishes of different roughness (blue and white). The fill quality was then carefully evaluated using a 3.5× zoom lens (Olympus Corporation, Shinjuku, Tokyo, Japan) with white light-emitting diode (LED) light.
Group 1A was filled using 3M ESPE “Single bond” in ideal working conditions, following manufacturer’s instructions. Group 1B was filled using the same adhesive, only this time over drying a surface of the drilled cavity. Alternatively, group 1C was filled when the cavity surface was too wet. The same process was repeated for the remaining groups only using different adhesive: 2A/B/C were filled using Dentsply “Prime and Bond Active” adhesive, 3A/B/C using Coltene “One Coat 7 Universal” adhesive, 4A/B/C using Kuraray “Clearfil Universal Bond Quick” adhesive.
Each sample was exposed to a temperature cycling test to resemble oral cavity environment. An ABB high precision industrial robot (type: IRB120 M2004) (ABB Ltd., Zurich, Switzerland) was programmed to achieve 3000 cycles of submerging the teeth into cold and hot water baths for exactly 1 min following the recommendation of Cevik et al. [22] and Noda et al. [23]. The ABB robot was programmed to precisely handle the specimen basket to cyclically submerge and retract into a different temperature environments. Robot was programmed to repeat a constant action of smooth arm swing from one thermal bath to another, following an exact coordinate path with necessary slowdowns and interpolations. The graceful change period to shift a basket with teeth was set to 16 s from bath-to-bath allowing it to avoid spillage of water, not shifting the teeth themselves, and also no measurable cool down. A total length of a full cycle was 136 s. The submersion process was for a total, uninterrupted period of 4 days, 17 h and 13 min, in a clean room, with a person providing 24/7 on-site supervision. Two “Hart Scientific” Temperature Calibration baths were used for a constant and precise upkeep of water temperature. We have used a model 6022 as a hot water container (55 ± 0.3 °C) and model 7312 as a cold water container (5 ± 0.3 °C). Both baths were filled with distilled water and raised to the same top height. Teeth were placed in a custom made brass basket. The whole rig is displayed in Figure 1.
After the thermocycling the vertices of each tooth were sealed using a dental wax. Each tooth was then fully covered with lacquer. All teeth were then submerged into 1% methylene blue solution for 24 h in room temperature (around 21 °C). All removed teeth were carefully washed in distilled water after the 24 h.
All teeth were mounted one by one, suspended (temporary molded into) in acrylic auto-polymer iTEMP “Self Curing Acrylic Resin”, each block was then assigned a unique ID number and transversely cut through a center of restoration (see Figure 2 for illustration) using a slow speed diamond saw rig Buehler “IsoMet Low Speed Saw” (Model: 11-1280-250) (Bühler Holding AG, Uzwil, Switzerland) with a ±0.0001 in [±5 µm] precision via a manual micrometer. Series 15LC blade disk was used (No. 11-4254). (Bühler Holding AG, Uzwil, Switzerland). Each cut tooth was analyzed and photographed using Olympus BX43 microscope (Olympus Corporation, Shinjuku, Tokyo, Japan) with white LED lamp (U-LHLEDC), with a 4× zoom lens setting, using a camera sensor Olympus DP72 (Olympus Corporation, Shinjuku, Tokyo, Japan) (12.8 megapixel cooled digital color camera, capturing each color of RGB at 12 bits, at ISO 1600 setting, image color calibrated to AdobeRGB color space.
A hermeticity level of each filling was evaluated using a different degree of leakage of the dye: 0—no leakage; 1—dye has seeped through half of the cavity wall (lengthwise); 2—dye has seeped through the full length of the cavity wall; 3—dye has seeped through the full length of the cavity wall and has reached the bottom of the cavity (the axial wall). All leakage (seep length) measurements were taken using Olympus stream software. Some sample resulting images are given in Figure 2.
3. Results
The resulting dental image dataset consists of 2004 images; 416 photos were made under the microscope (standard light), as well as grayscale and inverted color modes. Additionally we supplemented the dataset with 252 regular photography images of cut and uncut teeth (also available in color, grayscale and inverted modes). Both halves of 121 teeth datasets were analyzed and the depth of leakage measured in micrometers. The results of analysis are also presented in Figure 3 as distribution of microleakage vs. degrees of leakage. Generally, larger microleakage translates to a larger degree of leakage. However note that outliers in Figure 3 shows microleakage through both walls (a high total value in micrometers) although the leak in these cases did not reach the bottom of the cavity (the reason for a different degree than a measurement of leakage depth would indicate).
The experimental analysis has shown that the most effective material when applied to ideally prepared cavity surface was Dentsply “Prime and Bond Active” with least amount of micro leakage (210 microns/degree of 0.6, see Figure 4a). The second best material was 3M ESPE “Single Bond” (1250 microns/degree of 1.5, see Figure 4b), third—Coltene “One Coat 7 Universal” (1980 microns/degree of 2.2, see Figure 4c), fourth—Kuraray “Clearfil Universal Bond Quick” (3250 microns/degree of 2.8, see Figure 4d).
The most effective material applied to too dry surface was Dentsply “Prime and Bond Active” with least amount of micro leakage (120 microns/degree of 0.4, see Figure 5a). The second best material was 3M ESPE “Single Bond” (1270 microns/degree of 1.3, see Figure 5b), third—Coltene “One Coat 7 Universal” (1490 microns/degree of 1.91, see Figure 5c), fourth—Kuraray “Clearfil Universal Bond Quick” (5050 microns/degree of 2.9, see Figure 5d).
The most effective material applied on too damp surfaces was also Dentsply “Prime and Bond Active” (670 microns/degree of 0.6, see Figure 6a). The second best was Coltene “One Coat 7 Universal” (890 microns/degree of 1.2, see Figure 6b), third—3M ESPE “Single Bond” (2460 microns/degree of 2.1, see Figure 6c), fourth—Kuraray “Clearfil Universal Bond Quick” (5690 microns/degree of 3, see Figure 6d).
The characteristics of teeth in the dataset itself are represented as a bubble plot in Figure 7, which shows the data from the perspective of surface cavity conditions.
The overall measurements have shown that the most effective adhesive overall was Dentsply “Prime and Bond Active”, objectively measured as 2.45 times more effective than the second best material Coltene “One Coat 7 Universal”. Kuraray “Clearfil Universal Bond Quick” was the least effective material in all conditions. The most forgiving non-ideal condition was the over-dried surface.
The analysis of the results used statistical methods.
For statistical analysis of data, we used the Wilcoxon signed test, Mann–Whitney U-test, Kruskal–Wallis test and Nemenyi test. Statistical analysis was performed using MATLAB (ver. 8.6.0.267246 (R2015b), Mathworks, Natick, MA, USA, 2018) software. The results are presented in Figure 8. The Wilcoxon signed rank test shows significant difference between Dentsply “Prime and Bond Active” and 3M (z = −4.011), Kuraray “Clearfil Universal Bond Quick” and 3M ESPE “Single bond” (z = 4.638), Coltene “One Coat 7 Universal” and Dentsply “Prime and Bond Active” (z = 3.655), Kuraray “Clearfil Universal Bond Quick” and Dentsply “Prime and Bond Active” (z = 4.782), and Kuraray “Clearfil Universal Bond Quick” and Coltene “One Coat 7 Universal” (z = 4.453) adhesive bonds (all p < 0.001). The results were confirmed by the Mann–Whitney U-test, also showing significant difference between Dentsply “Prime and Bond Active” and 3M ESPE “Single bond” (z = −5.221), Kuraray “Clearfil Universal Bond Quick” and 3M (z = 5.552), Coltene “One Coat 7 Universal” and Dentsply “Prime and Bond Active” (z = 4.556), Kuraray “Clearfil Universal Bond Quick” and Dentsply “Prime and Bond Active” (z = 6.573), and Kuraray “Clearfil Universal Bond Quick” and Coltene “One Coat 7 Universal” (z = 5.833) adhesive bonds (all p < 0.001). The Kruskal–Wallis test shows that there was significant effect of bond material on microleakage results at the p < 0.05 level [F(3,116) = 73.946, p = 6 × 10−16]. The Nemenyi post-hoc test was applied to determine whether differences between dental adhesive bonds were statistically significant, with a significance level of p = 0.05. The Nemenyi test shows significant differences between Dentsply, Kuraray and other bond materials, with Dentsply having the highest rank and Kuraray having the lowest one, while the difference between Coltene and 3M ESPE bonds were statistically insignificant (critical distance = 0.32).
4. Discussion
The principle adopted in restorative dentistry is that restorations should be undertaken with the best possible marginal quality to avoid postoperative sensitivity, marginal discoloration, and secondary caries [1,4,24,25]. Different laboratory methods claim to predict the clinical performance of restorative materials, for example, tests of bond strength and microleakage and gap analysis. Microleakage studies are sometimes used to assess the bonding quality and questions remain on the validity of such comparisons [3,7].
Microleakage studies might differentiate the quality of various materials and also bonding systems used under different conditions so as to simulate clinical situations affecting the quality of the enamel-composite interface in in vitro studies. The significance of the results obtained in the study presented by the authors also lies in the simulation of the oral cavity conditions through the use of the variable temperature cycles in the methodology [22,23]. In our experiment, the application of the adhesives in a single layer was used, as indicated by the manufacturer; the possibility of its use in two layers is reported in order to enhance the bond strength. Fujiwara et al. in their work [26] recommended the application of universal adhesives in two layers improved the adhesive quality when compared to the application in a single layer.
Solvents are one of the most important components of universal bonding systems. The bonding systems evaluated in the present study were no different from each other in relation to their solvents—all contain water and ethanol or isopropanol. This is consistent with the results of other studies which have reported a higher bonding ability in all-in-one adhesives containing a higher amount of ethanol [27].
The overall quality of the adhesive strength varied according to the level of cavity surface dampness. Over-dried surfaces exhibited a feature of bonding more strongly than those of the too-damp surfaces, probably due to dilution of the material. We have noticed that over-drying leads to demineralization of dentin, which probably depends on poorer levels of monomer penetration. The resulting possible microleakage still exhibits some degree of probability on all types of the materials analyzed, especially in the class V restorations. An important aspect of our experiment is to allow the analysis of the “imperfect” conditions, which most often occur in clinical situations concerning dental cavities class V located in the gingival area. The validity of the results obtained in this way and their usefulness for other researchers is also determined by a very large group of results received on the basis of a huge collection of microscopic images [12].
With regard to the fact that the variabe humidity conditions of the tissues resulted in a quality of marginal restorative adhesion, its worth considering the introduction and wider promotion of multi-mode universal adhesives in clinical bonds’ application [28]. Multi-mode universal adhesives give clinicians the choice of using the etch-and-rinse technique, selective enamel etch technique or self-etch technique to bond to tooth substrates and thus offer the possibility to modify the form of application depending on the location of the cavity, the outline of the enamel, the depth of the cavity and humidity [2,4].
5. Conclusions
Quality of adhesive varies on the level of cavity surface dampness. Over-dried surfaces exhibit bonding more strongly than over-damp surfaces due to dilution of material.
Due to frequency in maintaining the optimal humidity conditions for the moisture content of the cavity surface, the most expected universal adhesive system should have a strong adhesion/minimal microleakage even in sub-optimal moisture conditions.
With the introduction of the next new generation of bonding systems on the dental materials‘ market, there is a need to test the microleakage by methods that can be applied to the results of other researchers.
The method for assessing dye penetration in a marginal microleak can be an effective tool for analysis, provided that thermocycling simulation of variable conditions in the oral cavity is used.
Author Contributions
Conceptualization, A.P., R.M., and D.P.; methodology, A.P., R.M., R.D., G.N., and M.W.; formal analysis, G.N. and D.P.; investigation, R.N., R.M., R.D., and M.W.; resources, A.T., K.M.-P., and M.T.; writing—original draft preparation, A.T. and R.N.; writing—review and editing, M.T.; project administration, R.D. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Acknowledgments
We acknowledge Abdel-Badeeh M. Salem (Ain Shams University, Egypt), Sanjay Misra (Covenant University, Nigeria) and Basem AL-Madani (King Fahd University of Petroleum and Minerals, Saudi Arabia) for their valuable spiritual support.
Conflicts of Interest
The authors declare no conflict of interest.
Compliance with Ethical Standards
The Bioethics Center of Lithuanian University of Health Sciences has approved this research and issued a permit to Ruta Narbutaite (referral No. BEC-0F-81, 2017-11-08) certifying the compliance with the ethical principles of code of conduct of the human-related studies. The informed consent was obtained from all participants. No identities nor medical records of original healthy tooth owners were ever collected, nor used to conduct this research.
References
- Ozdogan, A.; Akyil, M.S.; Duymus, Z.Y. Evaluating the microleakage between dentin and composite materials. Dent. Med. Probl. 2018, 55, 261–265. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Gupta, A.; Tavane, P.; Gupta, P.K.; Tejolatha, B.; Lakhani, A.A.; Tiwari, R.; Kashyap, S.; Garg, G. Evaluation of microleakage with total etch, self-etch and universal adhesive systems in Class V restorations: An in vitro study. J. Clin. Diagn. Res. 2017, 11, ZC53–ZC56. [Google Scholar] [CrossRef] [PubMed]
- Fabianelli, A.; Pollington, S.; Davidson, C.; Cagidiaco, M.; Goracci, C. The Relevance of Micro-Leakage Studies. Int. Dent. SA 2007, 9, 64–74. [Google Scholar]
- Alhabdan, A.A. Review of microleakage evaluation tools. J. Int. Oral Health 2017, 9, 141–145. [Google Scholar] [CrossRef]
- Fortin, D.; Swift, E.J.; Denehy, G.E.; Reinhardt, J.W. Bond strength and microleakage of current dentin adhesives. Dent. Mater. 1994, 10, 253–258. [Google Scholar] [CrossRef]
- Hasegawa, T.; Retief, D.H.; Russell, C.M.; Denys, F.R. Shear bond strength and quantitative microleakage of a multipurpose dental adhesive system resin bonded to dentin. J. Prosth. Dent. 1995, 73, 432–438. [Google Scholar] [CrossRef]
- Ateyah, N.Z.; Elhejazi, A.A. Shear bond strengths and microleakage of four types of dentin adhesive materials. J. Contemp. Dent. Pract. 2004, 15, 63–73. [Google Scholar] [CrossRef]
- Moghaddas, M.J.; Moosavi, H.; Ghavamnasiri, M. Microleakage Evaluation of Adhesive Systems Following Pulp Chamber Irrigation with Sodium Hypochlorite. J. Dent. Res. Dent. Clin. Dent. Prospects 2014, 8, 21–26. [Google Scholar] [CrossRef]
- El Haddar, Y.S.; Cetik, S.; Bahrami, B.; Atash, R. A Comparative Study of Microleakage on Dental Surfaces Bonded with Three Self-Etch Adhesive Systems Treated with the Er: YAG Laser and Bur. Biomed. Res. Int. 2016, 2016, 2509757. [Google Scholar] [CrossRef] [Green Version]
- Maas, M.S.; Alania, Y.; Natale, L.C.; Rodrigues, M.C.; Watts, D.C.; Braga, R.R. Trends in restorative composites research: What is in the future? Braz. Oral Res. 2017, 28, e55. [Google Scholar] [CrossRef] [Green Version]
- Matos, A.B.; Trevelin, L.T.; Silva, B.T.F.D.; Francisconi-Dos-Rios, L.F.; Siriani, L.K.; Cardoso, M.V. Bonding efficiency and durability: Current possibilities. Braz. Oral Res. 2017, 28, e57. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Faggion, C.M., Jr. Guidelines for reporting pre-clinical in vitro studies on dental materials. J. Evid. Based. Dent. Pract. 2012, 12, 182–189. [Google Scholar] [CrossRef] [PubMed]
- Osadcha, O.; Trzcionka, A.; Pachońska, K.; Pachoński, M. Detection of Dental Filling Using Pixels Color Recognition. In Communications in Computer and Information Science; Damaševičius, R., Vasiljevienė, G., Eds.; Springer: Cham, Switzerland, 2018; Volume 920, pp. 347–356. [Google Scholar] [CrossRef]
- Somani, R.; Jaidka, S.; Arora, S. Comparative evaluation of microleakage of newer generation dentin bonding agents: An in vitro study. Indian J. Dent. Res. 2016, 27, 86–90. [Google Scholar] [CrossRef] [PubMed]
- Zanatta, R.F.; Lungova, M.; Borges, A.B.; Torres, C.R.G.; Sydow, H.G.; Wiegand, A. Microleakage and shear bond strength of composite restorations under cycling conditions. Oper. Dent. 2017, 42, 71–80. [Google Scholar] [CrossRef]
- Bolgul, B.S.; Anya, B.; Simsek, I.; Celenk, S.; Seker, O.; Kilinc, G. Leakage testing for different adhesive systems and composites to permanent teeth. Niger. J. Clin. Pract. 2017, 20, 787–791. [Google Scholar] [CrossRef] [Green Version]
- Jacker-Guhr, S.; Ibarra, G.; Oppermann, L.S.; Luhrs, A.K.; Rahman, A.; Geurtsen, W. Evaluation of microleakage in class V composite restorations using dye penetration and micro-CT. Clin. Oral Investig. 2016, 20, 1709–1718. [Google Scholar] [CrossRef]
- Mozaffari, H.R.; Ehteshami, A.; Zallaghi, F.; Chiniforush, N.; Moradi, Z. Microleakage in Class V Composite Restorations after Desensitizing Surface Treatment with Er: YAG and CO2 Lasers. Laser Ther. 2016, 25, 259–266. [Google Scholar] [CrossRef] [Green Version]
- Phanombualert, J.; Chimtim, P.; Heebthamai, T.; Weera-Archakul, W. Microleakage of Self-Etch Adhesive System in Class V Cavities Prepared by Using Er:YAG Laser with Different Pulse Modes. Photomed. Laser Surg. 2015, 33, 467–472. [Google Scholar] [CrossRef]
- Muhammed, G.; Dayem, R. Evaluation of the microleakage of different class V cavities prepared by using Er:YAG laser; ultrasonic device, and conventional rotary instruments with two dentin bonding systems (an in vitro study). Lasers Med. Sci. 2015, 30, 969. [Google Scholar] [CrossRef]
- Al Shayeb, K.N.; Turner, W.; Gillam, D.G. Accuracy and reproducibility of probe forces during simulated periodontal pocket depth measurements. Saudi Dent. J. 2014, 26, 50–55. [Google Scholar] [CrossRef] [Green Version]
- Cevik, P.; Eraslan, O.; Eser, K.; Tekeli, S. Shear bond strength of ceramic brackets bonded to surface-treated feldspathic porcelain after thermocycling. Int. J. Artif. Organs 2018, 41, 160–167. [Google Scholar] [CrossRef] [PubMed]
- Noda, Y.; Nakajima, M.; Takahashi, M.; Mamanee, T.; Hosaka, K.; Takagaki, T.; Ikeda, M.; Foxton, R.M.; Tagami, J. The effect of five kinds surface treatment agents on the bond strength to various ceramics with thermocycler aging. Dent. Mater. J. 2017, 36, 755–761. [Google Scholar] [CrossRef] [PubMed]
- Söderholm, K.J.M. Coatings in dentistry—A review of some basic principles. Coatings 2012, 2, 138–159. [Google Scholar] [CrossRef]
- Maj, A.; Trzcionka, A.; Twardawa, H.; Tanasiewicz, M. A comparative clinical study of the self- adhering Flowable composite resin Vertise Flow and the traditional flowable resin Premise Flow. Coatings 2020, 10, 800. [Google Scholar] [CrossRef]
- Fujiwara, S.; Takamizawa, T.; Barkmeier, W.W.; Tsujimoto, A.; Imai, A.; Watanabe, H.; Erickson, R.L.; Latta, M.A.; Toshiyuki, N.; Miyazaki, M. Effect of double-layer application on bond quality of adhesive systems. J. Mech. Behav. Biomed. Mater. 2018, 77, 501–509. [Google Scholar] [CrossRef]
- Vichi, A.; Margvelashvili, M.; Goracci, C.; Papacchini, F.; Ferrari, M. Bonding and sealing ability of a new self-adhering flowable composite resin in class I restorations. Clin. Oral Investig. 2013, 17, 1497–1506. [Google Scholar] [CrossRef]
- Chen, C.; Niu, L.-N.; Xie, H.; Zhang, Z.-Y.; Zhou, L.-Q.; Jiao, K.; Chen, J.-H.; Pashley, D.H.; Tay, F.R. Bonding of universal adhesives to dentine—Old vine in new bottles? J. Dent. 2015, 43, 525–536. [Google Scholar] [CrossRef] [Green Version]
Figure 1.
Submersion rig made from ABB robot and two Hart Scientific thermal baths.
Figure 2.
Tooth cut in half using a high precision Beuhler cutter. Rig is on the left, cut tooth sample on the right.
Figure 2.
Tooth cut in half using a high precision Beuhler cutter. Rig is on the left, cut tooth sample on the right.
Figure 3.
Distribution of microleakage in micrometers vs degrees of leakage: 0—no leakage; 1—dye has seeped through half of the cavity wall (lengthwise); 2—dye has seeped through the full length of the cavity wall; 3—dye has seeped through the full length of the cavity wall and has reached the bottom of the cavity (the axial wall).
Figure 3.
Distribution of microleakage in micrometers vs degrees of leakage: 0—no leakage; 1—dye has seeped through half of the cavity wall (lengthwise); 2—dye has seeped through the full length of the cavity wall; 3—dye has seeped through the full length of the cavity wall and has reached the bottom of the cavity (the axial wall).
Figure 4.
Samples of microleakage in ideal surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) 3M ESPE “Single bond”, (c) Coltene “One Coat 7 Universal”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 4.
Samples of microleakage in ideal surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) 3M ESPE “Single bond”, (c) Coltene “One Coat 7 Universal”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 5.
Samples of microleakage in too dry surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) 3M ESPE “Single bond”, (c) Coltene “One Coat 7 Universal”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 5.
Samples of microleakage in too dry surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) 3M ESPE “Single bond”, (c) Coltene “One Coat 7 Universal”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 6.
Samples of microleakage in ideal surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) Coltene “One Coat 7 Universal”, (c) 3M ESPE “Single bond”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 6.
Samples of microleakage in ideal surface cavity conditions: (a) Dentsply “Prime and Bond Active”, (b) Coltene “One Coat 7 Universal”, (c) 3M ESPE “Single bond”, and (d) Kuraray “Clearfil Universal Bond Quick”.
Figure 7.
Summary of data: microleakage in micrometers/degrees of leakage (Dentsply “Prime and Bond Active”, 3M ESPE “Single bond”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”).
Figure 7.
Summary of data: microleakage in micrometers/degrees of leakage (Dentsply “Prime and Bond Active”, 3M ESPE “Single bond”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”).
Figure 8.
Results of statistical analysis using the Wilcoxon signed rank test, Mann–Whitney U-test, Kruskal–Wallis test and Nemenyi test (Dentsply “Prime and Bond Active”, 3M ESPE “Single bond”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”).
Figure 8.
Results of statistical analysis using the Wilcoxon signed rank test, Mann–Whitney U-test, Kruskal–Wallis test and Nemenyi test (Dentsply “Prime and Bond Active”, 3M ESPE “Single bond”, Coltene “One Coat 7 Universal”, and Kuraray “Clearfil Universal Bond Quick”).
Table 1.
Chemical properties and application protocol of 4 adhesive bonds.
| Adhesive Bond | Specification | Application |
|---|---|---|
| 3M ESPE “Single Bond” | Methacryloyloxydecyl dihydrogen phosphateMDP Phosphate Monomer, Dimethacrylate resins, hydroxyethylmethacrylate (HEMA), Vitrebond™ Copolymer, Filler, Ethanol, Water, Initiators, Silane | Apply with the microbrush for 20 s, apply air for 5 s, light cure for 10 s. |
| Dentsply “Prime and Bond Active” | Bi- and multifunctional acrylate (bisphenol A-glycidyl methacrylate (bisGMA), urethane dimethacrylate (UDMA), trithylene glycol dimethacrylate(TEGDMA)), Phosphoric acid modified acrylate resin (PENTA, MDP), Initiator, Stabilizer, Isopropanol, Water | Apply adhesive, slight agitation, mild air blowing (>5 s), light cure for 10 s. |
| Coltene “One Coat 7 Universal | Metacrilatos (MDP), photoinitiators, ethanol, water | Apply with a microbrush, scrub for 20 s, gentle air drying for 5 s, light cure for 10 s. |
| Kuraray “Clearfil Universal Bond Quick” | HEMA, bisGMA, MDP, hidrophylic amid monomers, colloidal silica, silane, natrium fluoride, ethanol, water, initiator, activator | Apply in rubbing motion, air blowing (≥5 s), light cure for 10 s. |
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Trzcionka, A.; Narbutaite, R.; Pranckeviciene, A.; Maskeliūnas, R.; Damaševičius, R.; Narvydas, G.; Połap, D.; Mocny-Pachońska, K.; Wozniak, M.; Tanasiewicz, M. In Vitro Analysis of Quality of Dental Adhesive Bond Systems Applied in Various Conditions. Coatings 2020, 10, 891. https://doi.org/10.3390/coatings10090891
AMA Style
Trzcionka A, Narbutaite R, Pranckeviciene A, Maskeliūnas R, Damaševičius R, Narvydas G, Połap D, Mocny-Pachońska K, Wozniak M, Tanasiewicz M. In Vitro Analysis of Quality of Dental Adhesive Bond Systems Applied in Various Conditions. Coatings. 2020; 10(9):891. https://doi.org/10.3390/coatings10090891
Chicago/Turabian StyleTrzcionka, Agata, Ruta Narbutaite, Alma Pranckeviciene, Rytis Maskeliūnas, Robertas Damaševičius, Gintautas Narvydas, Dawid Połap, Katarzyna Mocny-Pachońska, Marcin Wozniak, and Marta Tanasiewicz. 2020. "In Vitro Analysis of Quality of Dental Adhesive Bond Systems Applied in Various Conditions" Coatings 10, no. 9: 891. https://doi.org/10.3390/coatings10090891
APA StyleTrzcionka, A., Narbutaite, R., Pranckeviciene, A., Maskeliūnas, R., Damaševičius, R., Narvydas, G., Połap, D., Mocny-Pachońska, K., Wozniak, M., & Tanasiewicz, M. (2020). In Vitro Analysis of Quality of Dental Adhesive Bond Systems Applied in Various Conditions. Coatings, 10(9), 891. https://doi.org/10.3390/coatings10090891
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