Original research

Dental Materials

Thiago Soares PORTO(a)  

Renato Cassio ROPERTO(a)  

Sorin Theodor TEICH(b)  

Fady Fouad FADDOUL(a)  

Fabio Antonio Piolla RIZZANTE(a)  

Sizenando de Toledo PORTO-NETO(c)  

Edson Alves de CAMPOS(c)

 (a) Case Western Reserve University, 
School of Dental Medicine, Department 
of Comprehensive Care, Cleveland, 
Ohio, USA.

 (b) Medical University of South Carolina, 
College of Dental Medicine, Department 
of Oral Rehabilitation, Charleston, South 
Carolina, USA.

 (c) Universidade do Estado de São Paulo – 
Unesp, Faculty of Dentistry, Department 
of Restorative Dentistry, Araraquara, São 
Paulo, Brazil.

Brittleness index and its relationship 
with materials mechanical properties: 
Influence on the machinability of 
CAD/CAM materials

Abstract:The aim of this study is to evaluate the machinability of 
four CAD/CAM materials (n = 13) assessed by brittleness index, 
Vickers hardness, and fracture toughness and interaction among 
such mechanical properties. The materials selected in this in vitro 
study are Feldspathic ceramic [FC], Lithium-disilicate glass ceramic 
[LD], leucite-reinforced glass ceramic [LR], and nanofilled resin 
material [RN]. Slices were made from the blocks following original 
dimensions 14 x 12 x 3 mm (L x W x H), using a precision slow-speed 
saw device and then surfaces were regularized through a polishing 
device. Brittleness index and fracture toughness were calculated by 
the use of specific equations for each one of the properties. The Vickers 
hardness was calculated automated software in the microhardness 
device. One-way Anova and Pearson’s correlation were applied to 
data evaluation. LD obtained the highest values for brittleness index 
and was not significantly different from FC. LR presented statistically 
significant difference compared with RN, which had the lowest 
mean. Vickers hardness showed LD with the highest average, and no 
statistical difference was found between FC and LR. RN presented the 
lowest average. Fracture toughness showed FC and LR not statistically 
different from each other, likewise LD and RN. The brittleness index, 
considered also as the machinability of a material, showed within this 
study as positively dependent on Vickers hardness, which leads to 
conclusion that hardness of ceramics is related to its milling capacity. 
In addition, fracture toughness of pre-sintered ceramics is compared to 
polymer-based materials.

Keywords: Dental Materials; Polymers; Prosthodontics; Hardness.

Introduction

The ongoing pursuit of excellence in aesthetic and prosthetic 
rehabilitation has resulted in the need to study numerous parameters. 
Among all factors that can influence rehabilitation; material’s mechanical 
properties, restorations marginal fit and the cementing process1,2,3,4,5 
are important keys to achieving success. For a long time gold was the 
preferred material for indirect restorations due to adaptation characteristics, 

Declaration of Interests: The authors 
certify that they have no commercial or 
associative interest that represents a conflict 
of interest in connection with the manuscript.

Corresponding Author:
Dr. Thiago S Porto 
E-mail: txp209@case.edu

https://doi.org/10.1590/1807-3107bor-2019.vol33.0026

Submitted: May 30, 2018 
Accepted for publication: February 16, 2019 
Last revision: February 27, 2019

1Braz. Oral Res. 2019;33:e026

https://orcid.org/0000-0001-7806-8476
https://orcid.org/0000-0003-4542-909X
https://orcid.org/0000-0002-5353-823X
https://orcid.org/0000-0002-0055-3719
https://orcid.org/0000-0002-4123-5637
https://orcid.org/0000-0002-9593-2702
https://orcid.org/0000-0001-9120-4305


Brittleness index and its relationship with materials mechanical properties: Influence on the machinability of CAD/CAM materials

polishing and laboratory handling.6,7 According to 
evidence from the literature, however, after ten years, 
ceramic restorations are very similar to gold in overall 
performance.7 In addition, esthetic requirements are 
easier to achieve with ceramic restorations.7

The accuracy of how well the prosthetic crown 
fits the dental preparation is one of the important 
determinants of rehabilitation success. The computer-
aided-design and computer-aided-manufacturer 
(CAD/CAM) technology has enormous advantage in 
manufacturing precise restorations. This technology 
reduces the distortions caused by standard methods 
and eliminates numerous laboratorial phases that could 
be complicating factors during the manufacturing 
process.8,9,10 Dental ceramics and polymer-based 
materials can be easily fabricated with CAD/CAM 
technology, with desirable properties due to adequate 
environment where it is produced.10,11,12

CAD/CAM technology provides powerful 
restoration and conservative preparation; however, 
for best performance the materials should be chosen 
during the treatment planning.5,11,12,13 The digital 
system allows preparations that are less complex 
and also less invasive; in addition, it provides the 
same strength of other treatment options.14, 15 Studies 
have shown unexpected behavior like the higher 
fatigue resistance of polymer-based materials when 
compared with that of ceramics. The flexural modulus 
of polymer-based materials is very similar to that 
of dentin, which creates a single body in regarding 
mechanical behavior, and consequently polymer-based 
materials can be widely used.11,16,17

Missing is a clear gap between CAD/CAM 
interactions of materials’ machinability and 
their characteristics like marginal fit after such 
mechanical tests as static and dynamic loading. These 
interactions are indispensable to clinical performance 
conclusions.12,18 However, the influence of fatigue and 
discrepancies on marginal integrity are reported for 
all-ceramic and gold restorations, with acceptable 
margins.5, 6,11,17,18

The first mention in literature for brittleness 
index19 combined the results with marginal chipping 
factor (CF), which can be calculated only after the 
crowns have been milled. Ceramics have a higher 
brittleness index when compared with composite 

materials. Although some of the materials reported 
in the literature are no longer available, new materials 
have been developed in recent years.20,21 Furthermore, 
tests that predict the brittleness of a material before 
milling can be more relevant for clinicians.22,23

The chemical composit ion of CAD/CAM 
materials tested in previous in vitro studies19 led 
to the hypothesis that CAD/CAM polymer-based 
blocks may have a better clinical performance than 
ceramics. It is necessary, however, to conduct a deep 
analysis of others aspects of mechanical properties. 
The purpose of our investigation is to satisfy this 
necessity by considering the brittleness index as 
an important aspect of aesthetics materials and its 
possible interactions with other properties.

The different compositions of ceramic materials 
affect their mechanical properties, such as flexural 
strength, fracture toughness, fracture resistance, 
hardness, and, the main property to be investigated 
in this study, brittleness index. The CAD/CAM 
technology brings in new concepts and the necessity 
of new methods to predict the longevity of restorations 
that use machinable materials regarding susceptibility 
to cracks, voids, and flaws. The aim of this study is 
to measure the brittleness index, Vickers hardness, 
and fracture toughness (KIc) of several CAD/CAM 
materials used with the digital system and to assess 
their interactions in order to better understand the 
behavior of the materials. The null hypothesis is that 
there is no correlation between the properties tested.

Methodology

Fifty-two specimens were prepared using a 
CAD/CAM milling unit (CEREC MC XL Sirona, 
Bensheim, Germany). The blocks used after milling 
the crowns were divided into four groups (n=13 
each). The materials selected for the research were 
feldspathic ceramic (FC) as a control group, lithiuim 
disilicate glass ceramic (LD) in its intermediate phase, 
leucite-reinforced glass ceramic (LR), and nanofilled 
resin material (RN). The materials compositions, 
manufacturers, batch number, and flexural strength 
provided by the manufacturer are in Table 1. The 
blocks surface was regularized using a slow-speed 
diamond saw (Isomet 4000, Buehler, Lake Bluff, 

2 Braz. Oral Res. 2019;33:e026



Porto TS, Roperto RC, Teich ST, Faddoul FF, Rizzante FAP, Porto-Neto ST et al.

USA), and all blocks had an approximate 3.0mm 
of ceramic thickness with length and width kept 
as original for each material block (approximately 
14 mm and 12 mm, respectively). Their surface 
having been planned, with a grinding and polishing 
device (Metaserv 2000, Buehler, Lake Bluff, IL, 
USA) equipped with sandpaper cooled by water 
(3M ESPE, St. Paul, USA), the specimens were 
sequentially polished with #180, #250, #360, #400, 
#600, #800, #1200, and #1500. In order to create the 
ideal smooth surface for proper data acquisition 
by the microhardness machine, specimens were 
additionally treated with a sequence of a 1μm and 
0.5μm polish diamond paste (Buehler, Lake Bluff, 
USA) in combination with the #1500 grit sandpaper. 
Specimens were then cleaned by ultrasonic water 
bath (Boekel Analog Model 139400, PA, USA) for 
fifteen minutes and air-dried.

For both tests, each specimen surface was divided 
in four quadrants. On each quadrant, several 49N 
load (P) indents with loading time of fifteen seconds 
were made using a Vickers hardness machine 
(W-402MVD Buehler – Lake Bluff, USA) at room 
temperature; until two acceptable indents per 
quadrant were selected totaling eight measures per 
sample and 104 per material. The following criteria 
was considered to have the two ideal measurements: 
brittleness (a) all cracks emanated from the corners 
of indent; (b) presence of only four radial cracks; 
(c) no crack chipping and; (d) no crack branching; 
Vickers (a) clean and visible indents; (b) no chipping 
around diamond indents.19

The brittleness index was calculated by measuring 
the crack along the vertex of the indentation in the 
same direction as the diagonal one. Because the 
cracking growth is time dependent, readings were 
made after 30 seconds. Using the microhardness 

tester, two-lines markers visible on the lens were 
positioned on both ends of the crack. Measurements 
were made and calculated by equation one:24

Equation (1) – B =γP-2/4(C/α)3/2

On the equation (1) above, B is the brittleness 
index in μm-1/2; P is the indentation loading (N), γ is 
the constant value equal to 2.39N1/4/μm1/2; C is the 
diagonal one and; α is the crack length diagonal 
one in μm. 

Vickers hardness was calculated by measuring 
the diagonal one and two distances and analyzed by 
the micro hardness software on the tester machine.

Twenty new specimens from each one of the 
materials described in Table 1 were fabricated 
measuring 14 mm of length by 3 mm of height and 
2.5 mm of width.  To the specimens a notch with 
a relationship of 1 to 3 was done along the 3 mm 
height. The protocol for specimen’s preparation and 
the notch is described in Porto et al.25 The specimens 
were submitted to a three-point bending test (Test 
Resources, Shakopee, MN, USA) at a cross-head speed 
of 0.5mm/min until fracture. The fracture toughness 
was calculated with the same method described by 
previous publications.25,26,27,28

To identify the loading distribution on the 
specimens with the notch and the influence of such 
loading on the mechanical behavior, two calibrated 
100mm macro lenses F2.8D (Tokina, Tokyo, Japan) were 
positioned on tripods. The cameras were connected 
with the software VIC Snap 8 and VIC 3D (Correlated 
Solutions, USA) to analyze the specimens in real time 
during the loading. The specimens were sputtered 
with a white ink and black ink speckles in order to the 
calibrated macro lenses identify the surface loading 
distribution. During the three-point bending test 
around one hundred and fifty pictures were taken. 
Two pictures were chosen from each material, one 

Table 1. Compositions and flexural strength of CAD/CAM materials used.

Materials Compositions Flexural strength Lot number

Vitablocs Mark II [FC] Feldspathic ceramic 154 MPa 33410

IPS e.max CAD [LD] Lithium disilicate glass-ceramic 130–150 MPa T15004

IPS Empress CAD [LR] Leucite-reinforced glass ceramic 160 MPa T32757

LAVA Ultimate [RN] Nanofilled resin with silica and zirconia fillers 150 MPa N678317

3Braz. Oral Res. 2019;33:e026



Brittleness index and its relationship with materials mechanical properties: Influence on the machinability of CAD/CAM materials

at the initial loading and one just before the failure. 
As proposed by Lawn and Marshall an estimative of 
Brittleness index could be done by the relationship 
between Vickers hardness and KIc (VH/KIc). This 
relationship is presented in the results and compared 
with the KIc data.

Statistical data were calculated by SPSS 22.0 
software. Levene’s test and Shapiro-Wilk test were 
performed to make the assumptions of homogeneity 
variances and data normally distributed. One-way 
ANOVA analysis was performed followed by 
Games-Howell post-hoc comparisons to find 
any statistically significant differences between 
Vickers hardness and brittleness index among 
the four materials. One-way ANOVA and Tukey 
post-hoc test were performed to find statistically 
significant differences among the materials tested 
for fracture toughness and VH/KIc. Finally, the 
Pearson’s correlation was calculated to analyze the 
interaction between both mechanical properties. 
The significance level was set at α = 0.05.

Results

The statistical analysis associated with materials’ 
Vickers hardness and comparing the four different 

types of materials are reported in Table 2. A Levene’s 
test for homogeneity of variances was used (p < 0.05) 
and not satisfied, also Shapiro-Wilk’s test (normality 
distribution) - (p < 0.05) and a visual inspection of 
their histograms, normal Q-Q plots, and box plots 
showed that the Vickers hardness of each ceramic 
is normally distributed.

For the Vickers hardness (VH) test, one-way 
ANOVA was performed and showed statistically 
significant differences among the samples (p < 0.05). 
The Games-Howell post-hoc test showed statistically 
significant difference among ceramic materials by 
multiple comparisons (p < 0.05). LD (6.84 ± 0.16) was 
significantly higher than all other groups, while FC 
(5.97 ± 0.22), was not significantly different from LR 
(5.74 ± 0.20), and RN (1.02 ± 0.06) was significantly 
lower than all other groups.

The brittleness index testing for each ceramic 
group was calculated by using the measurement of 
the loading indentation and cracking along the vertex. 
The descriptive statistics with materials’ brittleness 
index are reported in Table 3. The Levene’s test for 
homogeneity of variances was applied (p < 0.05) 
and not satisfied; also Shapiro-Wilk’s test (normality 
distribution) - (p < 0.05) and a visual inspection of 
their histograms, normal Q-Q plots, and box plots 

Table 2. Means and standard deviation  (±  SD), for first column Vickers hardness (VH - GPa); second column Brittleness index 
(BI - μm-1/2); third column fracture toughness KIc (MPa m1/2); and fourth column Vickers hardness (VH – Gpa)/fracture toughness 
KIc, across the materials type.

Variable VH (GPa) BI (μm-1/2) KIc (MPa m1/2) VH/KIc

FC 5.97  (±  0.22)a 2.31  (±  0.11)a 1.39  (±  0.23)a  4.29  (±  0.49)a

LD 6.84  (±  0.16)b 2.53  (±  0.17)a 2.18  (±  0.23)b 3.13  (±  0.34)b

LR 5.74  (±  0.20)a 1.77  (±  0.11)b 1.43  (±  0.26)a 4.01  (±  0.59)a

RN 1.02  (±  0.06)c 0.91  (±  0.03)c 2.22  (±  0.33)b 0.45  (±  0.10)c

*Same letters means that not statistically significant difference was found (columns).

Table 3. The descriptive statistics for Brittleness Index (μm-1/2) across the materials type.

Variable N Mean Std. deviation Variance Skewness Kurtosis

FC 13 2.31a 0.11 0.011 0.053 -1.065

LD 13 2.53a 0.17 0.029 -0.250 -0.796

LR 13 1.77b 0.11 0.013 0.459 1.545

RN 13 0.91c 0.03 0.001 1.265 3.067
*Same letters means that not statistically significant difference was found.

4 Braz. Oral Res. 2019;33:e026



Porto TS, Roperto RC, Teich ST, Faddoul FF, Rizzante FAP, Porto-Neto ST et al.

showed that the Vickers hardness of each ceramic is 
normally distributed.

One-way ANOVA was also performed for 
the brittleness index and showed statistically 
significant differences among the materials (p < 0.05). 
Games-Howell post-hoc test showed statistically 
significant difference by multiple comparisons 
(p < 0.05). The LD (2.54 ± 0.17) was not found to be 
statistically different from FC (2.31 ± 0.11); however, 
both materials were statistically significantly higher 
than LR (1.77 ± 0.11) and RN (0.91 ± 0.03). 

Because Vickers hardness and the brittleness index 
are both dependent variables, Pearson’s correlation 
was used and showed a statistically significant 
relationship between both dependent variables (p 
< 0.05). There is a significant positive relationship 
involving Vickers hardness and the brittleness index 
(r [50] = 0.93) (Figure 1).

After assumptions of homogeneity and data 
normally distributed one-way ANOVA was applied 

to KIc. Statistically significant differences were found 
and can be observed, with the means and standard 
deviations in Table 4. FC did not present statistical 
difference compared to LR. The last two materials 
were significantly different from LD and RN, however, 
LD and RN were not statistically different between 
each other.

A comparison between KIc and VH/KIc showed 
FC and LR with a strong relationship. Lower the 
fracture toughness (KIc) higher the brittleness (VH/KIc). 
Conversely, RN presented higher KIc compared to 
FC and LR but lower VH/KIc values. LD was not 
statistically significant different from RN in the 
KIc comparisons, however, as a pre-sintered glass 
ceramic phase the material had a higher VH/KIc 
value compared to RN.

Discussion

The purpose of this study is to investigate 
and evaluate the brit t leness index and the 
relationship with Vickers hardness, in addition 
the fracture toughness (KIc) of different CAD/
CAM materials, as well as the correlation between 
these measurements. The developments of CAD/
CAM technology combined with the new ceramic 
materials specifically designed for this technology 
are attracting the curiosity of many researchers.5, 

9, 10, 29-31 The principles of chair-side CAD/CAM are 
becoming increasingly accepted among clinicians 
and universities, changing the common way of 
learning indirect restorations and providing access 
to their application by more professionals in their 
practices.10,32,33,34 A new skill is becoming of major 
importance for future dentists, improving their 
competence and ability to do digital restorations. 
Furthermore, the mechanical properties of recent 
CAD/CAM materials demand knowledge and 
familiarity from clinicians.10,19 The behavior of a 
variety of CAD/CAM ceramics is being introduced 
in new concepts such as materials’ machinability, 
which is still not so well defined. The combination 
of inappropriate preparation design and the chosen 
materials can decrease the restoration longevity.

The first null hypothesis, that there is no correlation 
between properties tested, was rejected. As a result of 

Table 4. Means and standard deviation (SD) for KIc (MPa m1/2) 
across the materials tested. The third column presents the 
average by Vickers hardness (H) presented in table 2 and KIc 
(H/ KIc).

Variable N Mean (SD)* H/KIc

FC 13 1.39 (± 0.23)a  463 (± 50)a

LD 13 2.18 (± 0.23)b 319 (± 35)b

LR 13 1.43 (± 0.26)a 416 (± 61)a

RN 13 2.22 (± 0.33)b   49 (± 11)c

*Same letters means that not statistically significant difference was 
found within columns.

Figure 1. Pearson correlation between Vickers hardness (x) 
and Brittleness index (y).

Br
itt

le
ne

s 
in

de
x 

(µ
m

-1
/2
)

Vickers hardness

3

800700600500400300200100
0

0

2.5

2

1.5

1

0.5

5Braz. Oral Res. 2019;33:e026



Brittleness index and its relationship with materials mechanical properties: Influence on the machinability of CAD/CAM materials

the Pearson’s Correlation Coefficient, a relationship 
of 0.93 was achieved, indicating a strong relationship 
between the brittleness index and Vickers hardness, 
with a magnitude of 86%. Thus, the use of hard 
materials means more susceptibility to chipping, 
because the machinability of the materials with a 
high brittleness index performs more poorly than the 
machinability of the one with lower values. Lithium 
disilicate glass ceramic showed the highest values of 
brittleness index as well as Vickers hardness, whereas 
the feldspar leucite-reinforced glass ceramic showed 
intermediate values. As expected the nanofilled CAD/
CAM resin block presented the lowest values and 
thus can be considered the material with the best 
machinability among the ones tested. Based on the 
results of this study and the literature previously 
published, the polymer-based CAD/CAM materials 
will perform better in matters of machinability when 
compared with ceramic materials.19, 23The results also 
suggest that materials with high values of Vickers 
hardness will perform badly when they are combined 
with CAD/CAM technology.

The first research to discuss the relationship of 
brittleness index and other CAD/CAM mechanical 
properties has raised some significant questions 
regarding the use and the consequences of machining 
process.19,20,21 The proposal of considering chipping 
factor is reliable and can predict the materials’ 
machinability; however, the chipping factor can 
be measured only after milling.19 Determining the 
relationship between the brittleness index and other 
mechanical properties will lead the researchers 
to better understand the brittleness index as well 
as the behavior of CAD/CAM materials. The 
brittleness index can indicate the susceptibility of 
these materials to premature edge chipping.19,20,21 
Furthermore, as previously mentioned by other 
author polymer-based CAD/CAM materials has a 
lower hardness compared to ceramic materials,23 
which is in accordance with the results found in 
this in vitro study. Also a linear relationship can be 
established in between the milling and the materials 
hardness, which is predicted by the Archard wear 
equation.23 So not only a faster milling is possible 
but also polymer-based CAD/CAM materials will 
offer less resistance. Furthermore, the same positive 

relationship found between the chipping factor 
(CF) and BI19, 22 was also found between the BI and 
Vickers hardness. Even though it seems that the 
materials hardness could be another predictable 
of machinability, it should be always associated 
with other mechanical property. Finally polymer-
based materials will have a great advantage of 
producing smoother margins that of will reduce 
the edge chipping and marginal discrepancies.19,22,23 
Our findings can be supported by the increased 
chipping factor,19 on the ease of milling,23 and the 
Pearson’s correlation, which is 0.93.

CAD/CAM technology needs easy and simple 
prediction of machinability. The factors that are 
not easy to predict are tool wear, chipping control, 
machining and energy forces, and surface finish and 
integrity, because they can be checked only after 
manufacturing and qualitatively analyses.9, 10, 29 Due 
to application of the modern way of manufacturing 
ceramic restorations, quantitative analysis is extremely 
necessary to assess the purpose of new materials.

Recent data regarding fracture resistance, 
calculated by the thickness of the CAD/CAM11 
restorations for posterior teeth, have shown results 
that are comparable with our findings. The fracture 
resistance of nanofilled resin material was higher 
than that of lithium disilicate glass ceramic at a 
thickness of 0.5mm; however, when the thicknesses 
were increased to 3.0 mm, they had opposite 
results.10, 35 A strong positive linear relationships 
between the thickness and fracture load for 
lithium disilicate glass ceramic was observed. As 
the thickness of lithium disilicate glass ceramic 
was decresead, the fracture resistance was also 
decreased.10 Our findings show that LD with the 
highest level of brittleness index, when compared 
with the poor performance of fracture resistance at 
reduced thickness, should have specific indications. 
Despite these indications, lithium disilicate glass 
ceramic is still one of the best-performing materials 
when used correctly.

The strong positive relationship found between 
the brittleness index and Vickers hardness leads 
to the conclusion that harder materials are the 
most sensitive to fracture. In addition, previous 
studies showed that fracture resistance is affected 

6 Braz. Oral Res. 2019;33:e026



Porto TS, Roperto RC, Teich ST, Faddoul FF, Rizzante FAP, Porto-Neto ST et al.

by the occlusal thickness of ceramic and composite 
crowns.36,37 Occlusal thickness might lead us to 
define which materials should be used in determined 
clinical situations. 

Fracture toughness (KIc) that of lithium disilicate 
glass ceramic has a lower resistance in a pre-sintered 
phase which is comparable to nanofilled resin 
materials.28 Furthermore, a relationship between 
hardness and KIc (VH/KIc) which could be another 
simple approach of brittleness as described by Lawn 
and Marshall21 has shown lower values for lithium 
disilicate compared to feldspathic ceramic and 
leucite-reinforce glass ceramic (Table 2). Conversely, 
to the brittleness index (MPa.m1/2) and fracture 
toughness presented in Tables 2. The lower value 
indicates less brittleness. Within the materials tested 
the nanofilled resin material on both brittleness 
calculations presented the lowest values indicating 
less brittleness. Despite the linear relationship 
only for three of the four materials tested on both 
methods the authors believe that the discrepancy 
for lithium disilicate glass ceramic is due to a plastic 
behavior. Such plastic behavior could be to the pre-
sintered phase which the material is presented before 
milling. The brittleness index measured analyzing 
the cracks size after the indentation is closer to the 
reality of the material in terms of machinability 
compared to the simple approach of VH/KIc. The 
assumptions can be made based on the results 

previously published19-21, 23 in comparisons with the 
data acquired within this study.

The milling process of CAD/CAM technology 
can cause inner flaws, voids and cracks; as we can 
see on Figures 2–5, the concentration of loading 
around a pre-crack is much higher in ceramics than 
in composite materials. Furthermore, the literature 
implies the possibility of radial cracking mode for thin 
ceramics.25,38,39,40 Bulk properties will be significant 
for ceramic materials only at 2.0mm of thickness,35 
however, because of such great mechanical properties, 
dental ceramics can be use below that thickness.

Hardness is defined as the resistance to a permanent 
surface indentation. As a consequence of the resistance, 
ceramics hardness influences polishing procedures, 
wear resistance, and machinability.41 The brittleness 
index also has a strong positive connection with the 
hardness property, causing it to be one of the most 
important features to be analyzed before choosing a 
restorative CAD/CAM material. Despite the positive 
relationship found between Vickers Hardness and 
BI and within the limitations of this in vitro study 
Vickers hardness cannot predict the fragility of 
such materials, however, as mentioned above and 
supported by previously publications it seems that 
polymer-based materials produce better margins 
after milling procedures.

Currently, CAD/CAM restorations are not 
always successful because of overall materials’ 

Figure 2.  (a) Feldspathic ceramic strain released by the compression at the top of the specimen at the beginning of the test. (b) 
Below the compression area is possible to identify the strain being generated by such movement. Located above the V-notch a 
yellow orange area shows the tensile concentration at the exact moment before the specimen fracture.

exx [1] -
Lagrange
0.000122

0.000100005

8.475e-05

6.6125e-05

4.75e-05

2.8075e-05

1.025e-05

-8.37501e-06

-2.7e-05

-4+5625e-05

-6.425e-05

-8.2375e-05

-0.0001015

-0.000120125

-0.00013875

-0+000157375

-0.000176

exx [1] -
Lagrange
0.0006

0.00053125

0.0004625

0.00039375

0.000325

0.00025625

0.0001875

0.00011875

5e-05

-1.875e-05

-8.75e-05

-0.00015625

-0.000225

-0.00029375

-0.0003625

-0.00043125

-0.0005

A B

7Braz. Oral Res. 2019;33:e026



Brittleness index and its relationship with materials mechanical properties: Influence on the machinability of CAD/CAM materials

Figure 3. (a) Lithium disilicate glass ceramic represented by neutral strains on moments before initial loading. (b) The compression 
area can be identified by the negative forces applied at the top of the specimen. The v-notch is characterized by positive tensile 
spread over it. On both sides of the v-notch yellow orange area is present.

exx [1] -
Lagrange

1

0.875

0.75

0.625

0.5

0.375

0.25

0.125

0

-0.125

-0.25

-0.375

-0.5

-0.625

-0.75

-0.875

-1

exx [1] -
Lagrange

0.00245

0.00021

0.000175

0.00014

0.000105

7e-05

3.5e-05

0

-3.5e-05

-7e-05

-0.000105

-0.00014

-0.000175

-0.00021

-0.000245

-0.00028

-0.000315

A B

Figure 4. (a) Leucite-reinforced glass ceramic shows the initial compression area spread on the surface of the specimen. (b) As 
presented by the feldspathic ceramic in fig. 3(a) at the top of the V-notch the tensile is characterized by the loading concentration 
in sharp corners. The same pattern can be observed in this figure for leucite-reinforced glass ceramic.

exx [1] -
Lagrange
0.000188

0.000172375

0.00015675

0.000141125

0.0001255

0.000109875

9.425e-05

7.8625e-05

6.3e-05

4.7375e-05

3.175e-05

1.6125e-05

5.00004e-07

-1.5125e-05

-3.075e-05

-4.6375e-05

-6.2e-05

exx [1] -
Lagrange

0.00038

0.00032875

0.0002775

0.00022625

0.000175

0.00012375

7.25e-05

2.125e-05

-3e-05

-8.125e-05

-0.0001325

-0.00018375

-0.000235

-0.00028625

-0.0003375

-0.00038875

-0.00044

A B

Figure 5. (a) Nanofilled resin material is characterized by scattering the strain due to plastic behavior. The initial compression 
can be seen just below the machine device. (b) At the moment just before the fracture scattering of the tensile stress is around the 
v-notch similar to the lithium disilicate glass ceramic showing that of unexpected plastic behavior.

exx [1] -
Lagrange
9.7e-05

8.2375e-05

6.775e-05

5.3125e-05

3.85e-05

2.3875e-05

9.25e-06

-5-375e-06

-2e-05

-3.4625e-05

-4.925e-05

-6.3875e-05

-7.85e-05

-9.3125e-05

-0.00010775

-0.000122375

-0.000137

exx [1] -
Lagrange

0.00142

0.00121125

0.0010025

0.00079375

0.000585

0.00037625

0.0001675

-4.125e-05

-0.00025

-0.00045875

-0.0006675

-0.00087625

-0.001085

-0.00129375

-0.0015025

-0.00171125

-0.00192

A B

8 Braz. Oral Res. 2019;33:e026



Porto TS, Roperto RC, Teich ST, Faddoul FF, Rizzante FAP, Porto-Neto ST et al.

characteristics and complex restorations which are 
continual difficulties that every clinician is faced with. 
In this study, we find that an important mechanical 
property, such as the brittleness index, can make a 
real difference into the daily clinical application of 
these materials. Our findings should be eventually 
tested with different in vitro experiment, such as crown 
fracture resistance or fatigue, in order to develop 
a better understanding of the materials’ behavior.

Conclusion

Based on the limitations of our findings of the 
Brittleness index and its relationship with Vickers 
hardness, the following conclusions were drawn 
assuming the load used to calculate:
a. There is a high and positive relationship 

between Brittleness index and Vickers hardness, 

which is above of 85%. In addition, materials 
with higher BI are more susceptible to chipping;

b. Based on our findings is possible to affirm that 
materials, which possess elevated hardness, are 
more susceptible to chipping that may lead to 
inner cracks and flaws;

c. Milling procedures must be controlled in order 
to avoid premature edge chipping even though 
the materials are not being stressed to its 
maximum capacity;

d. The fracture toughness of CAD/CAM materials 
is not related to materials’ milling capacity.

Acknowledgments
The authors would like to thanks Professor Romeu 

Magnani for supporting knowledge and helping 
with the calculation of statistical test, also Dr. Jim 
Stephens for editorial assistance.

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