Serviços Personalizados
Artigo
Indicadores
Links relacionados
- Citado por Google
- Similares em Google
Compartilhar
South African Dental Journal
versão On-line ISSN 0375-1562
versão impressa ISSN 0011-8516
S. Afr. dent. j. vol.75 no.6 Johannesburg Jul. 2020
http://dx.doi.org/10.17159/2519-0105/2020/v75no6a3
RESEARCH
The effect of off-axis seating on the marginal adaptation of full coverage all ceramic crowns
GP BabiolakisI; CP OwenII
IBDS (Wits), MScDent (Wits), Postgraduate student, Department of Prosthodontics, School of Oral Health Science, Faculty of Health Sciences, University of the Witwaters-rand, Johannesburg, South Africa
IIEmeritus Professor, Faculty of Health Sciences, University of the Witwaters-rand, Johannesburg, South Africa. ORCID Number: 0000-0002-9565-8010
ABSTRACT
INTRODUCTION: No studies on the marginal gap or internal fit of crowns have reported the effect of non-axial seating which may often occur inadvertently clinically.
AIM: Therefore this in vitro study sought to investigate the off-axis seating of CAD/CAM crowns and its effect on the marginal gap and internal fit.
METHOD: A standardised crown preparation on a typodont tooth was used to design and mill 30 crowns with a flat occlusal surface. Ten Zirconia (Dentsply Sirona, Germany), 10 Enamic (Vita, Austria), and 10 Brilliant Crios (Coltene, Switzerland) crowns were milled, Ave of each milled with a luting space of 100µm, and Ave of 200µm. The marginal gap was measured in two and three dimensions after luting with silicone on a 3D-printed metal replica. Seating occurred axially, at 5° buccally and 5° lingually. The silicone was used to calculate the internal fit
RESULTS: Axial seating with a 100 µm luting space obtained the smallest marginal gap, irrespective of material or luting space. 3D measurements were larger than 2D measurements, but not significantly. The maximum off-axis gap was 117µm, on the opposite side to which pressure was applied.
CONCLUSIONS: Care must be taken clinically to ensure that luting takes place in an axial direction only.
Keywords: Marginal gap, Internal fit, Luting Space, full crown.
INTRODUCTION
The introduction of Computer-Aided Design and Computer-Aided Manufacturing (CAD/CAM) technology has allowed for improved aesthetics compared with ceramo-metal crowns.1
The luting space within a prosthesis is created to allow the formation of a film of luting agent between the tooth and prosthesis. With CAD/CAM this space is created by selecting the milling parameters within the software to produce a pre-defined cement space when the restoration is milled. However, different manufacturers (of which there are now more than 70)2 have recommended different luting spaces, and several studies have linked luting space to marginal gap measurements.3-7
Recommendations have ranged from 10 µm to 100µm, with the larger spaces generally producing the smaller marginal gaps both before and after actual or replicated cementation.4-6,8-12
The milling process to achieve the luting space is limited by the size of the burs used, and the movements of the axes of the milling machine. This in turn influences the preparation form, and in case that form is not ideal, manufacturers have recommended a luting space of up to 100 µm. The smallest diameter bur is generally 1 mm and so any sharp edges in a preparation would not be reproduced, hence the 100 µm recommended space.
The marginal gap can be defined as the vertical and horizontal dimension from the finish line of the preparation to the margin of the restoration. The internal fit can be described as the area between the crown and the tooth that will be occupied by cement.13
Failure of restorations to seat completely can result in a sizeable marginal gap and occlusal prematurities resulting in sensitivity, and may cause the prosthesis to loosen prematurely.14
Discrepancies in the marginal gap can lead to micro-leakage;15 plaque retention at the margin;16 secondary caries and pulpal involvement;17,18 and changes in the microflora causing the development of periodontal disease,19-21 any and all of which could ultimately result in failure of the crown.
Many studies have measured the marginal gap and internal fit of full coverage restorations using different methods, with varying results. It is generally accepted that marginal gaps below 120 µm are clinically acceptable.22-26 With regards to the internal fit, it is clinically relevant to ensure that adequate space is created to allow an even thickness of dental cement.
The marginal gap was was originally measured at a few points around the circumference but it has been found that to determine an accurate marginal gap it is necessary to measure at least 18 locations around the circumference of the tooth.27
Several methods have been used to evaluate the marginal gap including the use of an optical microscope;28-33 using a profile projector;3 profilometry;34 embedding in epoxy resin and sectioning and measured with a three-dimensional microscope;35-39 cementation and use of microCT;40-43 and the use of a silicone luting replica tech-nique.3,13,30,35,41,43,44 The silicone replica technique can also be used to measure the overall total fit of the crown and provides a correlation with the marginal gap.
None of the studies have reported on the effect of non-axial seating discrepancies, and these are known to happen in the clinical environment, as finger pressure is used to cement a crown.
Therefore this in vitro study sought to investigate the off-axis seating of CAD/CAM crowns and its effect on the marginal gap and internal fit, using three different materials, a zirconia (Dentsply Sirona, Germany), a polymer infiltrated ceramic network (PICN) (Enamic, Vita, Austria), and a composite (Brilliant Crios, Coltene, Switzerland).
METHOD
A resin typodont molar tooth was prepared to produce a standardised crown preparation with a total convergence angle of 12 degrees as measured digitally from the scanned image using Finite Element Analysis (FEA) Software (Solidworks, SolidWorks Corp, United States), internally rounded shoulder margins of 1.5mm circum-ferentially, and an occlusal reduction of 1.5 mm. All line angles were rounded. The surface area of the preparation was calculated from the scan using the FEA software, to aid in the internal fit calculations.
The typodont tooth was scanned with the CEREC Omnicam intra-oral scanner (Sirona Dental Systems. Germany), and 30 crowns were milled with a flat occlu-sal surface. The flat occlusal surface of the crowns aided in seating the crown off-axis and axially. Ten Zirconia, 10 Enamic, and 10 Brilliant Crios crowns were milled using a CEREC MC X milling machine (Sirona Dental Systems, Germany). In each group, five crowns were milled with a luting space of 100 µm and the other Ave crowns with a luting space of 200 µm.
Each crown was then seated on the metal replicated tooth set in a typodont model with adjacent teeth to provide contact points. The typodont model was set on a custom-made tilting device (adapted from the model-holding device of a model surveyor) that allowed the model to be tilted 5 degrees to either side, and a standard 3 kg weight was lowered parallel to the ground simulating cementation pressure.
Each crown was filled with light-body polyvinyl siloxane material (Express XT light-body quick, 3MESPE, Germany) to represent the luting agent and seated onto the tooth. A constant load was placed on the crown with the 3 kg weight for 10 minutes with the model either straight, tilted 5 degrees buccally or 5 degrees lingually.
Excess impression material was removed using a scalpel. Thereafter the marginal gap was measured at 12 points according to marking points on the metal tooth at 6 points buccally and 6 points lingually.
The marginal gaps were measured at these points using a Reflex Microscope (Reflex Measurement Ltd., Cambridge, UK) which is a microscope and an optical plotter that uses a virtual point of light to measure objects in two and three dimensions (Fig. 3), with an accuracy of 4 µm.45 There is some difficulty in locating the virtual point of light, especially on the z-axis, and so the entire experiment was repeated on three separate occasions to assess measurement consistency.
The crown was then removed, and the silicone impression material removed and weighed to calculate the overall internal fit according to the formula:3
Sample size and statistical analysis
The literature review has shown that marginal gaps of greater than 120 µm were considered the limit of clinical acceptability.
Given an expected mean marginal gap of 110µm for any group, and aiming to detect a difference of more than 20% from this, given a within-group relative standard deviation of 22% (which corresponds to an effect size of d = 0.83), 80% power and the 5% significance level, a total sample size of 24, i.e. 4 per group, would be required.46 It was decided, however, to use 5 per group as the expected mean gap may differ from the above.
Reliability was tested by the Intra-class Correlation Coefficient (ICC). Test-retest reliability for whether or not the marginal gap exceeded 120 µm was determined by Cohen's kappa.
Post-hoc tests were carried out using the Tukey-Kramer adjustment for unequal group sizes (to allow for the deletion of outliers). From the post-hoc tests, the material-luting space combinations which had the smallest values for the outcomes were determined.
All measurements were below the limit of 0.120 mm, so it was not necessary to measure comparisons between the experimental groups. Comparison of the marginal gap between matching 3D measurements was carried out using the paired samples t-test.
Within each material, across both luting spaces, the difference between buccal and lingual readings for each seating direction was compared using the paired samples t-test. The effect of luting space on the 2D and 3D outcomes for each direction of seating, was determined by a repeated measures ANOVA with the outcome as the dependent variable, luting space as the independent variable, and experiment as the repeated measure. The effect of material was determined similarly. Data analysis was carried out using Statistical Analysis Software (SAS) version 9.4 for Windows. The 5% significance level was used.
RESULTS
The Intraclass Correlation Coefficients (ICC) for the marginal gap measurements ranged between 0.78 and 0.99, representing excellent agreement and so the average of all three sets of measurements was used for further analysis.
Marginal gap measurements
Table 1 shows the minimum, maximum, and mean marginal gap measurements in all scenarios.
In all circumstances, the marginal gap did not exceed 120 µm. For all materials and luting spaces, the maximum value (117 µm) occurred on the buccal marginal gap when seating was applied at an angle to the lingual, and on the lingual marginal gap (112 µm) it occurred when seating was applied at an angle to the buccal.
For all 2D and 3D measurements and their differences between buccal and lingual, the ANOVA showed that the three-factor interaction was significant for each measurement set (Table 2).
The differences between the buccal and lingual marginal gap measurements for each seating direction were calculated and then compared, combining the 100 and 200 µm measurements.
In all cases, the buccal and lingual measurements differed significantly for buccal and lingual seating angles except for two 3D measurements for Enamic and Zir-conia which were not significantly different for axial seating, but this direction yielded the smallest difference ranging from 3.2 µm-20.1µm.
When comparing materials, there were no significant differences between materials for any seating angle. The smallest differences were again found for the axial seating. For 2D measurements, this ranged from 10.4 µm -20.1 µm, and for 3D measurements, this ranged from 3.5 µm - 9.4 µm.
For all materials, the differences between the buccal and lingual marginal gaps were grouped into the buccal, axial and lingual seating directions, to compare the luting spaces (Table 3).
The only statistically significant differences between the 100 µm and 200 µm spaces, for both the 2D and 3D measurements, were for the axial direction of seating. The actual gaps averaging all buccal and lingual measurements for the axial seating only are shown in Table 4.
All 2D and 3D measurements, irrespective of material, pressure and luting space were then compared. The 3D measurements for the buccal marginal gap were an average of 13.5 µm higher than the corresponding 2D measurements (95% confidence interval: 12.0-15.0µm; p< 0.0001).
The 3D measurements for the lingual marginal gap were an average of 13.4 µm higher than the corresponding 2D measurements (95% confidence interval: 10.9-15.8 µm; p<0.0001).
When the buccal and lingual gaps were combined, the 3D measurements were an average of 13.4 µm higher than the corresponding 2D measurements (95% confidence interval: 11.7-15.1 µm; p<0.0001).
Internal fit measurements
The effects of material, seating direction, and luting space, and their interaction, on each outcome were compared and the ANOVA source table is shown as Table 5.
The signifant interactions were between the material and the seating direction, and the material and luting space.
Post-hoc tests revealed the following significant differences:
• The mean internal fit was significantly higher for all Zirconia seating angles (p<0.0001) compared with Enamic and Crios, but not within Zirconia.
• Within Enamic, the mean internal fit for lingual seating was greater than buccal (p=0.0088) and axial (p = 0.0052).
• Within Crios, the mean internal fit for buccal seating was greater than for the occlusal (p = 0.014).
When comparing the luting spaces, Post-hoc tests revealed the following significant differences:
• The mean internal fit was significantly higher for all 200 µm experiments compared with all 100 µm experiments (p<0.0001).
• Within the 100 µm experiments, the mean internal fit decreased in the order Zirconia > Enamic (p<0.0001) > Crios (p<0.0078).
• Within the 200 µm experiments, the mean internal fit decreased in the order Zirconia > Enamic (p< 0.0055) > Crios (p<0.0034).
DISCUSSION
This is the first study to be carried out to measure and compare the effect of off-axis seating on the adaptation of full coverage crowns using the marginal gap and internal fit as excellent proxies for the clinical quality and success of a restoration.
Discrepancies in the marginal gap can lead to a variety of problems which could ultimately result in failure of the crown.15-21 It is generally accepted that marginal gaps below 120µm are clinically acceptable.22-26,47,48
With regards to the internal fit, it is clinically relevant to ensure that adequate space is created to allow an even thickness of dental cement. Theoretically, the space required for the cement to lute is 20-40µm, as cement thickness ranges from 25-50 µm, and an acceptable practical guide was set between 50µm and 100µm.49
In CAD/CAM restorations, a luting space is used to allow for this, and several studies have linked luting space to marginal gap measurements.3-7 In the literature, luting space recommendations have ranged from 10 µm to 100 µm. The larger spaces have produced the smaller marginal gaps both before and after actual or replicated cementation.4-6,8-12
In this study, it was decided to use luting spaces of 100 µm and 200 µm. In a pilot study it had been observed that, as finger pressure is used to cement a crown, it is possible that it may not seat evenly if seated at an angle to the occlusal. No studies have reported on the effect of non-axial seating discrepancies.
It was evident that seating the crown off-axis at just 5° did affect the marginal gap: there was a significant difference between the buccal and lingual marginal gap measurements in all cases when the crowns were seated off axis, but it was interesting to note that none of the marginal gaps measured exceeded 120µm. However, the greatest discrepancies were observed in off-axis seating with a luting space of 200µm for all materials, indicating that that luting space is proably too large and may produce more off-axis seating clinically.
There were statistically significant differences between the 100µm and 200µm spaces, for both the 2D and 3D measuremets, for the axial direction of seating, indicating that the luting space did affect the marginal gap.
The smallest gaps were from the axial seating using the 100 µm luting space. Overall, for all materials these differences for the 2D measurements ranged from 10.4 µm - 20.1 µm, and for 3D measurements, from 3.5µm - 9.4µm.
Overall the 3D measurements were 13.4 µm greater, but not significantly different from the corresponding 2D measurements (p = 0.92). These measurements are to be expected, as the 3D gap is likely always to be higher
than the 2D measurement, but they are nevertheless all extremely low, which is a testament to the accuracy of the milling of these crowns. As with the marginal gaps, within each material, axial seating yielded the smallest internal fit when compared with off-axis seating.
The internal fit of a crown is just as important as the marginal gap, as it enables the seating of the crown and expression of cement, while also aiding in retention and resistance.31 The mean internal fit for all 200 µm crowns was significantly higher than the 100 µm crowns, which was expected.
This also shows that the CAD/CAM process is highly accurate, generating an internal fit for each crown which closely resembles the luting space chosen. Clinically the results obtained in this study have implications.
Irrespective of material used when seating a crown, a minor tilt of even 5 degrees can result in a larger marginal gap specifically on the opposite side to the pressure being applied.
Although this study did not find these measurements to be above 120µm, some marginal gaps were still large, with one reaching 117µm.
Previous studies which measured the marginal gap of crowns found that they ranged from <70µm50, 52 µm to 74µm3, a median of 130.2 and 132.2 µm, 51 below 90µm.52 The marginal gaps measured in this study which more closely resemble those of other studies are the values measured for axial seating.
Should other studies have taken into consideration the tilt that may be found when seating off axis, they may have measured larger results. In this study the marginal gaps ranged from 36µm -117µm with off-axis seating and 31 µm - 99 µm with axial seating.
The other factor not taken into consideration in other studies is measuring the marginal gap buccally and lin-gually separately. Gassino et al. (2004)27 found that to obtain an accurate overall marginal gap measurement requires at least18 points around the circumference of the tooth to be measured.
However, this again did not take into account the tilt and used an average of all measurements to arrive at a marginal gap. Considering that a larger marginal gap will be found on the opposite side to the pressure being applied it is necessary to measure the buccal and lingual sides separately, to yield an accurate result that resembles the correct fit of the crown.
CONCLUSION
Within the limitations of this study, it was found that, irrespective of the material, seating off-axis at 5 degrees buccally or lingually resulted in a marginal gap which was larger on the opposite side to which pressure was applied. The smallest marginal gaps and internal fit were obtained when seating axially, with a luting space of 100 µm.
All measurements made in three dimensions were larger than those derived for two-dimensional measurement, but the difference, average of 13.4 µm, was not significant. None of the measurements, whether cemented axially or off-axis were larger than 120 µm. However, when seating off axis, the largest gap was 117µm as opposed to seating axially which yielded a mean maximum marginal gap measurement of 76 µm.
It is recommended that future studies should measure the marginal gap both buccally and lingually separately and not just use an average to obtain an accurate measurement, and that a method needs to be devised to cement crowns axially in the clinical environment to provide the best fit possible and minimise complications.
Acknowledgements
We are grateful to Dr P Gaylard for statistical advice and analysis.
Declaration
The authors declare no conflict of interest.
References
1. Masek R. Achieving high-level esthetics with CEREC. Com pend Contin Educ Dent. 2001; 22 (6 Suppl): 19-26. https://www.medicalexpo.com/medical-manufacturer/dental-labora-tory-milling-machine-28385.html. (Accessed April 2020). [ Links ]
2. Nakamura T, Dei N, Kojima T, Wakabayashi K. Marginal and internal fit of Cerec 3 CAD/CAM all-ceramic crowns. Int J Prosthodont. 2003; 16(3): 244-8. [ Links ]
3. Hmaidouch R1, Neumann P, Mueller WD. Influence of preparation form, luting space setting and cement type on the marginal and internal fit of CAD/CAM crown copings. Int J Comput Dent. 2011; 14(3): 219-26. [ Links ]
4. Shim JS, Lee JS, Lee JY, Choi YJ, Shin SW, Ryu JJ. Effect of software version and parameter settings on the marginal and internal adaptation of crowns fabricated with the CAD/ CAM system. J Appl Oral Sci. 2015; 23(5): 515-22. [ Links ]
5. Kale E, Seker E, Yilmaz B, Òzcelik TB. Effect of cement space on the marginal fit of CAD-CAM-fabricated monolithic zirconia crowns. J Prosthet Dent. 2016; 116(6): 890-5 [ Links ]
6. Dauti R, Lilaj B, Heimel P, Moritz A, Schedle A, Cvikl B. Influence of two different cement space settings and three different cement types on the fit of polymer-infiltrated ceramic network material crowns manufactured using a complete digital workflow. Clin Oral Investig. 2019; Sep 13. doi: 10.1007/s00784-019-03053-1 (Online ahead of print). [ Links ]
7. Wang CJ, Millstein PL, Nathanson D. Effects of cement, cement space, marginal design, seating aid materials, and seating force on crown cementation. J Prosthet Dent. 1992; 67(6): 786-90 [ Links ]
8. Wilson, PR. Effect of increasing cement space on cementation of artificial crowns. J Prosthet Dent. 1994; 71(6): 560-4. [ Links ]
9. Wu JC, Wilson PR. Optimal Cement Space for Resin Luting Cements Int J Prosthodont. 1993; 7(3): 209-215 [ Links ]
10. Iwai T, Komine F, Kobayashi K, Saito A, Matsumura H. Influence of convergence angle and cement space on adaptation of zirconium dioxide ceramic copings. Acta Odontol Scand. 2008; 66(4): 214-8. [ Links ]
11. Yildirim G, Uzun IH, Keles A. Evaluation of marginal and internal adaptation of hybrid and nanoceramic systems with microcomputed tomography: an in vitro study. J Prosthet Dent 2017; 118(2): 200-7. [ Links ]
12. Kokubo Y, Tsumita M, Kano T, Sakurai S, Fukushima, S. Clinical marginal and internal gaps of zirconia all-ceramic crowns. J Prosthodont Res 2011; 55(1): 40-43. [ Links ]
13. Abelson J. Cementation of cast complete crown retainers. J Prosthet Dent. 1980; 43(2): 174-9. [ Links ]
14. Jacobs MS, Windeler AS. An investigation of dental luting cement solubility as a function of the marginal gap. J Prosthet Dent. 1991; 65: 436-42. [ Links ]
15. Valderhaug J, Hel0e LA. Oral hygiene in a group of supervised patients with fixed prostheses. J Periodontol. 1977; 48(4): 221-4. [ Links ]
16. Goldman M, Laosonthorn P, White RR. Microleakage e full crowns and the dental pulp. J Endod 1982; 18(10): 473-5. [ Links ]
17. Rinke S, Fornefett D, Gersdorff N, Lange K, Roediger M. Multifactorial analysis of the impact of different manufacturing processes on the marginal fit of zirconia copings. Dent Mater J. 2012; 31: 601-9. [ Links ]
18. Lang N, Kiel R, Anderhalden K. Clinical and microbiological effects of subgingival restorations with overhanging or clinically perfect margins. J Clin Periodontol. 1983; 10(6): 563-78. [ Links ]
19. Hunter AJ, Hunter AR. Gingival margins for crowns: a review and discussion. Part II: Discrepancies and configurations. J Prosthet Dent. 1990; 64: 636-42. [ Links ]
20. Felton DA, Konoy BE, Bayne MS, Wirthman GP. Effect of in vivo crown margin discrepancies on periodontal health. J Prosthet Dent 1991; 65: 357-64. [ Links ]
21. McLean J, von Fraunhofer J. The estimation of cement film thickness by an in vivo technique. Brit Dent J 1971; 131(3): 107-111. [ Links ]
22. Belser U, MacEntee M, Richter W. Fit of three porcelain-fused-to-metal marginal designs in vivo: A scanning electron microscope study. J Prosthet Dent. 1985; 53(1): 24-9. [ Links ]
23. Weaver J, Johnson G, Bales D. Marginal adaptation of castable ceramic crowns. J Prosthet Dent 1991; 66(6): 747-53. [ Links ]
24. Fonseca J, Henriques G, Sobrinho L, de Góes M. Stress-relieving and porcelain firing cycle influence on marginal fit of commercially pure titanium and titanium-aluminium-vanadium copings. Dent Mater. 2003; 19(7): 686-91. [ Links ]
25. Karatasli O, Kursoglu P, Capa N, Kazazoglu E. Comparison of the marginal fit of different coping materials and designs produced by computer aided manufacturing systems. Dent Mater J. 2011; 30: 97-102. [ Links ]
26. Gassino G, Barone Monfrin S, Scanu M, Spina G, Preti G. Marginal adaptation of fixed prosthodontics: a new in vitro 360-degree external examination procedure. Int J Prosthodont. 2004; 17(2): 218-23. [ Links ]
27. Yeo I, Yang J, Lee J. In vitro marginal fit of three all-ceramic crown systems. J Prosthet Dent. 2003; 90(5): 459-64. [ Links ]
28. Akbar J, Petrie C, Walker M, Williams K, Eick, J. Marginal Adaptation of Cerec 3 CAD/CAM Composite Crowns Using Two Different Finish Line Preparation Designs. J Prosthodont. 2006; 15(3): 155-63. [ Links ]
29. Lee K, Park C, Kim K, Kwon, T. Marginal and Internal Fit of All-ceramic Crowns Fabricated with Two Different CAD/CAM Systems. Dent Mater J. 2008; 27(3): 422-6. [ Links ]
30. Beuer F, Edelhoff D, Gernet W, Naumann M. Effect of preparation angles on the precision of zirconia crown copings fabricated by CAD/CAM system. Dent Mater J. 2008; 27(6): 814-20. [ Links ]
31. Alghazzawi T, Liu P, Essig M. The Effect of Different Fabrication Steps on the Marginal Adaptation of Two Types of Glass-Infiltrated Ceramic Crown Copings Fabricated by CAD/CAM Technology. J Prosthodont. 2012; 21(3): 167-72. [ Links ]
32. Jayaraman S, Rajan B, Kandhasamy B, Rajakumaran I. Evaluation of marginal fit and internal adaptation of zirconia copings fabricated by two CAD - CAM systems: An in vitro study. J Indian Prosthodont Soc. 2015; 15(2): 173-8. [ Links ]
33. Mitchell C, Pintado M, Douglas W. Nondestructive, in vitro quantification of crown margins. J Prosthet Dent. 2001; 85(6): 575-84. [ Links ]
34. Tsitrou E, Northeast S, van Noort R. Evaluation of the marginal fit of three margin designs of resin composite crowns using CAD/CAM. J Dent. 2007; 35(1): 68-73. [ Links ]
35. Han H, Yang H, Lim H, Park Y. Marginal accuracy and internal fit of machine-milled and cast titanium crowns. J Prosthet Dent. 2011; 106(3): 191-7. [ Links ]
36. Souza R, Òzcan M, Pavanelli C, Buso L, Lombardo G, Michi-da S, et al. Marginal and Internal Discrepancies Related to Margin Design of Ceramic Crowns Fabricated by a CAD/ CAM System. J Prosthodont. 2011; 21(2): 94-100. [ Links ]
37. Biscaro L, Bonfiglioli R, Soattin M; Vigolo, P. An In Vivo Evaluation of Fit of Zirconium-Oxide Based Ceramic Single Crowns, Generated with Two CAD/CAM Systems, in Comparison to Metal Ceramic Single Crowns. J Prosthodont. 2012; 22(1): 36-41. [ Links ]
38. Sachs C, Groesser J, Stadelmann M, Schweiger J, Erdelt K; Beuer F. Full-arch prostheses from translucent zirconia: Accuracy of fit. Dent Mater 2014; 30(8): 817-23. [ Links ]
39. Seo D, Yi Y; Roh, B. The effect of preparation designs on the marginal and internal gaps in Cerec3 partial ceramic crowns. J Dent. 2009; 37(5): 374-82. [ Links ]
40. Rungruanganunt P, Kelly J, Adams D. Two imaging techniques for 3D quantification of pre-cementation space for CAD/CAM crowns. J Dent. 2010; 38(12): 995-1000. [ Links ]
41. Alfaro D, Ruse N, Carvalho R; Wyatt, C. Assessment of the Internal Fit of Lithium Disilicate Crowns Using Micro-CT. J Prosthodont. 2015; 24(5): 381-6. [ Links ]
42. Moldovan O, Luthardt R, Corcodel N, Rudolph H. Three-dimensional fit of CAD/CAM-made zirconia copings. Dent Mater 2011; 27(12): 1273-8. [ Links ]
43. Anunmana C, Charoenchitt M, Asvanund C. Gap comparison between single crown and three-unit bridge zirconia sub structures. J Adv Prosthodont. 2014; 6(4): 253-8. [ Links ]
44. Speculand B, Butcher G, Stephens C. Three-dimensional measurement: The accuracy and precision of the reflex microscope. Br J Oral Maxillofac Surg. 1988; 26(4): 276-83. [ Links ]
45. Faul F, Erdfelder E, Lang A, Buchner A. G*Power 3: A flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007; 39(2): 175-91. [ Links ]
46. Hung S, Hung K, Eick J, Chappell, R. Marginal fit of porcelain-fused-to-metal and two types of ceramic crown. J Prosthet Dent. 1990; 63(1): 26-31. [ Links ]
47. Coli P, Karlsso S. Fit of a New Pressure-Sintered Zirconium Dioxide Coping. Int J Prosthodont. 2004; 17(1): 59-64. [ Links ]
48. Martins L, Lorenzoni F, Melo A, Silva L, Oliveira J, Oliveira P et al. Internal fit of two all-ceramic systems and metal-ceramic crowns. J Appl Oral Sci. 2012; 20(2): 235-40. [ Links ]
49. May K, Russell M, Razzoog M, Lang B. Precision of fit: The Procera All Ceram crown. J Prosthet Dent. 1998; 80(4): 394-404. [ Links ]
50. Akin A, Toksavul S, Toman M. Clinical Marginal and Internal Adaptation of Maxillary Anterior Single All-Ceramic Crowns and 2-year Randomized Controlled Clinical Trial. J Prosthodont 2014; 24(5): 345-50. [ Links ]
51. Anadioti E, Aquilino S, Gratton D, Holloway J, Denry I, Thomas G et al. 3D and 2D Marginal Fit of Pressed and CAD/CAM Lithium Disilicate Crowns Made from Digital and Conventional Impressions. J Prosthodont. 2014; 23(8): 610-17. [ Links ]
Correspondence:
CP Owen
Faculty of Health Sciences
7 York Road, Parktown, 2193,, South Africa
Email: peter.owen@wits.ac.za
Author contributions:
1 . George P Babiolakis: Conceptualization, methodology, validation, investigation, writing - review and editing - 50%
2 . C Peter Owen: Conceptualization, methodology, validation, formal analysis, resources, writing - original draft, writing - review and editing, supervision, project administration - 50%