UNIVERSIDADE ESTADUAL PAULISTA
“JÚLIO DE MESQUITA FILHO”
Instituto de Ciência e Tecnologia
Campus de São José dos Campos
ORIGINAL ARTICLE DOI: https://doi.org/10.4322/bds.2023.e3680
1
Braz Dent Sci 2023 July/Sept;26 (3): e3838
Effect of novel pre-sintered zirconia surface treatment on shear
bond strength between zirconia and veneering porcelain compared
to conventional surface treatments: an in-vitro study
Efeito de um novo tratamento de superfície de zircônia pré-sinterizada na resistência ao cisalhamento entre zircônia e
porcelana em comparação com os tratamentos de superfície convencionais: estudo in vitro
Ahmed Atef BAIOMY1 , Norhan Naief Abd El HALIEM1 , Hanan Ahmed NAGUIB2 , Amina ZAKI3
1 - Egyptian Russian University, Faculty of Dentistry. Badr City, Egypt.
2 - Cairo University, Faculty of Dentistry. Cairo, Egypt.
3 - Cairo University, Faculty of Dentistry, Fixed Prosthodontics Department. Cairo, Egypt.
How to cite: Baiomy AA, Haliem NNAE, Naguib HA, Zaki A. Effect of novel pre-sintered zirconia surface treatment on shear bond
strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study. Braz Dent Sci.
2023;26(3):e3838. https://doi.org/10.4322/bds.2023.e3680
ABSTRACT
Objective: to evaluate the effect of novel zirconia surface treatment method on shear bond strength between
zirconia and veneering porcelain compared to air abrasion and CoJet surface treatment methods. Material and
Methods: twenty-one zirconia ceramic discs were fabricated with diameter of 7mm and 3mm thickness and
divided according to surface treatment into three subgroups, control group I: Air Abrasion (n=7), group II: CoJet
(n=7) and group III: Z-etch (n=7). Porcelain was built over the zirconia specimens with a customized mold and
red in a ceramic furnace. All specimens were thermocycled (20000 cycles) between 5°C – 55 °C with a dwell
time of 30 seconds in distilled water and shear bond strength of veneering porcelain to each zirconia specimen
was tested using a universal testing machine. Results: numerical data were explored for normality by checking
the distribution of data and using tests of normality (Kolmogorov-Smirnov and Shapiro-Wilk tests). One-way
ANOVA test was used to compare between the groups. There was a statistically signicant difference between
the three groups (P-value = 0.002, Effect size = 0.503). Pair-wise comparisons between groups revealed that
Z-etch showed the statistically signicantly highest mean shear bond strength. Conclusion: zirconia coating
using z-etch is showing promising results in promoting higher bond strength than conventional surface treatment
methods as air abrasion and silica coating.
KEYWORDS
Air-abrasion; Dental materials; Shear bond strength; Surface treatment; Z-etch; Zirconia.
RESUMO
Objetivo: avaliar o efeito do novo método de tratamento de superfície de zircônia na resistência ao cisalhamento
entre a zircônia e a porcelana de cobertura em comparação com os métodos de abrasão a ar e jateamento
com CoJet. Material e Métodos: vinte e um discos de zircônia foram confeccionados com diâmetro de 7mm
e espessura de 3mm e divididos de acordo com o tratamento de superfície em três subgrupos, grupo controle
I: Abrasão a ar (n=7), grupo II: CoJet (n=7) e grupo III: Z-etch (n=7). A porcelana foi aplicada sobre os
espécimes de zircônia com um molde personalizado e sinterizada em forno de cerâmica. Todos os espécimes
foram termociclados (20.000 ciclos) entre 5°C - 55°C com um tempo de permanência de 30 segundos em água
destilada e a resistência ao cisalhamento da porcelana de cobertura foi testada através de uma máquina de ensaio
universal. Resultados: os dados numéricos foram avaliados quanto à normalidade, vericando a distribuição
dos dados e utilizando testes de normalidade (testes de Kolmogorov-Smirnov e Shapiro-Wilk). O teste ANOVA
2
Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
INTRODUCTION
Restoring optimum esthetics and function
in restorative dentistry has always been limited
by lack of advanced materials that can provide
both esthetics and withstand occlusal forces.
This idea has greatly changed in the past few
decades due to advancements in material
science and introduction of recent generations
of dental zirconia [1]. Zirconia has been through
a long journey of material science research and
subsequent advancements to tweak its properties
to meet the goal of esthetics and function. Among
these methods was the addition of stabilizing
oxides as yttria to help make the material in
its strongest form possible at room and mouth
temperature [2]. This resulted in a phenomenon
of transformation toughening, which can only
resist primary cracks but cannot resist any
secondary forces in the same area where the crack
was arrested before [3-5].
On the other hand, bonding to zirconia
was a challenge as well due to lack of silica
content within the material that can provide
chemical bonding to either silica in the veneering
porcelain or to resin cement. To overcome such
problem, many materials and methods have been
introduced to modify the surface of zirconia by
increasing surface area available for bonding [6].
The use of air abrasion in treating the surface
of zirconia has been advocated in literature and
widely used to enhance the bonding to zirconia.
The use of several particles has been studied
and 50 µm aluminum oxide particles are the
most used particles in blasting zirconia surface
to create micro irregularities or roughness to
enhance micro mechanical interlocking with
either resin cement or veneering porcelain [5,7].
CoJet method has also been introduced to
modify the surface of zirconia by addition of silica
particles to the aluminum oxide particles to embed
them in the surface of zirconia and provide a
chemical bond between embedded silica and resin
cement [8-11]. However, due to the nature of the
application of both methods, the blasting action
of aluminum oxide particles adversely affects the
mechanical properties of zirconia. The energy
caused by the collision between aluminum oxide
and zirconia results in phase transformation
from the higher strength tetragonal phase into
less resistant to crack and weaker phase called
monoclinic phase. Many studies have conrmed
the high concentration of monoclinic phase on
the surface of zirconia after air abrasion and
subsequent phase transformation [12-14]. That
created a need for a new surface treatment method
that can be applied safely without any adverse
effects to the zirconia or the operator and can
prevent the creation of monoclinic phase after its
application to avoid weakening the material and
shortening its service time in the oral environment.
In addition, can create good bond strength
between zirconia and veneering porcelain or resin
cement [2].
A novel approach composed of a suspension
(Z-etch, IDS CAD, USA) was introduced to
enhance the surface of zirconia for better bonding.
This suspension is constituted of zirconia nano
particles and carbon particles suspended in
distilled water with specific concentration.
The method of application is by brushing it over
the surface of zirconia before sintering to create
surface roughness. While some authors compared
the effect of z-etch using different concentrations,
others compared it to other less common methods
as hydrofluoric acid or nontreated zirconia
de um fator foi utilizado para comparar os grupos. Houve uma diferença estatisticamente signicativa entre os
três grupos (P-valor = 0,002, tamanho do efeito = 0,503). As comparações pareadas entre os grupos revelaram
que o Z-etch apresentou a resistência de união ao cisalhamento estatisticamente signicativamente mais alta.
Conclusão: o revestimento de zircônia utilizando Z-etch mostrou resultados promissores para o aumento da
resistência de união em comparação aos métodos convencionais de tratamento de superfície, como abrasão a
ar e revestimento de sílica.
PALAVRAS-CHAVE
Abrasão dental por ar; Materiais dentários; Resistência ao cisalhamento; Tratamento de superfície; Z-etch; Zircônia.
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
as control group. No scientific research has
compared this material to other well-established
methods such as CoJet and air abrasion to nd out
its performance in comparison to them [15-18].
The aim of this study was to evaluate the effect
of novel zirconia surface treatment method on shear
bond strength between zirconia and veneering
porcelain compared to air abrasion and CoJet
surface treatment methods. Fractured specimens
were analyzed using stereomicroscope to determine
the mode of bond failure. The null hypothesis tested
was that z-etch surface treatment does not have a
signicant difference from other surface treatment
methods regarding shear bond strength values
between zirconia and veneering porcelain.
MATERIAL AND METHODS
Yttria stabilized zirconium oxide discs
(3Y-TZP) used for core manufacturing of the
discs used as core materials (Bio ZX2, Dental
Direkt GMBH, Germany). Feldspathic porcelain
used as a veneering material over the zirconia
discs to test the shear bond strength between the
two materials after different surface treatment
(Ceramco PFZ, Dentsply Sirona, USA) (Table I).
Air abrasion
Fifty µm aluminum oxide particles were used
to performing the air-abrasion method.
CoJet
CoJet (3M, ESPE) was used to perform
silica coating. CoJet is composed of silica and
aluminum oxide powders. The aim of CoJet sand
blasting was to embed silica particles into the
surface of zirconia and thus modify the surface
to be more chemically bondable.
Z-etch
Z-etch (Z-etch, IDS CAD, USA) was the novel
material used to modify the zirconia surface
before sintering procedure. It is composed of
zirconia and carbon nanoparticles suspension.
The aim of the application of the material was
to increase the zirconia surface area, roughness,
and porosity.
Sample size
Sample size was determined based upon
the results of a pilot study conducted on three
specimens in each group, the effect size (f) for
one-way ANOVA was 0.895. Using alpha (α)
level of (5%), β level of 0.8 (Power = 80%); the
minimum estimated sample size was a total of
18 specimens (6 specimens per group). Sample
size calculation was performed using G*Power
version 3.1.9.2
Twenty-one zirconia discs were designed in
CAD software with dimensions of 7mm diameter
and 3mm thickness and then subdivided into
3 subgroups according to surface treatment,
control group I: Air Abrasion (n=7), group II:
CoJet (n=7) and group III: Z-etch (n=7).
Twenty-one porcelain discs were molded
and fired over the zirconia discs to reach
nal dimensions of 5mm diameter and 3mm
thickness.
Table I - Showing materials used in this study
Material Manufacturer Chemical Composition %
Bio ZX2
Zirconium
Dental Direkt
GmbH, Germany
Zirconium oxide 70-100%
Aluminum oxide 0-1%
Yttrium oxide 3-15%
Hafnium oxide 1-5%
Ceramco
PFZ
Dentsply Sirona,
USA
Sodium Potassium Aluminosilicate SiO2, Al2O3, Na2O, K2O, SnO2, CeO2,
Pigments, 1.3-Butanediol Xi Not mentioned
Z-etch Dmax
Zirconium Dioxide ≤15%
Water ≥85%
Carbon not mentioned
CoJet 3M ESPE
Aluminum Oxide > 95%
Synthetic Amorphous Silica, Fumed, < 5%
Crystalline free
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
Sample preparation
Dental direct zirconia-based disc
(DDBioZX2) was selected with a diameter of
98.5mm and thickness of 16mm and scaling
factor of 1.237 which was predetermined by the
manufacturer to compensate for the shrinkage of
the zirconia after the sintering process.
Zirconia discs were designed using CAD
software (Fusion 360 2.0.15293 x86_64) with
the desired dimensions (7mm diameter and
3mm thickness). After completion of the design,
the digital .stl files were loaded in the CAM
software of the milling machine (Dental CAM 7,
Vhf GMBH, Germany). The milling process and
machine milling strategy were fully automated
processes without any interference in a dry
mode as required by the manufacturer and
the machine milling strategy with the required
zirconia milling burs (Vhf S1, VHF GMBH,
Germany).
After completion of the milling procedure,
zirconia discs were separated from the discs
using a diamond coated bur. In addition,
600,800,1000,1200,2000 grit sandpaper were
used to standardize the surface of the samples.
Each sample was moved in 4 directions (right,
left, up, down) by the same operator 10 times
in each direction per sandpaper so that all
specimens were subjected to the same pressure
at the same time from the operator.
After sanding the discs, they were submerged
in a closed bottle containing distilled water and
placed in an ultrasonic cleaner to clean the surface
of the samples from all residues from the sanding
and surface nishing process. The samples were
left for 10 minutes in the ultrasonic cleaner. After
ultrasonic cleaning, steam cleaner was used to
clean the surface then air dried in an electric oven
for 20 minutes at 200 °C.
After cleaning, an online research
randomization software (randomizer.org) was
used to allocate each sample to its designated
testing group randomly.
Z-etch application
According to recommendations of the
manufacturer and due to the nature of application,
z-etch was applied before sintering process to its
subgroup. The z-etch bottle was shaken well and
dispensed in a small porcelain palette. A brush
was used to paint it over the surface of the
specimen in one coat according to manufacturer’s
instructions. It is important to note that number
of layers or coats of application can affect the
resultant shear bond strength [16].
Sintering process
The discs were placed over zirconia beads in
a plate inside the sintering furnace (Roko Tytan Zr
II, Poland) and sintering parameters were inserted
according to the manufacturer’s sintering schedule.
The time for the sintering cycle was 9.2h (Table II).
Surface treatment and porcelain buildup
Before application of Air abrasion and CoJet
surface treatments 2 devices were designed in
CAD software (Fusion 360 2.0.15293 x86_64)
and 3d printed to ensure the standardization
of tip of the surface treatment device in terms
of distance and angle between the tip and the
specimen. Device A was used with Air abrasion
method and device B was used with CoJet
method to accommodate the different designs of
handpiece used for each method.
Air abrasion
Device A was used to align the tip of the
sandblasting device in a perpendicular direction
Table II - Showing sintering schedule of the zirconia discs as recommended by the manufacturer
Temp.
1 [°C]
Temp.
2 [°C]
Heating rate
[°C/h]
Heating rate
[°C/min]
Dwell time
[min]
Time
[min]
Heating 20 900 480 8 110
Dwell 900 900 30 30
Heating 900 1450 3 3 165
Dwell 1450 1450 120 120
Cooling 1450 200 600 10 125
Total Time: 550
9.2h
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
to the surface of the sample and at 10mm distance
from the surface. The device was used inside the
air abrasion chamber and at an air pressure of
2.8bar and the particles used for air abrasion were
50µm aluminum oxide particles for 10 second
duration per sample (Figure 1a).
CoJet
Device B was used with CoJet powder to
align the tip of the contra angle handpiece at
perpendicular direction to the sample and at
10 mm distance. CoJet sand was added and air
ow of 2.8bar were allowed for 15 seconds per
sample to allow the CoJet particles to blast the
surface of the discs (Figure 1b).
After surface treatment, discs were
ultrasonically cleaned in distilled water to clean
the surface from residues. Steam cleaner was
additionally used to clean the surface of the
specimens followed by air drying using oil free air.
Porcelain mold
A mold was used as a housing to accommodate
the porcelain dough and adapt it to the surface
of the overlying zirconia disc with the required
dimensions of 5mm diameter and 3mm thickness.
The mold was designed using 3d CAD software
(Fusion 360 2.0.15293 x86_64) and 3d Printed
using a desktop LCD 3d Printer (Phrozen Mighty
4K, Phrozen Inc., Taiwan) with the recommended
3d printing parameters for the selected resin
(Phrozen Aqua Grey 4K).
Porcelain discs were made by direct
application over the treated zirconia discs.
A specially designed porcelain mold was made
in fusion 360 CAD design software with internal
dimensions to make a 5mm diameter x 3mm
thickness porcelain discs. However, due to the
shrinkage of the porcelain discs after ring, the
dimensions of the resulting disc was used to
modify the mold dimensions to be able to deliver
the exact dimensions of the porcelain discs after
ring to be 5mm x 3mm (Figure 2).
By measuring the feldspathic disc
dimensions after ring and comparing it to the
planned dimensions, a simple mathematical
equation was used to determine the needed
dimensions of the mold to compensate for the
shrinkage of the porcelain after ring and get
the exact nal dimensions needed after ring
for the discs which were 5mm diameter x 3mm
thickness.
Equation used was as followed:
1- Measured dimension of the porcelain disc
after ring = A
2- Measured dimension of the porcelain disc
before firing = X which is needed to be
planned in the 3d design
3- Measured dimension of the porcelain disc
before ring in the pilot study= B
4- Measured dimension of the porcelain disc
after ring in the pilot study = C
Then
AB
XC
X AC
X
B
= ×
(1)
After application of the porcelain over the
zirconia discs inside the mold the ring program
was adjusted in the ring furnace according to
manufacturer’s ring schedule.
Figure 1 - 3D printed devices to standardize distance and angle for air abrasion and CoJet application (1a) Showing device A used for air
abrasion procedure. (A) Cylinder to hold the air abrasion pen perpendicular to the zirconia specimen. (B) Zirconia disc cavity to hold the zirconia
disc. (C) Base of the device (1b) Showing device B used to standardize the CoJet application. (A) Cylinder to hold the CoJet handpiece. (B)
Cavity to hold the zirconia disc. (C) Base of the device.
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
AGING AND SHEAR BOND STRENGTH
To simulate clinical aging conditions,
all specimens were thermocycled between
5°C – 55 °C for 20000 cycles with a dwell time of
30 seconds in distilled water bath and a transfer
time of 10 seconds after surface treatment in
a thermo-cycling unit (Julabo FT200, Julabo,
Seelbach, Germany).
Shear bond strength was performed using
universal testing machine (Instron universal
testing machine model 3345, England).
Specimens were mounted in lower compartment
and mono beveled chisel with a thickness of
0.5mm was used to perform the shear test in a
direction parallel to the surface of the disc and
at a crosshead speed of 1mm/min.
Measurement of shear bond strength values
were calculated by converting the loads into
MPa by dividing the maximum failure load (N)
by the bonding area (mm2) saved in excel sheet
(Figure 3).
Mode of failure
Mode of failure was analyzed using
stereomicroscope (50X magnification) (MA
100 Nikon, Japan) after performing shear bond
strength.
Surface roughness analysis
After surface treatment, zirconia surface was
inspected at 4,000X magnication using scanning
electron microscopy (SEM). Surface roughness
Figure 2 - Showing the 3D printed device for porcelain application over zirconia discs. (A) Piston used for condensing the porcelain. (B)
Porcelain molding cavity to hold the porcelain slurry. (C) Zirconia disc cavity that contains the zirconia discs. (D) Base for the device to hold
the porcelain mold tightly over the zirconia.
Figure 3 - Graphical representation of shear bond strength test. (A) Porcelain disc. (B) Zirconia Disc. (C) Chisel used to break the sample. (D)
Base of the device made from2 components that close on each other to fix the sample between them.
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
was measured at an area of 100µm width by
60µm height to inspect the surface and evaluate
the microscopic effect of the surface treatment
on the surface of the sample.
Statistical analysis
Numerical data were explored for normality by
checking the distribution of data and using tests of
normality (Kolmogorov-Smirnov and Shapiro-Wilk
tests). Shear bond strength data showed normal
(parametric) distribution. Data were presented as
mean and standard deviation (SD) values. One-way
ANOVA test was used to compare between the three
groups. Bonferroni’s post-hoc test was used for pair-
wise comparisons when ANOVA test is signicant.
The signicance level was set at P ≤ 0.05. Statistical
analysis was performed with IBM SPSS Statistics for
Windows, Version 23.0. Armonk, NY: IBM Corp.
RESULTS
Primary outcome shear bond strength
There was a statistically signicant difference
between the three groups (
P
-value = 0.002,
Effect size = 0.503). Pair-wise comparisons
between groups revealed that Z-etch showed
the statistically signicantly highest mean shear
bond strength.
CoJet showed statistically signicantly lower
mean value. Air abrasion showed the statistically
signicantly lowest mean shear bond strength
(Table III) (Figure 4).
Secondary outcome mode of failure
After analysis of the mode of failure. It was
divided into 3 categories:
a- Adhesive failure: failure occurs at the interface
between the two materials with no remnants
of porcelain over the zirconia surface.
b- Cohesive failure: failure occurs predominantly
within the structure of the same material
whether porcelain or zirconia.
c- Mixed: adhesive failure between 2 materials
at the interface with porcelain remnants over
zirconia
After inspection of the specimens using
the same observer with the above criteria for
categorizing the observed failure, it could be
found that z-etch showed the highest percentage
of mixed failure while air abrasion showed
the highest percentage of adhesive failure
(Figures 5-6).
Scanning electron microscopy
Scanning electron microscope was
used to evaluate the surface of zirconia and
the modification occurred at two different
magnification levels 4000x and 15000x.Air
abrasion and CoJet electron microscope share a
common crater like depressions which conrms
Figure 4 - Bar chart representing mean and standard deviation
values for shear bond strength of the three groups.
Figure 5 - Mode of failure according to each group.
Table III - Descriptive statistics and results of one-way ANOVA test for comparison between shear bond strength (MPa) of the three groups
Air abrasion CoJet Z-etch
P
-value
Effect size
(Eta squared)
Mean SD Mean SD Mean SD
14.63 C1.7 19.91 B5.82 23.61 A3.19 0.002* 0.503
*Significant at P ≤ 0.05.
Different superscripts indicate statistically significant difference between groups.
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
the damage that occurs to the surface of zirconia
due to blasting power of the aluminum oxide
and silica particles which are needed to increase
surface area and roughness of the surface and
increase bond strength mechanically (Figure 7).
On the other hand, Z-etch showed a pattern
of bead like appearance over the surface of
zirconia and with 15000x magnication a cloud
or scaffold appearance of zirconia appears with
no other sign of damage of the surface of the
specimens as it air abrasion and CoJet subgroups
(Figure 7).
Surface roughness analysis
Surface roughness analysis showed that the
highest mean surface roughness Ra was in case
of Z-etch surface treatment (Ra [µm] = 15.97)
followed by CoJet (Ra [µm]=15.12) and air
abrasion (Ra [µm]= 14.7) (Table IV) (Figure 8).
DISCUSSION
The bonding to zirconia has always been a
point of interest in the literature due to its wide
applications in the dental eld whether for xed
restorations or for implant supported prosthesis.
Many methods have been introduced to enhance
the bond to zirconia whether from the intaglio
side or the external porcelain veneering side.
In the present study, yttria stabilized zirconia
(3Y-TZP) was selected as it is the most common
used type for veneering technique by porcelain
to enhance its esthetic properties and outcome.
The compatible porcelain veneering system was
selected based on manufacturer instructions
for the suitable veneering porcelain systems.
Air abrasion as a surface treatment method is
the most popular method used for treating the
surface of zirconia. In addition, it has been widely
used in literature while CoJet silica coating can
provide effective bond strength values because
of surface modication and silica embedding in
the surface of zirconia [6,7,19,20].
The null hypothesis was rejected due to
the results that showed significant difference
between different surface treatment methods.
The Macro shear bond strength test is the
most widely used test in evaluating bond strength
Figure 6 - Mode of failure under stereomicroscope (A) adhesive failure in air abrasion group (B) mixed failure in air abrasion group (C) mixed
failure in CoJet group (D) adhesive failure in CoJet group (E) adhesive failure in z-etch group (F) mixed failure in z etch group.
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Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
between ceramics and other substructures.
The lower incidence of pretest failure is one of
the most important features of the shear bond test
among other tests. The micro shear bond strength
was introduced to analyze the bonding stresses
over a smaller area with a more homogenous stress
pattern compared to macro shear. However, the
use of micro shear and its application was a very
technique sensitive procedure that can lead to
inconsistent results if not performed accurately.
The selection of macro shear bond test was due
to its simplicity and the evaluation of secondary
outcomes as failures modes can be interpreted
easily using this test [21-24].
The dimensions of the samples were estimated
to be 7mm diameter and 3mm thickness for
zirconia and 5mm diameter and 3mm thickness
for porcelain and these dimensions were based
upon the ISO standards (ISO 29022:2013) for
notched edge shear bond strength test.
When surface treatment is performed on
ceramics, variables including air pressure, size of
the blasting particles, type of the particles and the
distance between the nozzle tip and the ceramic
surface are vital factors to consider [1,25-27].
All the specied variables for air abrasion, CoJet
and z-etch were based upon manufacturer.
In addition, throughout literature it was
found that optimal pressure for air abrasion and
CoJet to be around 2-2.8bar and the particle
size of air abrasion to be 50µ .These parameters
are an important aspect for surface treatment of
zirconia as any increase in air pressure or particle
size can lead to higher percentage of tetragonal to
Figure 7 - (A) SEM image of zirconia surface after air abrasion at 15000X magnification (B) SEM image of zirconia surface after air abrasion
at 4000X magnification (C) SEM image of zirconia surface CoJet at 15000X magnification (D) SEM image of zirconia surface CoJet at 4000X
magnification (E) SEM image of zirconia surface after Z-etch at 15000X magnification (F) SEM image of zirconia surface after Z-etch at 4000X
magnification.
Table IV - Showing mean roughness values (Ra) for each surface treatment method
Surface Treatment Air Abrasion CoJet Z-etch
Roughness at 4000x (Ra) 14.7 15.12 15.97
10
Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
monoclinic phase transformation which weakens
the zirconia material and makes it less resistant
to stresses under function [5,6, 28-31].
Cleaning the surface of zirconia using
distilled water is an important step to make sure of
absence of surface contamination. In 2020, Attia
and Ebeid [32] evaluated several decontamination
methods for zirconia and it was concluded that
decontamination method has an impact on shear
bond strength to zirconia [32].
Many experimental coatings other than z-etch
have been tested in the literature to enhance
zirconia bond strength as the use of silica coating
technique and the use of Sol-jel dip technique
for silica coating [33-35]. On the other hand,
graphite using graphite leads was used as well
over the zirconia surface followed by Er: YAG laser
application as an experimental coating to enhance
bond strength which showed higher shear bond
strength in comparison to air abrasion [36].
Z-etch was used in this study to prove
its effectiveness in comparison to previous
methods and to address the drawbacks of
conventional methods as phase transformation
from stabilized tetragonal phase to monoclinic
less resistant to fracture phase due to blasting
action to the surface of zirconia and content of
aluminum oxide. The basic principle of using
z-etch was to implement carbon particles as
a carrier for zirconia nanoparticles to provide
hydrogen bond between zirconia surface and
nano zirconia coating. After sintering procedure,
carbon particles evaporate due to high sintering
temperature leaving a rough network of zirconia
nano particles over the zirconia surface [37].
The application of z-etch suspension could be
considered fast, effective, and economic method
to modify the surface of zirconia without exposing
the zirconia surface to unnecessary stresses and
energy that cause phase transformation and
subsequent weakening of the material. Acquiring
a strong interface between zirconia and veneering
ceramic is a critical issue that has been addressed
by many researchers. As failure of zirconia is
mainly due to lack of proper bond between
veneering ceramic and zirconia. In addition, the
presence of zirconia surface contaminants and
decontamination techniques before porcelain
application is a crucial aspect that should be
taken into consideration as well. Further research
is needed to address this issue as well [32,38].
Z-etch showed the highest mean shear bond
strength compared to air abrasion and CoJet and
this can be attributed to the mechanism of action
Figure 8 - (A) 3D representation of roughness of the surface (B) 3D representation of roughness of the surface (C) 3D representation of
roughness of the surface.
11
Braz Dent Sci 2023 July/Sept;26 (3): e3838
Baiomy AA et al.
Effect of novel pre-sintered zirconia surface treatment on shear bond strength between zirconia and veneering porcelain compared to conventional surface treatments: an in-vitro study
Baiomy AA et al. Effect of novel pre-sintered zirconia surface treatment on
shear bond strength between zirconia and veneering porcelain
compared to conventional surface treatments: an in-vitro study
of the material as it forms a cloud like layer of
zirconia over the surface that can provide a
substrate for undercuts and irregularities to engage
the porcelain. This could be better than depending
solely on roughness made by blasting of aluminum
oxide in case of air abrasion and CoJet.
Bae et al. [18] compared the effect of
zirconia slurry application over zirconia and used
air abrasion with 50 µ and 125 µ particle size as
comparator groups. Although Z-etch improved
the shear bond strength in that study by it was
not higher that air abrasion groups and this can
be attributed to different surface conditioning
method after surface treatment and substrate as
this study used Panavia, superbond and Variolink
to test their bond strength to zirconia not as the
present study which addresses the outer surface
of zirconia that received porcelain layering [18].
Jo et al. [16], studied the effect of zirconia
slurry coating as well in 2020 with different
concentrations and it was found that zirconia
coating enhanced the shear bond strength
significantly with the highest value in 50%
concentration of zirconia slurry, The substrate
bonded to that study was resin cement as well as
no previous study studied the effect of z-etch or
coating zirconia on the bond strength between
zirconia and veneering porcelain [16].
This can be confirmed by inspection of
the scanning electron microscope images
showing a cloud like appearance of z-etch and
by the highest roughness values calculated
for z-etch in comparison to air abrasion and
CoJet. The increase in roughness values were in
accordance with Jo et al. [16], as zirconia coating
increases the roughness parameters of the surface
by deposition of nano zirconia particles result in
a cloud like appearance [16].
On the other hand, CoJet showed sig-
nicantly higher shear bond strength compared
to air abrasion which is in accordance with
Baiomy et al. [39] and can be attributed to the
embedded silica on zirconia surface and their
ability to bond chemically with silica content from
porcelain. The measured mean surface roughness
of the specimens conrmed this nding as z-etch
showed the highest values in mean surface rough-
ness compared to other methods [16]. However,
in study by Bae et al. [18] different concentra-
tions of zirconia slurry were evaluated to test
their effect on shear bond strength and surface
roughness was not measured.
Even though surface roughness increased
with increasing the concentration of zirconia
slurry, it was found that it does not increase the
shear bond strength until a certain concentration is
reached. This could mean that there is a bottleneck
for concentration of the zirconia slurry and after it
shear bond strength can decrease signicantly as
conrmed by Jo et al. [16]. In addition, mode of
failure showed that mixed failure is more prone to
occur in z-etch subgroup which can be related to
increased shear bond strength and mean surface
roughness value in z-etch group.
CONCLUSION
Within the limitations of this study, the
application of z-etch to pre sintered zirconia
surface could be an effective method to obtain
increased bond strength between zirconia
and veneering porcelain in comparison to
conventional zirconia surface treatment methods.
Acknowledgements
All co-authors have seen and agree with the
contents of the article and there is no nancial
interest to report.
Author’s Contributions
AAB: Conceptualization. AAB: Methodology.
AAB: Writing – Original Draft Preparation.
NNAEH, HAN, AZ: Writing – Review & Editing.
HAN, AZ: Visualization. HAN, AZ: Supervision.
AZ: Project Administration.
Conict of Interest
No conicts of interest declared concerning
the publication of this article.
Funding
The authors declare that no nancial support
was received.
Regulatory Statement
Not applicable.
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Ahmed Atef Baiomy
(Corresponding address)
Egyptian Russian University, Faculty of Dentistry
Email: ahmed.baiomy@dentistry.cu.edu.eg Date submitted: 2023 Mar 21
Accept submission: 2023 May 22
