Oral Sciences n3


Original Article Braz J Oral Sci.
April/June 2010 - Volume 9, Number 2

Influence of preparation height and luting agent
type on crown retention in molars

Marcelo Marchiori1, Cezar Augusto Garbin2, Lilian Rigo3, Daniel Becker Nunes1,
Genaro Marcial Mamani Gilapa4

1Specialist in Dental Prosthesis, Postgraduate Program, Dental school, Uningá, Brazil
2PhD, Dental School, University of Pernambuco; Coordinator of the Postgraduate Program, Dental School, Uningá, Brazil

3PhD, Dental School, University of Pernambuco; Professor of Scientific Methodology, Postgraduate Program, Dental school, Uningá, Brazil
4PhD, Professor, Electromechanical Production Engineering Course, Federal Technological University of Paraná, Brazil

Correspondence to:
Lilian Rigo

Av. Major João Schell, 1121
Vila Santa Terezinha

Passo Fundo, RS – CEP 99020-020
Phone: +55 (54) 33131081

E-mail: lilianrigo@via-rs.net

Received for publication: October 27, 2009
Accepted: June 16, 2010

Abstract
Aim: Mechanical characteristics of the preparation along with luting agent are significant elements
on the maintenance of fixed prostheses. This study aimed at assessing the retention of metal
complete crowns luted with two different luting agents under different preparation height. Methods:
Forty human third molars were selected and prepared to receive total crowns, and were randomly
divided in 4 groups: (1) 5-mm preparation height (PH) and RelyX U100 self-adhesive resin
cement (SA); (2) 5-mm PH and zinc phosphate (ZP); (3) 3-mm PH and SA; and (4) 3-mm PH and
ZP. Crowns were cast in nickel-chromium alloy. The tensile strength was tested in a universal
testing machine. Results: Mean tensile strength values to crown displacement (kgf) and standard
deviation were 39.6 (13.0) for group 1; 16.9 (8.1) for group 2; 32.2 (7.9) for group 3; and 10.6
(3.2) for group 4. Overall, the crowns cemented with SA presented significantly higher mean
tensile strength values than ZP, and the 5-mm PH presented significantly higher mean tensile
strength values than 3-mm PH. Conclusions: The self-adhesive resin cement and higher
preparation height improved crown retention.

Keywords: crown retention, luting agents, preparation design.

Introduction

The stabilizing properties of abutments used in cemented complete coverage
restorations have been ascribed to retention and resistance form1-3. Geometric
configuration of the prepared tooth is essential to promote retention between axial
walls of preparation and the prosthetic restoration4. The retention shape obtained
by tooth preparation must avoid dislocation of the restoration along its insertion
axis, acting against tensile forces5. Reduction of convergence angle, higher axial
surface and minimal occlusal reduction contribute to increase the retentive
capability of the prepared tooth6-8.

Several types of luting agents are available and the choice for a material
depends of various factors. The retention of most luting agents is based on
mechanical imbrications in the irregularities of tooth-restoration interface9-10. Zinc
phosphate cement is still the most used for crown luting due to its low cost, easy
of handling and good mechanical properties11-13. However, it has some negative
properties namely solubility in oral environment and absence of adhesive bonding14.

The resin cements has significant role in increasing crown retention by
promoting an adhesive bonding between tooth and restoration, which has increased
the use of these luting agents15.  Nevertheless, the use of these materials requires

Braz J Oral Sci. 9(2):89-93



several steps, mainly for treatment of dental substrate, which
make them technically sensitive16. Self-adhesive resin cements
have been recently introduced on the market. The goal of
these luting agents is to combine the easiness of use offered
by zinc phosphate cements (they do not demand pretreatment
steps) with the favorable mechanical properties, esthetics and
adequate adhesion to dental structure of conventional resin
cements17,18.

The aim of this study was evaluate the influence of
preparation height (3- or 5-mm) and type of luting agent
(zinc phosphate or self-adhesive resin cement) on the retention
of metal complete crowns on molars.

Material and methods

The study was approved by the Research Ethics
Committee of Uningá (Protocol 0089/08). Forty sound human
third molars with similar shapes and dimensions, which had
been freshly extracted due to orthodontic or periodontal
reasons, were used in this study. The selected teeth were
scaled, cleaned for debris and stored in saline, which was
constantly renewed.

Specimen preparation

The roots were centrally inserted into PVC cylinders
(25-mm height x 20-mm internal diameter; Tigre, Joinville,
SC, Brazil) containing self-curing acrylic resin (Jet; Clássico
Artigos Odontológicos Ltda., São Paulo, SP, Brazil). The
acrylic resin was maintained 2 mm below to the cementoenamel
junction12,19. One horizontal perforation was made in the root
equidistant from the cementoenamel junction and tooth apex,
enabling the passing of a rectangular orthodontic wire (Dental
Morelli Ltda., Sorocaba, SP, Brazil) to endure that teeth were
not removed from the acrylic resin during the tensile test.

Preparation was standardized by using a mechanical
lathe, according to previous studies20-21. Tooth reduction was
initiated by positioning the cutting instrument at the
cementoenamel junction and then moving it along the axial
wall in a cervical-occlusal direction, under constant cooling.
Following axial reduction, the external portion of the root
was reduced to standardize the cervical area (Figure 1).
Tapered-shaped preparations had the following characteristics:
6.5-mm upper diameter, 16 degree of convergence and the
cervical finish line was in straight-shoulder shape. Finishing
was made at 45 degree angle on the edge formed by the
axial and occlusal walls, where an approximately 1-mm-wide
groove was made all around the preparation using a
cylindrical diamond bur (#1090; KG Sorensen, Barueri, SP,
Brazil) in a handpiece under water cooling.. The diamond
bur was used in almost the whole area of preparation,
simulating the clinical condition.

The teeth were randomly divided into four groups (n =
10), according to the preparation height and luting agent:
Group 1 – tooth prepared with 5 mm of height and crowns
fixed using self-adhesive resin cement (RelyX™ U100, lot
#318258; 3M ESPE, Seefeld, Germany), according
manufacturer’s directions; Group 2 – tooth prepared with 5

Fig. 1 - Preparation on mechanical lathe.

mm of height and crowns fixed using zinc phosphate cement
(lot #06809007 powder and lot #0040807 liquid, SS White,
São Paulo, SP, Brazil), according manufacturer’s directions;
Group 3  – tooth prepared with 3 mm of height and crowns
fixed using self-adhesive resin cement as group 1; and Group
4 – tooth prepared with 3 mm of height and crowns fixed
using zinc phosphate cement as group 2.

The preparation heights are presented in Figure 2.
Standardization of height was done using a cylindrical
diamond bur (#1090; KG Sorensen) in a handpiece under
water cooling. The last cut was made in a groove shape, with
0.5 mm depth in the proximal walls along the tooth long axis
to guide the insertion pathway of the cast crown. Areas of
pulp chamber exposure were closed with a light-cured resin
(Z350; 3M ESPE, St. Paul, MN, USA). Specimens were stored
in constantly renewed saline until the luting procedure.

Crown cast

Crowns were waxed directly on the prepared teeth6. A
handle was done on each crown for future joining to the
testing machine, using wax wires (Bego, Bremer, Germany)
with 1.5 mm of diameter. The wax crowns were invested
with proportion of 100 g for 22.5 ml of liquid (Begosol;
Bego) and 2.5 mL of water, according to the manufacturer’s
directions. The crowns were cast in a NiCr alloy (Wironia;

90

Braz J Oral Sci. 9(2):89-93

Influence of preparation height and luting agent type on crown retention in molars

Fig. 2 – Preparation heights: 3 mm (left) and 5 mm (right).



Bego). After divesting, fit was checked, the internal surfaces
of the cast crowns were airborne-particle abraded with 110-
ìm aluminum oxide (Korox 110; Bego) under 2 bar of pressure,
and cast crowns prepared for luting as presented in Figure 3.

Crown luting

The preparation was cleaned using rotary brush and pumice
in low-speed hand piece, washed and then dried using sterile
cotton10,22. Metallic crown were sandblasted (Microjet; Bio Art
Equipamentos Odontologicos Ltda, Sao Carlos, SP, Brazil) with
a 50-µm particle stream, cleaned with alcohol and water, and
dried with an air stream free of water or oil. Luting procedure
was performed according to each manufacturer’s instructions.

The crowns were finger pressed after insertion on the
preparation, and were then subjecte dto constant axial pressure
of 5 kg for 10 min using a custom-made press  that allowed
cement flow and correct crown fit on the preparation12,19,23

(Figure 4). Excess material was removed with a sharp explorer.

Fig. 3 - Cast crowns prepared for luting.

Fig. 4 - Standardization of luting load.

Excesses of RelyX U100 were first light-cured using LED
curing unit (Radii Cal; SDI, Australia; 1.200 mW/cm2) for 2 s
to facilitate the removal. The margins of the preparation were
then light-cured for 30 s at each face. Specimens were stored
in distilled water at room temperature for 10 days before of
the tensile strength test.

Tensile Strength Test

Crown retention was measured by applying a tensile
force to the loop attached to the cast crown in a universal
testing machine (EMIC DL 20000, São José dos Pinhais, PR,
Brazil) at a cross-head speed of 0.5 mm/min13,24. Each
specimen was positioned on the lower part of the machine.
The upper part of the testing machine had a 2.5-mm diameter
S-shaped steel hook to which the handles of crowns were
connected (Figure 5). Tensile force values required to separate
the crowns (kgf) was recorded by machine’s software.
Lavenes’s test was applied to verify the homogeneity of
variances, as well as the Kolmogorov-Smirnov’s test to verify
data distribution. As normal distribution was observed,
statistical analysis was performed by two-way ANOVA and
Tukey’s post-hoc test at 5% significance level. Visual
examination of the debonded surfaces of the teeth and crowns
was performed.

Fig. 5 – Specimen positioned in the testing machine.

Results

The results are presented in the Table 1. Both factors,
height preparation and luting cement had significant
influence on crown retention. Crowns cemented with RelyX
U100 (groups 1 and 3) presented significantly higher mean
tensile strength values (p<0.0001) than crowns cemented
with zinc phosphate cement (groups 2 and 4). The 5-mm
preparation height promoted significantly higher mean tensile
strength values than 3-mm preparation height (p=0.018).
There was no significant interaction between the factors
(p=0.847).

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Influence of preparation height and luting agent type on crown retention in molars

Luting agent           Preparation height
5 mm 3 mm

Self-adhesive resin cement 39.6 (13.0) Aa 32.2 (7.9) Ba

Zinc phosphate cement 16.9 (8.1) Ab 10.6 (3.2) Bb

Table 1. Means (standard deviations) tensile strength values
(kgf) for the different experimental conditions.

Means followed by different uppercase letters in the same line and different lowercase
letters in the same column are significantly different (p<0.05).



Debonded adhesive failure types were predominantly
found. For groups 1 and 3, the failures were adhesive between
cement and preparation on the axial surfaces; and between
cement and crown on the occlusal surface. For groups 2 and
4, on the other hand, the failures were adhesive between
cement and crown on the axial surfaces; and between cement
and preparation on the occlusal surface.

Discussion

Retention is considered an important requirement in the
fixation of prosthetic crowns, and its achievement is
dependent on some factors, namely favorable relation
between surface geometry of the prepared tooth and the
definitive restoration4,9,25-28. Clinically, a crown would hardly
undergo such great tensile efforts as those applied in this
study, but the tested experimental conditions serve as
parameters to evaluate different properties and behaviors of
the materials used. According to the obtained results,
minimum occlusal reduction during preparation contributes
significantly to increase the retention6-8, regardless of the
type of luting agent used.

The results of the present study may be explained by
the fact that higher preparation height promotes greater
superficial area with the crown5,26,28-29. Although other factors
may influence on crown retention, the preparations were
standardized (cervical diameter, taper, roughness, piece fit),
thus eliminating or minimizing the interference of these
variables on the results. Rubo et al. 5 concluded that
preparation 2 mm higher contributes significantly for a better
retention of crowns. Other studies have shown greater crown
retention for preparation with greater height24,29-32.

Concerning of the luting agents, the results showed
greater retention (Table 1) for the RelyX™ U100 self-
adhesive resin cement when compared to the zinc phosphate
cement, probably due to the adhesive capacity of the resin
cement to dentin by hybrid layer formation, improving the
retention compared to conventional cements13,17-18. Moreover,
better mechanical properties of resin cement in relation to
zinc phosphate cement also influence their tensile,
compressive and shearing strengths. The lower tensile strength
of the zinc phosphate cement may be related to its ceramic
composition, which makes this material friable and less
resistant to tensile forces33.

Zinc phosphate cement does not have chemical
adhesion to any dental substrate, acting only as luting agent
by mechanical or frictional retention. Thus the height, taper
and area of the preparation important aspects for its success
as a luting material 32,34. Therefore, in situations where
preparation retention is deficient, for example, a short clinical
crown and accentuated taper of the preparation, the choice
for a luting agent lies on resin cement, leading to a more
favorable clinical prognosis15. However, the difference in
tensile strength between the luting agents found in this study
does not contraindicates use of the zinc phosphate cement
because the retention values obtained were higher that the
forces expected clinically, which is around of 4 kgf23.

Tjan and Li35 compared the retention of cast crowns luted

with adhesive resin cement (Panavia Ex®) and zinc phosphate
cement (Flecks®), concluding that the resin cement Panavia
Ex® provided almost twice the retention values given by zinc
phosphate. Browning et al.12 compared the retentive capacity
of three cements (resin, glass ionomer and zinc phosphate)
on crown preparations that presented adverse conditions for
retention, and found that the resin cement showed
significantly higher retention values than the conventional
cements. The findings of other studies13,36 are in agreement
with ours.

Piwowarczyk et al.16 compared the shear bond strength
of luting agents used in fixed prostheses, stating that the
self-adhesive resin cement RelyX® Unicem did not differ
significantly from other conventional resin cements. However,
it presented significantly higher bond strength than glass
ionomer, zinc phosphate and resin-modified glass ionomer
cements. Martins Pinto31 verified the tensile strength of metal
crowns luted with RelyX™ Unicem, RelyX™ ARC and Hy
bond® (zinc phosphate). The author observed higher retention
for self-adhesive resin cement RelyX™ Unicem than for the
other cements.

Under the tested conditions, it may be concluded that
self-adhesive resin cements should be preferred for luting of
metal crowns and minimum occlusal reduction should be
done on preparation. Further studies using other variables
such as thermal cycling, cyclic loading and long-term storage
should be performed to confirm the results and hypotheses
addressed in the present study.

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