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Influence of framework design on the cervical color of metal ceramic crowns
1. cervical color of metal ceramic crowns
Gianluca Paniz, DDS, MS,a Yongjeong Kim, DDS, DMD, MS,b
Haythem Abualsaud, BDT, MS,c and Hiroshi Hirayama, DDS,
DMD, MSd
School of Dental Medicine, Tufts University, Boston, Mass;
University of Padova, Padova, Italy; College of Dentistry, King
Saud University, Riyadh, Saudi Arabia
Statement of problem. The replication of natural teeth, especially for single tooth restorations in patients with high
esthetic needs, represents a challenge.
Purpose. The purpose of the study was to analyze the color of the cervical portion of single metal ceramic crowns
fabricated with different metal framework designs.
Material and methods. The color, as measured on the CIELAB color scale, of 3 different groups of restorations
(n=10) fabricated with a high noble metal alloy (V-Deltaloy) and feldspathic porcelain (Noritake Super Porcelain) was
analyzed with a colorimeter. Conventional metal ceramic crowns with metal facial margins were compared to metal
ceramic crowns with porcelain facial margins and a horizontal reduction of the metal framework (1.0 mm reduction)
or an additional vertical reduction (1.0 mm reduction). In all specimens, the finish line was positioned at a subgingi-
val or equigingival level. The 6 groups obtained by the combination of the levels of the 2 factors (framework extension
and finish line location) were examined with an ANOVA Fisher’s F-test and a post hoc Tukey’s HSD test ( =.05).
Results. The mean color difference for all the groups was clinically acceptable (∆ <3.7). Conventional metal ceramic
crowns showed higher differences in relation to finish line location (∆ =2.34), while a vertical reduction of the frame-
work was related to lower values (∆ =0.96). Mean Lab* values were reported for all the groups of crowns. Statistically
significant differences were present for L*, a*, and b* values when related to framework extension. Considering each
value in relation to the interaction between framework extension and finish line location factors, significant differ-
ences were present only for L* and a* values.
Conclusions. No significant differences in base shade were present among the investigated crowns. Nevertheless metal
ceramic crowns with vertical cut-back and porcelain facial margins presented more consistent results that tended to
be closer to those of natural teeth. (J Prosthet Dent 2011;106:310-318)
If metal ceramic is selected as the restorative material for a crown in the esthetic zone, a
vertical cut-back of approximately 1 mm is recommended on the facial metal framework/
porcelain facial margin to achieve an adequate esthetic result. If a conventional metal frame-
work design is selected, deep subgingival margins might reduce the color impairment.
Presented as a poster at the Greater New York Academy of Prosthodontics Annual Meeting, December 2006, New York, NY.
a
Adjunct Assistant Professor, Graduate & Postgraduate Prosthodontics, Department of Prosthodontics and Operative Dentistry,
Tufts University; Adjunct Professor, Department of Prosthodontics, University of Padova, Dental School.
b
Associate Professor, Graduate and Postgraduate Prosthodontics, Department of Prosthodontics and Operative Dentistry.
c
Senior Specialist, College of Dentistry, King Saud University.
d
Professor, Division Head of Postgraduate Prosthodontics, Director of Graduate and Postgraduate Prosthodontics, Director of
Advanced Education in Esthetic Dentistry, and Director of Advanced Dental Technology and Research program, Tufts University,
School of Dental Medicine.
The Journal of Prosthetic Dentistry Paniz et al
2. November 2011 311
The replication of natural teeth metal framework reduction of 2 mm timate goal in achieving an accurate
with single tooth restorations in pa- coronally from the buccocervical line color match is to achieve the smallest
tients with high esthetic needs and angle. With this design, metal was not possible ∆E value.34 The correlation
expectations represents a challenging visible at the external crown surface, between ∆E and clinical observation
task in restorative dentistry.1-4 An im- light transmission was increased, and was analyzed in an in vivo study of
portant consideration is color repro- the opaquing effect of metal and subjects treated with composite resin
duction in the cervical portion, where opaque porcelain was eliminated in veneers. Within the limitation of the
a thinner layer of restorative material the cervical region. Recent studies study, 3.7 was the average color dif-
must be used to prevent harm to the have confirmed that the metal frame- ference among teeth rated as a match
pulpal tissue or interference with the work should be cut back a minimum in the oral environment.44 When ana-
proper emergence profile.5-7 of 2 mm away from the shoulder to lyzing metal ceramic crowns, different
Different materials and techniques avoid a color mismatch.33 However, results were obtained. Thresholds for
have been proposed to achieve an others show similar esthetic results acceptability were reduced to ∆E=1.7,
improved esthetic result. The metal with less reduction of the metal while perceptibility was reduced to
ceramic crown is one of the most framework, which also provides im- ∆E=0.4. In addition, observers were
popular restorations since it com- proved porcelain support.27 more sensitive to and critical of
bines good esthetics with adequate One of the objective methods crowns whose color differed in red-
strength, accurate fit, and long-term for evaluating color in dentistry is ness (∆a*) than crowns whose color
survival.8 Esthetic problems with this through colorimetric or spectropho- differed to the same extent in yellow-
type of restoration are related to the tometric analysis.34-40 These instru- ness (∆b*).45 More recently, different
opaque porcelain layer used to mask ments use the CIELAB color scale, thresholds for perceptibility (∆E<2.6)
the dark color of the underlying met- which identifies tooth color through and acceptability (∆E<5.5) of shade
al framework. Acting as a barrier to the black/white (L* value), green/red mismatch have been described in a
light transmission, this opaque layer (a* value) and yellow/blue dimen- clinical setting and used in experimen-
causes an impairment of color and sions (b* value).41 In an analysis of tal research.46,47
translucency, which is more evident the color of natural, maxillary central The purpose of this study was to
in the cervical portion, where the por- incisor teeth, Hasegawa et al42 found compare, through spectrophotomet-
celain is thinner.2, 9-11 Furthermore, the significant variations in Lab* values ric digital technology, the color of
presence of a facial, marginal metal along the axis of the surface of the the cervical portion of single metal
collar thick enough to support the teeth: L* was higher in the center; a* ceramic crowns fabricated with dif-
overlying layers of porcelain and resist was higher in the cervical region and ferent metal framework designs. Con-
metal deformation during porcelain significantly lower when approaching ventional metal ceramic crowns with
firing12,13 often becomes an esthetic the incisal edge; and b* was higher in metal margins (metal extended to the
issue.14 To fulfill the esthetic require- the cervical area but with gradual and finish line) were compared with col-
ments, collarless metal ceramic resto- significant reduction toward the in- larless metal ceramic crowns fabri-
rations have been suggested, limiting cisal area. Older subjects had darker cated with different metal extensions.
the extension of the metal framework and more yellowish color at the cen- Subgingival and equigingival margin
to a certain distance from the margin ter of the natural tooth. Both reddish positions were evaluated. The null hy-
of the preparation. Several techniques and yellowish colors of natural teeth pothesis was that there would be no
have been proposed to fabricate col- tended to increase from the incisal to color differences present in the cer-
larless metal ceramic restorations, in- the cervical area, whereas translucen- vical portion of single metal ceramic
cluding platinum foil techniques,14,15 cy decreased. In an in vitro study, the crowns fabricated with different met-
the direct-lift technique,16 and the distribution of color was identified for al framework design and tested with
wax technique.17-20 Research has con- 3 regions with respective mean Lab* equigingival and subgingival margin
firmed adequate marginal adapta- values of 71.4, 0.9, and 12.8 for the placement.
tion21-24 and fracture resistance25-31 for incisal portion, 72.4, 1.2, and 16.2
this type of restoration. In particular, for the middle portion, and 72.6, 1.5, MATERIAL AND METHODS
to achieve adequate strength, a deep and 18.4 for the gingival portion.43
chamfer preparation and no more The most commonly used method The color of 3 different margin
than 1 mm of unsupported ceramic for evaluating color differences among design groups of restorations (n=10)
are recommended.27 specimens is through ∆L*, ∆a*, and fabricated with high noble metal alloy
Analyzing the esthetic effect of ∆b*. Their combination is described (V-Deltaloy; Metalor Dental AG, Biel-
metal ceramic restorations through as color difference (∆E), which is de- Bienne, Switzerland) and feldspathic
transillumination and photography, termined by the following equation: porcelain, (Noritake Super Porcelain;
Geller and Kwiatkowski32 proposed a ∆E = (∆L*2+ ∆a*2+∆b*2)1/2.34 The ul- Noritake Dental Supply Co, Nagoya,
Paniz et al
3. 312
Japan) was measured with a color-
imeter (ShadeVision System; X-Rite,
Inc, Grand Rapids, Mich). The sam-
ple size was arbitrary as no a priori
power analysis was performed, and
no reliable estimate of within-group
standard deviation for the population
could be obtained. The conventional
metal ceramic crowns with metal
margins (group C) were compared
with metal ceramic crowns with 2
different designs of porcelain facial
margin. One group had a horizontal
reduction of the metal framework 1 Different designs of metal framework tested. Conventional metal
(group H: 1.0 mm reduction), and ceramic crowns (Cmc), metal ceramic crowns with horizontal re-
the second had an additional vertical duction of metal framework (Hmc), and metal ceramic crowns with
reduction (group V: 1.0 mm vertical additional vertical reduction of metal framework (Vmc).
reduction) (Fig. 1).
One extracted, intact, human Type and thickness of materials used for crowns
maxillary central incisor was prepared
to receive the crowns. The facial re- Materials Cervical
duction was 1.5 mm following the Crown Layers (Manufacturer) Thickness
depth of a rounded shoulder finishing
line. The margin was positioned at the Metal framework High noble metal alloy 0.3 mm
(V-Delta Alloy, Metalor)
level of the cement-enamel junction
and 2.0 mm of incisal reduction was
Opaque layer Porcelain opaque 0.1 mm
performed. Throughout the study, the (POA1, Noritake Porcelain)
tooth was stored in a 0.05 % thymol
and distilled water solution. The pre- Dentin porcelain Feldspathic porcelain 1.0 mm
pared tooth was duplicated with a (A1B, Noritake Porcelain)
vinyl polysiloxane impression mate-
rial (CapSil, Aquatrols Corporation of Enamel porcelain Feldspathic porcelain 0.1 mm
America, Paulsboro, NJ). Type IV den- (A1B, Noritake Porcelain)
tal stone (New Fuji-Rock, GC Corp,
Porcelain for Feldspathic porcelain Minimal
Tokyo, Japan) was used to fabricate
butt margin (MA1, Noritake Porcelain) achievable
the 30 dies, each corresponding to a
single crown. Cement medium Translucent cement Thin layer
A standardized framework was (Variolink II, trial-base,
cast for each die in a high noble metal Ivoclar Vivadent AG)
alloy (V-Delta; Metalor Dental AG).
After the heat treatment process, lingual side of the crown. For group applications of margin porcelain were
the intaglio surfaces were finished to V crowns, an additional 1.0 mm was applied to achieve adequate marginal
a uniform facial and interproximal added to the vertical reduction of the integrity. The thickness of the margin
thickness of 0.3 mm. For the conven- metal framework. porcelain was reduced as much as
tional margin design, group C, the Dental porcelain (Noritake Super possible. Two layers of dentin porce-
metal framework remained extended Porcelain; Noritake Dental Supply lain were applied to all 3 groups to
to the preparation finish line (Fig. Co) was applied to all groups with achieve proper contour and reduced
1). For group H crowns, the cervi- a brush-on technique according to to a cervical thickness of 1.4 mm.
cal margin of the metal framework the manufacturer’s recommenda- Enamel porcelain was then applied
was reduced at the axiocervical line tions and fired under vacuum in a over the dentin porcelain to achieve a
angle at a distance of 1.5 mm from porcelain furnace (Programat P300; proper final crown contour with a 1.5
the preparation finishing line; this re- Ivoclar Vivadent AG, Schaan, Liech- mm thickness at the cervical area. All
duction was made on the facial and tenstein). Three layers of opaque por- specimens were autoglazed according
interproximal margin, leaving 150 de- celain were applied to all of the metal to the manufacturer’s recommenda-
grees of metal collar exposure on the frameworks. For groups V and H, 2 tions. A caliper (Iwanson Decimal
The Journal of Prosthetic Dentistry Paniz et al
4. November 2011 313
conditions for each of the experimen-
tal margins. Six experimental groups
were evaluated in the study.
On the computer screen, the cervi-
cal portion of the teeth was selected
by using a transparent custom-made
plastic template, which was fabricat-
ed to fit the computer screen to better
identify the different tooth portions. A
4 mm length was considered enough
to represent the cervical portion since
2 Selected cervical portion in equigingival (left) and subgingival the initial length of the tooth before
(right) groups of metal ceramic crowns. Note that subgingival preparation was approximately 12
crowns have margin positioned 0.5 mm apical to gingival level. mm, and a standardized area, extend-
ing 2 mm from the gingival level, was
Groups analyzed. Variables included framework extension (3 selected in the cervical portion (Fig.
groups of specimens) and finish line location (total 6 study groups) 2). The measurements were recorded
in CIELAB coordinates.
Groups of Framework
The color difference among the
Specimens Extension Study Finish Line
experimental groups was determined
(n=30) (C, H, V) Groups Location (S, E)
with the equation: ∆E= [(∆L*)2 +
Cmc Finish line CST
(∆a*)2 + (∆b*)2]1/2,33,34 calculated
from the mean values of L*, a*, and
Hmc 1.5 mm horizontal reduction, HST b*. To determine clinical significance,
Subgingival the ∆E values were related to those
(buccocervical line angle)
(0.5mm) present in the literature, which range
Vmc 1 mm additional vertical VST
from 1.7 to 3.7. 44,45
A 2-way ANOVA was calculated
reduction
for each CIELAB coordinate (L*, a*,
and b* values) to show which of the 2
Cmc Finish line CET
factors (framework extension or finish
Hmc 1.5 mm horizontal reduction, HET
line location) had a significant impact
Equigingival on the values of each coordinate. A
(buccocervical line angle)
post hoc Tukey’s Honestly Significant
Difference (HSD) test was performed
Vmc 1 mm additional vertical VET
to determine statistically significant
reduction
differences among the group means.
Caliper; Asa Dental s.p.a., Lucca, cally (Fig. 2). To achieve repeatability RESULTS
Italy) with an accuracy of 0.05 mm of measurements, the position of the
was used to measure and adjust the tooth and of the measuring instru- The mean L*, a*, and b* values
final thicknesses, which are reported ment was standardized for all the are presented in Table III. When con-
in Table I. measurements with custom-position- sidering L* values through the analy-
The color of the cervical region of ing indices. Each measurement was sis of variance (2-way ANOVA), there
the crowns, fitted on a prepared max- performed 5 times to reduce mea- were significant differences (P=.012)
illary central incisor, was measured surement error. Since natural teeth among the different groups of crowns,
with a colorimeter (ShadeVision Sys- are usually observed in a wet environ- with framework extension having the
tem; X-Rite, Inc). The measurements ment, all measurements were made main effect (Table IV). The mean L*
were made in a dental mannequin with the specimens in a slightly moist value for the Vmc group (78.8) was
(KaVo Dental, Biberach/Riss, Germa- condition. All the crowns were mea- significantly lower (P=.027) than
ny) with the margin of the restoration sured with the application of trans- the mean value for the Cmc group
positioned either 0.5 mm subgingi- parent cement medium try-in paste (79.4) and also significantly lower
vally (subgroup S) or at the gingival (Variolink II; Ivoclar Vivadent AG). Ta- (P=.023) than the value for the Hmc
level (subgroup E) by moving the pre- bles I and II summarize the porcelain group (79.4) (Fig. 3). Considering L*
pared tooth 0.5 mm more or less api- layer thicknesses and measurement values in relation to framework ex-
Paniz et al
5. 314
Mean L* values, a* values, and b* values for each single group of crowns (n=6)
L* a* b*
Mean Mean Mean
Group Values SD Values SD Values SD
CST 78.48 0.93 3.77 0.34 12.26 0.65
HST 79.96 0.81 3.06 0.47 11.87 1.00
VST 78.89 0.55 3.64 0.07 13.33 0.60
CET 80.37 0.84 2.53 0.27 11.65 0.58
HET 78.92 0.68 2.31 0.23 11.78 1.15
VET 78.71 0.57 2.69 0.25 13.30 0.82
Two-way ANOVA table for L* value (main effects and interaction term)
Sum of Mean
Source Squares df Square F P
Framework extension 5.39 2 2.69 4.81 .12
Finish line location 0.74 1 0.74 1.33 .25
Framework extension × 22.5 2 11.25 20.07 <.001
Finish line location
Error 30.3 54 0.56
Framework Extension; LS Means Framework Extension* Finishing Line; LS Means
Current effect: (F2, 54) = 4.82, P=.012 Current effect: (F2, 54) = 20.0, P<.001
80.0 81.5
79.8 81.0 Sub-gingival
79.6 Equi-gingival
80.5
79.4
80.0
79.2
L*
L*
79.5
79.0
79.0
78.8
78.6 78.5
78.4 78.0
78.2 77.5
Cmc Hmc Vmc Cmc Hmc Vmc
Framework Extension Framework Extension
3 L* values in relation to framework extension factor. 4 L* values in relation to framework extension and fin-
ishing line location factors.
The Journal of Prosthetic Dentistry Paniz et al
6. November 2011
tension and finish line location fac- with framework extension having the measured subgingivally and 2.7 when
tors, significant differences (P<.001) main effect (Table V). Hmc crowns measured equigingivally (Fig. 6).
were present (Table IV). The post showed lower a* values (2.69) than When considering b* values, there
hoc Tukey test revealed no significant Cmc crowns (3.17) and Vmc crowns were significant differences (P<.001)
differences (P=.95) between subgin- (3.17) (Fig. 5). Considering a* values among the different groups of crowns,
gival (78.9) and equigingival (78.7) in relation to framework extension with framework extension having the
measurements within the Vmc group. and finish line location factors, signif- main effect (Table VI). Vmc crowns
However, significant differences were icant differences (P=.043) were pres- show higher values (13.3) than Cmc
present within the Cmc (P<.001) and ent (Table V). The post hoc Tukey’s (12, P<.001) and Hmc (11.9, P<.001)
Hmc (P=.035) groups. Conventional test showed that, for all of the groups crowns (Fig. 7). Considering b* val-
metal ceramic crowns had an L* value of crowns, mean values were signifi- ues in relation to framework exten-
of 78.4 when measured subgingivally cantly higher when measured subgin- sion and finish line location factors,
and 80.4 when measured equigingi- givally. Cmc crowns (P<.001) showed no significant differences (P=.488)
vally. Specimens from the Hmc group a value of 3.78 when measured sub- were present (Table VI and Fig. 8).
had a mean L* value of 80 when mea- gingivally and 2.54 when measured The ∆E values among the groups
sured subgingivally and 78.9 when equigingivally. Hmc crowns (P<.001) of crowns are represented in Table
measured equigingivally (Fig. 4). showed a value of 3.06 when mea- VII. Evaluating subgingival groups of
When considering a* values, there sured subgingivally and 2.31 when crowns, the base shade comparison
were significant differences (P<.001) measured equigingivally. Vmc crowns between Cmc crowns (CST) and Vmc
among the different groups of crowns, (P<.001) showed a value of 3.65 when crowns (VST) showed ∆ =1.15. The
Table V. Two-way ANOVA table for a* value (main effects and interaction term)
Sum of Mean
Source Squares df Square F P
Framework extension 3.03 2 1.51 16.85 <.001
Finish line location 14.4 1 14.4 159.4 <.001
Framework extension × 0.60 2 0.30 3.34 .04
Finish line location
Error 4.86 54 0.09
Framework Extension; LS Means Framework Extension* Finishing Line; LS Means
Current effect: (F2, 54) = 16.9 P<.001 Current effect: (F2, 54) = 3.3, P=.043
3.4 4.2
3.3 4.0
3.8
3.2
3.6
3.1
3.4
3.0 3.2 Sub-gingival
b*
2.9
L*
3.0 Equi-gingival
2.8 2.8
2.6
2.7
2.4
2.6
2.2
2.5 2.0
2.4 1.8
Cmc Hmc Vmc Cmc Hmc Vmc
Framework Extension Framework Extension
5 a* values in relation to framework extension factor. 6 a* values in relation to framework extension and fin-
ishing line location factors.
Paniz et al
7. 316
Two-way ANOVA for b* value (main effects and interaction term)
Sum of Mean
Source Squares df Square F P
Framework extension 27.1 2 13.6 19.53 <.001
Finish line location 0.89 1 0.89 1.28 .26
Framework extension × 1.01 2 0.50 0.72 .48
Finish line location
Error 37.5 54 0.69
Framework Extension; LS Means Framework Extension* Finishing Line; LS Means
Current effect: (F2, 54) = 19.5 P<.001 Current effect: (F2, 54) = 0.73, P=.488
14.0 14.5
14.0 Sub-gingival
13.5
13.5 Equi-gingival
13.0
13.0
b*
b*
12.5 12.5
12.0
12.0
11.5
11.5
11.0
11.0 10.5
Cmc Hmc Vmc Cmc Hmc Vmc
Framework Extension Framework Extension
7 b* values in relation to framework extension factor. 8 b* values in relation to framework extension and fin-
ishing line location factors.
∆E values among different groups of crowns
--- CST HST VST CET HET VET
CST --- 1.68 1.15 2.34 1.59 1.51
HST 1.68 --- 1.90 0.70 1.28 1.93
VST 1.15 1.90 --- 2.49 2.04 0.96
CET 2.34 0.70 2.49 --- 1.47 2.34
HET 1.59 1.28 2.04 1.47 --- 1.58
VET 1.51 1.93 0.96 2.34 1.58 ---
The Journal of Prosthetic Dentistry Paniz et al
8. November 2011 317
same comparison performed equig- strated ∆E to be lower than 1.7 (Table crowns (Hmc) showed lower values,
ingivally (CET vs. VET), found higher VII). Evaluating subgingival groups of indicating a color closer to that of
mean values (∆ =2.34). Consider- crowns, excluding the first 0.5 mm natural teeth.43
ing the color of each specific group coronal to the finish line (Fig. 2), the Considering b* values, equigingival
of specimens, Vmc crowns showed base shade comparison between Cmc and subgingival crowns showed simi-
∆ =0.96 when comparing equigin- crowns (CST) and Vmc crowns (VST) lar b* values, except for the analysis of
gival and subgingival groups, Hmc showed clinically acceptable results Cmc crowns, which showed lower val-
crowns showed ∆ =1.28, and Cmc (∆ =1.15). The same comparison ues when equigingival (Figs. 7, 8). In
crowns showed ∆ =2.34 (Table VII). performed equigingivally, including general, vertical cut-back crowns (Vmc)
the most apical 0.5 mm (CET vs VET), showed higher values, indicating a color
DISCUSSION found mean values above the limit closer to that of natural teeth.43
of acceptability (∆ =2.34). This re- The use of a dental mannequin
This study was designed to achieve sult suggests that, when the shade of with a plastic gingival substitute al-
a standardized evaluation of 3 differ- conventional metal ceramic crowns is lowed exclusion of portions of the
ent metal framework designs for the analyzed, there is significant color im- crowns, creating 2 different groups of
color of the cervical area of metal pairment in the most apical 0.5 mm specimens, subgingival (S) and equig-
ceramic restorations. The goal was of the restoration. Furthermore, the ingival (E). However, the plastic gingi-
to understand whether the technical color of the cervical portion of Vmc va did not replicate a clinical situation
challenges of fabricating and man- crowns is most consistent between since it eliminated the impact of the
aging a collarless metal ceramic res- the equigingival and subgingival crown on the soft tissue, whose color
toration19, 21-24, 26-32 were justified to groups (∆ =0.96), while that of the influences the final esthetic outcome.
achieve an improved esthetic result. Hmc crowns is moderate (∆ =1.28), Similarly, this study did not consider
The data support rejecting the null and that of the Cmc crowns is the the possibility of short-term or long-
hypothesis that no color differences worst (∆ =2.34) (Table VII). The pos- term tissue recession. The use of a dif-
would be present in the cervical por- sible positive esthetic implication of ferent gingival substitute could help
tion of single metal ceramic crowns the use of an additional millimeter of overcome these shortcomings in pos-
fabricated with different metal frame- metal framework reduction was not sible future research. Furthermore,
work designs. tested in this study because of the in- considering the development of ce-
In analyzing tooth color, the pri- creased fracture risk present with this ramic restorations, a similar study
mary concern was to obtain clinically type of restoration.25,27,28 design could be used to evaluate core
relevant results, and for this reason, Through the analysis of Lab* val- ceramic restorations.
the data obtained through the colo- ues, a deeper understanding of the
rimetric measurement were related to color differences and of influenc- CONCLUSION
the values reported in the literature. ing factors can be drawn (Figs. 3-8).
A natural tooth was not selected as a Considering L* values, Cmc crowns Within the limitations of this
standard since previously completed showed the highest value when equi- study, the following conclusions were
in vitro research clearly showed signif- gingival (CET), the lowest when sub- drawn:
icant color differences when compar- gingival (CST), and the highest differ- 1. No significant differences in
ing tooth structure to a metal ceramic ence of values between equigingival base shade were present among the
restoration. 33 According to Johnston and subgingival specimens (Figs. 3, investigated crowns.
and Kao,44 a ∆E > 3.7 indicates vi- 4). As discussed in the ∆E analysis, 2. Vertical cut-back crowns (Vmc)
sually perceivable color differences this confirmed that significant color had a cervical shade which was more
which are clinically unacceptable. By impairment occurs in the most apical consistent and appeared to be more
using this threshold and comparing 0.5 mm of the ceramic of metal ce- similar to that of a natural tooth.
the groups with the most clinical rel- ramic crowns. In contrast, when ana- 3. Conventional metal ceramic
evance, no clinical differences were lyzing Vmc crowns, the results were crowns (Cmc) were characterized by
noted (Table VII). A similar compari- more consistent and the color also significant color impairment in the
son can be made to other recent clini- closer to that of natural teeth.43 most apical 0.5 mm of the ceramic.
cal references.47 Even if Johnston and Considering a* values, consis- 4. Vertical cut-back crowns (Vmc)
Kao44 is often cited in the literature, tent differences were present be- tended to have mean L* and b* values
other values were considered for this tween equigingival (E) and subgingival closer to those of natural teeth, while
in vitro study. According to Douglas (S) crowns. In general, equigingival horizontal cut-back crowns (Hmc)
and Brewer,45 the threshold for accept- crowns demonstrated lower values tended to have closer mean a* values.
ability is ∆E=1.7 and for perceptibil- (Figs. 5 and 6). Among the different
ity, 0.4. Several comparisons demon- types of design, horizontal cutback
Paniz et al