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1471 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1471-1490, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-49849 

CERAMIC VENEERS ON TEETH WITH NON-CARIOUS CERVICAL 
LESIONS: CASE REPORT AND FINITE ELEMENT ANALYSIS 

 
FACETAS CERÂMICAS EM DENTES COM LESÕES CERVICAIS NÃO-CARIOSAS: 

RELATO DE CASO E ANÁLISE DE ELEMENTOS FINITOS 
 

Ana Paula Rodrigues MAGALHÃES1; Paulo Vinícius SOARES2; 
 Alexandre Coelho MACHADO3; Daiana Sabrine PAULI1;  

Marcelle Ignez dos Santos Moura FALEIROS1; Rafael Almeida DECURCIO1;  
Paula de Carvalho CARDOSO1 

1. Department of Restorative Dentistry, Brazilian Dental Association, Goiânia, GO, Brazil; 2. Department of Operative Dentistry and 
Dental Materials, School of Dentistry, Federal University of Uberlândia, Uberlândia, MG, Brazil; 3. NCCL Research Group, Technical 

Health School, Federal University of Uberlândia, Uberlândia, MG, Brazil. 
anapaulardm@gmail.com

 

 
ABSTRACT: On ceramic veneers rehabilitation, teeth with non-carious cervical lesions (NCCLs), 

especially premolars, are often involved. Preparation to remove deep NCCLs may lead to excessive wear and a 
less conservative approach, which goes against the current principles of minimal wear and maximum 
preservation. However, no evidence exists indicating which technique could avoid excessive wear during the 
dental preparation for veneers associated with NCCL. Thus, this study aimed to present an aesthetic treatment 
with ceramic veneers and follow-up of 24 months of a patient with various levels of NCCL severity; and to 
evaluate various wear protocols for dental veneers associated with NCCL via Finite Element Analysis (FEA) to 
guide and justify the clinical decision of the clinical case described. A 37-year-old male patient presented for 
treatment with wear on the anterior teeth and with NCCLs of various severity degrees on the posterior teeth. 
The treatment chosen was rehabilitation with ceramic veneers on teeth 15 to 25. The best restorative approach 
for the NCCL teeth was evaluated via an FEA, simulating various protocols and lesion depths while also 
calculating the percentage of tooth structure loss. Restoring the premolar’s deeper NCCL with a composite 
resin core, before a ceramic veneer impression, presented better mechanical behavior in FEA and less tooth 
wear. For the 1.0 mm NCCL, beveling the lesion promoted good stress distribution, less invasive wear and an 
easier clinical procedure, as it did not involve a previous restorative procedure. It could be concluded that the 
restorative decision for premolars with NCCLs that will receive veneers should consider the set biomechanical 
behavior and especially the tooth structure wear necessary. For the case report presented, after two years of 
follow-up, no changes from the immediate result were observed, indicating that the cause of the lesions was 
eliminated, and that the treatment was effective, at least in the short-term. For FEA analysis, restoring the 
deeper NCCL prior to ceramic veneer impression, presented better mechanical behavior and less tooth wear. 
For the 1.0 mm NCCL, beveling the margin of the lesion generated the same good results. 

 
KEYWORDS: Tooth wear. Dental veneers. Finite element analysis. 
 

INTRODUCTION 
 
Non-carious cervical lesions (NCCL) are 

defined as a loss of dental hard tissue at the 
cemento-enamel junction not related to a carious 
process (CIEPLIK et al., 2017). They usually result 
from a multifactorial process associated with 
abrasive and/or biocorrosive mechanisms but also 
from occlusal stress when the action of paraaxial 
occlusal biomechanical loads promote loss of tooth 
structure (GRIPPO; SIMRING; COLEMAN, 2012; 
JAKUPOVIC et al., 2014; TEIXEIRA et al., 2018). 
These loads concentrate stress in the cervical region 
of the tooth and generate the NCCL (JAKUPOVIC 
et al., 2014).  

The presence of NCCLs in the cervical area 
changes tooth geometry and may also interfere in 
the stress concentrations, distribution and intensity 
in the chewing process, tending to their evolution 
(REES; HAMMADEH, 2004). Mechanical abrasion 
and biocorrosion after dentin exposure can also 
speed up the NCCL’s progression. Removing or 
controlling the etiological factors involved in the 
development of the NCCLs is a very important step 
on their treatment, and the most effective measure 
on preventing their recurrence (SAWLANI et al., 
2016; SOUZA et al., 2017). However, restoring 
these NCCLs is also very important for protection 
against more severe wear, preventing dentin 
hypersensitivity, enhancing aesthetics and 

Received: 08/04/19 
Accepted: 20/12/19 



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minimizing the damages to a tooth’s biomechanical 
behavior (OGINNI; ADELEKE, 2014; SOARES et 
al., 2014a; SOARES et al., 2015; MACHADO et al., 
2017). Nowadays, many patients have an aesthetic 
complaint associated with NCCLs, requiring a more 
complex restorative resolution.  

The ceramic veneers have been widely 
applied for aesthetic rehabilitation in recent years 
(CALAMIA; CALAMIA, 2007; SOARES et al., 
2014b; ARIF et al., 2019). The presence of NCCLs 
makes the luting line on the cervical margin more 
fragile, as there is little or no enamel on that area 
and adhesion will rely on dentin (PERDIGÃO et al., 
2014; REIS et al., 2017). Besides, the decision to 
prepare to remove deep NCCLs may lead to 
excessive wear and a less conservative approach. 
This goes against current principles of minimal wear 
and maximum preservation in every restorative 
treatment, including with ceramics (DECURCIO et 
al., 2015). No evidence exists indicating which 
technique could better avoid invasive wear during 
the dental veneer preparation associated with 
NCCL: a composite resin filling under the veneer or 
simply filling the NCCL with resin luting cement 
and ceramic. 

Due to the difficulty of analyzing this kind 
of restoration in clinical or laboratorial studies, a 

finite element analysis (FEA) could help detect 
stress concentration areas in each possible 
restorative approach and lead to a more certain 
clinical decision. Thus, this study aimed to present 
an aesthetic treatment and follow-up with ceramic 
veneers of a patient with various levels of NCCL 
severity; and to evaluate various wear protocols for 
dental veneers associated with NCCL via FEA to 
guide the clinical decision of the clinical case 
described. For the second purpose, the null 
hypothesis was that there is no difference among 
various restorative techniques proposed in FEA. 

 
MATERIAL AND METHODS 

 
Finite Element Analysis 

An FEA was used to evaluate the effects of 
NCCL, the amount of dental wear and the 
restorative technique’s methods on the pattern of 
stress distribution on premolars. A computerized 
and two-dimensional linear FEA simulated a sound 
tooth model with dental structures, including dentin, 
pulp, enamel, periodontal ligament, cortical bone 
and trabecular bone (SOARES et al., 2008). 
Thirteen models were created, simulating various 
clinical situations listed in Table 1 and represented 
in Figure 1. 

 
Table 1. Description of the CAD models according to the characteristics of each restorative technique 

simulated   

Groups Lesion depth Wear Restorative technique 

S Sound No No 
SBV Sound Minimal wear Veneer 
SV Sound Conventional Veneer 
L1 1,0 mm No No 

L1BV 1,0 mm 
Bevel on lesion angle and minimal 
wear 

Veneer 

L1V 1,0 mm Conventional Veneer 
L1IV 1,0 mm Invasive (involving lesion) Veneer 
L1CV 1,0 mm Bevel Composite resin core + Veneer 
L2 2,5 mm No No 

L2BV 2,5 mm 
Bevel on lesion angle and minimal 
wear 

Veneer 

L2V 2,5 mm Conventional Veneer 
L2IV 2,5 mm Invasive (involving lesion) Veneer 
L2CV 2,5 mm Bevel Composite resin core + Veneer 

 



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Figure 1. CAD models created according to the characteristics of each restorative technique simulated. 

 
The dental structures’ geometry was 

simulated using CAD Software (Rhino3D 4.0, 
Rhinoceros, United States) to obtain internal and 
external structural contours (Figure 2.A). This 
software also calculated the amount of tooth 
structure lost (enamel and dentin) in each simulated 
model as compared to the sound tooth. The models 
were exported to ANSYS 12.0 using the *. IGES 

format. The stress distribution patterns were 
analyzed using ANSYS 14.0 (Ansys Workbench 
14.0, PA, United States). This software was used to 
define the dental structures’ area (Figure 2.B), 
mechanical properties, mesh (Figure 2.C) and the 
boundary conditions of each model (Figure 2.D and 
2.E) to produce the resulting analysis. 

  

 
 

Figure 2. Finite Element models generation.  
 A) CAD software model outlines. B) Created areas of each dental and support structure. C) Mesh generation. D) Vertical 

loading applied (100N); E) Displacement restriction (null on the purple line). 
 
Areas corresponding to each structure were 

plotted via linear associations (Figure 2.B). The 
models’ mesh was elaborated using isoparametric 
elements of 8- brick nodes with three degrees of 
freedom per node according to each structure’s 
mechanical properties (Figure 2.C). The values for 
mechanical properties were obtained via literature 

review (Table 2). Enamel and dentine properties 
were considered orthotropic; other dental structural 
properties used were considered isotropic. The 
meshing process involved a division of the studied 
system into a set of small and discrete elements 
defined by nodes. The number of elements 
generated varied depending on the various 



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geometries that were meshed, so the result 
accurately represented the original geometry. The 

models were considered homogeneous and elastic. 

 
Table 2. Mechanical properties used for structures  

STRUCTURE ORTHOTROPIC STRUCTURES (MIURA et al., 2009) 
 Longitudinal Transversal Z 
 Young Modulus (MPa) 

Enamel 73720 63270 63270 
Dentin 17070 5610 5610 

 Shear Coefficient (MPa) 
Enamel 20890 24070 20890 
Dentin 1700 6000 1700 

 Poisson Ratio (v) 
Enamel 0.23 0.45 0.23 
Dentin 0.30 0.33 0.30 

 ISOTROPIC PROPERTIES 
 Elasticity Modulus (MPa) Poisson Ratio (v) 

Composite Resin 
(SHINYA et al., 2008) 

22000 0.27 

Cortical Bone 
(CARTER; HAYES, 1977) 

13700 0.30 

Lithium Dissilicate (ERASLAN et 
al., 2009) 

65000 0.23 

Medular Bone 
(CARTER; HAYES, 1977) 

1370 0.30 

Periodontal Ligament 
(MIURA et al., 2009) 

300 0.45 

Pulp 
(RUBIN et al., 1983) 

2.07 0.45 

 
 
Each step of the boundary conditions 

included the displacement restrictions of the model 
and load application. The occlusal load (100 N) was 
applied equally on both cusps so that its resultant 
load was parallel to the tooth’s long axis (Figure 
2.D). The displacement model was restricted in all 
nodes on the cortical and medullar bone’s base 
(Figure 2.E). The results of the mathematical 
calculations were plotted on the von Mises stress 
(equivalent stress) and the maximum principal 
stress, measured in MPa. The maximum principal 
stress was plotted without the restorative materials 
to better analyze the remaining tooth structure.  

 
RESULTS 

 
The von Mises stress and maximum 

principal stress patterns of all simulated models are 
presented in Figures 3 and 4, respectively. 

For von Mises (Figure 3), the higher values 
(colors close to red) represent areas with higher 
stress and do not distinguish the stress type. The 

biomechanical behavior of the S model was similar 
to SBV and SV. These models presented more 
homogenous stress distribution compared to the 
models with NCCL (L1 and L2), independent of 
depth. With NCCL, the stress was concentrated at 
the bottom of the lesion, with greater stress on the 
2.5 mm depth. Independently of the evaluated dental 
veneer preparation protocol associated with 1.0 mm 
NCCL, all models presented stress patterns closer to 
the sound tooth (S). For the models with 2.5 mm 
NCCL, the most invasive preparation (L2IV) 
showed greater stress values on the cavity 
preparation’s dentin. The other models showed 
stress patterns similar to S, SBV and SV. 

For maximum principal stress (Figure 4), 
the positive values (colors close to red and black) 
represent areas with greater tensile stress values, and 
the gray and white colors show regions without 
tensile stress. For this criterion, the tensile stress 
pattern was very close for all models, except for the 
situation with unrestored NCCL (for both 1.0 and 
2.5 mm severities). 

 



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Figure 3. Stress distribution by von Mises criterion according to groups, identifying areas with higher stress 

(close to red color) and lower stress (close to blue color). 
 
 

 
Figure 4. Stress distribution by maximum principal stress criterion according to groups, identifying areas with 

more tensile stress (red and black) and no tensile stress (gray and white). 
 
Figure 5 shows the percentage of tooth area 

loss in each designed model compared with S. 
Veneers on the sound tooth showed an enamel loss 
of 20.8% and 36.6% for minimal (SBV) and 
conventional veneers (SV) preparation, respectively. 
The amount of dentin loss for 1.0 mm NCCL and 
for veneer preparation was close (between 1.1% and 
5.8%) for all the restorative protocols evaluated. 
However, the enamel loss was 16.1% greater for 
conventional wear (L1V) than for the minimal wear 

(L1BV) for 1.0 mm NCCL. The 2.5 mm lesion with 
conventional veneer wear (L2CV) presented enamel 
and dentin reductions up to 44.7% and 17.9%, 
respectively. The model L2CV with a 2.5 mm 
NCCL associated with composite resin core and 
veneer showed enamel loss similar to the SBV 
model with minimal veneer wear and dentin loss 
comparable to the L2 model (only for the 2.5 mm 
lesion).  



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Figure 5. Tooth area loss (in %) compared to the sound tooth for each NCCL or restorative technique model. 

 
Case report 

A 37-year-old male patient presented at the 
Restorative Dentistry clinic complaining that his 
smile looked aged and inverted (Figures 6 and 7). In 
resting-lips position, almost no tooth structure was 

visible (Figure 8). After clinical examination and a 
deeper anamnesis, he was noticeably unsatisfied 
with his smile due to significant tooth wear on the 
anterior teeth and the presence of NCCLs on the 
posterior teeth (Figure 9).  

 

 
Figure 6. Initial smile picture of the patient. 

 

 
Figure 7. Inital smile, showing tooth wear. 

 



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Figure 8. Resting-lips position photography showing insufficient teeth exposure. 

 

 
Figure 9. Intra-oral view evidencing anterior teeth wear and the presence of NCCLs in premolars and canines. 

 
A close examination of his posterior teeth 

verified shallow NCCLs, mainly on teeth 13, 15, 23, 
25 and 26, and deeper NCCLs on teeth 14 and 24 

(Figures 10 and 11). A periodontal probe (Golgran, 
São Caetano do Sul, Brazil) measured the NCCL on 
24 as approximately 2 mm deep (Figure 12). 

 

 
Figure 10. NCCLs of different depths in teeth 13, 14, and 15. 

 



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Figure 11. NCCLs of different depths in teeth 23, 24, 25, and 26. 

 

 
Figure 12. Periodontal probe measuring the approximately 2 mm-depth NCCL in tooth 24. 

 
In the interview, the patient reported that he 

presented bruxism for a while, which was probably 
the reason for all the wearing and could have helped 
develop the NCCLs he presented. The patient was 
further evaluated, and it was concluded that he no 
longer presented parafunctional habits. No 
premature contacts were identified in static 
occlusion, but occlusal interferences were found in 
the canine and anterior guides’ disocclusion. No 
acid diet or reflux were identified. Reported dental 
hygiene habits did not justify the presence or depth 
of the NCCLs.  

The patient presented a clear indication for 
aesthetic treatment with ceramic laminate veneers 
with minimal preparation. With the photographs 
taken, digital treatment planning was carried out to 
determine his ideal teeth dimensions. The reference 
for calculating dental size was the interpupillary 
distance (CESARIO; LATTA, 1984). Based on 
those calculations, a diagnostic wax-up was carried 
out for teeth 15 to 25 and a mock-up on bisacrylic 
resin (Protemp, 3M ESPE, Saint Paul, United 

States) was obtained from the wax-up (Figures 13 
and 14). With the mock-up in position, it was 
possible to see that the smile was no longer inverted 
and that the patient now had exposed teeth in 
resting-lips position. Also, the sizes calculated were 
harmonic to the patient’s face and lips. 

To improve the long-term life of the 
veneers, the preparations still had to be planned due 
to the presence of the NCCLs. No evidence exists in 
literature about what to do in these situations, 
although some evidence shows the biomechanical 
behavior of the tooth is better when the NCCL is 
restored (MACHADO et al., 2017).  

After analyzing the FEA results, the clinical 
decision was to use the more conservative 
restorative techniques. The first step was to bevel 
the margins of the shallow NCCLs that were less 
than 1 mm deep. A diamond bur of extra-fine (FF) 
granulation (KG Sorensen, Cotia, Brazil) was used 
with slight pressure perpendicular to the enamel 
margin to round the NCCL angle, creating a bevel 
(Figures 15a-15c). 



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Figure 13. Mock-up in resting-lips position, showing, now, good teeth exposure. 

 

 
Figure 14. Smile with mock-up in position, rebuilding the worn teeth. 

 

 
Figure 15. Clinical sequence for tooth 25(A and B), where only a bevel was created (C). 

 
Then, lesions deeper than 2 mm were 

restored with composite resin prior to impression. It 
was impossible to carry out absolute field isolation 
on tooth 24 due to the lesion’s subgingival depth. To 
control humidity, a relative isolation was carried out 
instead (DAUDT; LOPES; VIEIRA, 2013; 

LOGUERCIO et al., 2015). First, the lip retractor, 
cotton rolls and saliva ejector were positioned 
(Expandex, Maquira, Maringá, Brazil), and a 
retractor cord (Ultrapack 00, Ultradent, South 
Jordan, United States) was carefully inserted in the 
gingival sulcus (Figures 16a and 16b). Selective 



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enamel etching was carried out for 15 seconds with 
37% phosphoric acid (Power Etching, BM4, 
Maringá, Brazil), and then the etching was washed 
for another 15 seconds (Figure 16c). Then, the 
adhesive Singlebond Universal (3M ESPE, Saint 
Paul, United States) was actively applied in one 
layer for 20 seconds (Figure 16d). The excesses 
were removed, and then the adhesive layer was 
light-cured for 10 seconds (Valo, Ultradent, South 
Jordan, United States) (Figure 16e). The composite 
resin (Filtek Z350 XT, 3M ESPE, Saint Paul, United 

States) restoration was built in increments with 
spatulas (Golgran, São Caetano do Sul, Brazil) and 
brushes (Cosmedent, Chicago, United States) until 
the NCCL was completely filled (Figures 16f-16h). 
For tooth 14, absolute field isolation was carried 
out, and the same steps for restoring tooth 24 were 
carried out (Figures 17a-17b). Both restorations 
were polished with diamond burs (KG Sorensen, 
Cotia, Brazil) and rubber polishers (Cosmedent, 
Chicago, United States). 

 

 
Figure 16. Clinical sequence for tooth 24: retractor cord insertion (A and B); selective enamel etching (C); 

universal adhesive application (D); photocuring (E); incremental restorative technique (F and G); 
and final composite resin restoration (H). 

 

 
Figure 17. For tooth 14 it was possible to do absolute field isolation; initial NCCL aspect (A) and final 

restoration (B). 
 
Then, minimal preparation was carried out 

on the other teeth, and impressions were taken using 
the two cords (Ultrapak, Ultradent) and two steps 
technique with addition silicon (Elite HD, 
Zhermack, Badia Polesine, Italy).  

The obtained photographs, casts and 

occlusal registrations were sent to the technician to 
guide him through the presented clinical conditions 
for the development of the ceramic veneers. 
Considering the minimal preparation, no provisional 
restorations were needed. The ceramic veneers were 
made with lithium-disilicate ceramic (e.Max, 



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Ivoclar Vivadent, Schaan, Liechtenstein) via the 
pressed technique and then painted to look more 
natural. 

After cleaning the substrate with brushes 
(Microtuf, Hot Spot Design, Capão da Imbuia, 
Brazil), pumice stone (SS White, São Cristóvão, 
Brazil), and water, the veneers were positioned on 
the tooth’s surface for adaptation and color 
evaluation with the try-in paste color Neutral 
(Variolink Esthetic, Ivoclar Vivadent, Schaan, 
Liechtenstein).  

Then, the inner ceramic surface treatment 
was carried out with 5% hydrofluoric acid (Power 
CEtching 5%, BM4, Maringá, Brazil), respecting 
the 20-second conditioning time for lithium-

disilicate. After that time, the acid was removed 
from the ceramic surface through an abundant 
water/air spray for residue removal (MAGALHÃES 
et al., 2017). This was followed by a silane 
application (Monobond Plus, Ivoclar Vivadent, 
Schaan, Liechtenstein). Then, after relative field 
isolation and protection of the neighboring teeth 
(Figure 18a), the enamel was etched with 37% 
phosphoric acid (Power Etching

®
 37%, BM4) 

(Figure 18b) for 30 seconds and then rinsed with 
water/air sprays for 30 seconds. The adhesive 
(Singlebond Universal, 3M ESPE) was actively 
applied to the enamel surface for 20 seconds, and 
excesses were removed (Figure 18c). 

 

 
Figure 18. Luting of the veneer on tooth 14 with previous surface treatment: protection of the neighboring teeth 

(A); acid etching (B) and adhesive application (C). 
 
Finally, the ceramic was filled with the light 

cured resin luting cement and the color selected in 
the trial stage (Variolink Esthetic Neutral, Ivoclar 
Vivadent). The veneer was positioned with 
continuous finger pressure (Figure 19). Then, the 
excesses were removed with a brush, and the veneer 
was light cured for 60 seconds in the buccal and 

palatal faces with poliwave light curing device 
(Valo, Ultradent). These procedures were repeated 
for each individual tooth. Those with shallow 
NCCLs with subgingival termination received a 
retractor cord (Ultrapak, Ultradent) before luting 
procedures, and then everything was carried out the 
same way (Figure 20a-20c and 21).  

 

 
Figure 19. Ceramic veneer positioned on tooth 14 prior to cement excess removal and photocuring. 



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Figure 20. Luting of the veneer on tooth 25 with previous surface treatment: protection of the neighboring teeth 

(A); acid etching (B) and adhesive application (C). 
 

 
Figure 21. Luted veneers on teeth 24 and 25. 

 
After luting, all the porcelain veneers were 

finished with a serrated saw strip (Komet, Lemgo, 
Germany) on the proximal areas and with scalpel 
blade n.12 (Solidor, Joinville, Brazil) in the cervical 
region to remove excesses. The occlusal 
adjustments were carefully carried out to reestablish 
his anterior and canine guides and balance his 
occlusal loads, especially on the teeth that presented 
NCCLs. In the next appointment, when complete 
elimination of cement excesses was confirmed, the 
margins were polished with abrasive silicones for 

ceramic polishing, the Porcelain Veneer Kit® 
(Shofu, Japan). Figures 22 to 24 show the final 
photos after cementation. No occlusal guard was 
installed as the patient did not present bruxism 
anymore by the time the treatment was carried out, 
and the excursive guides were reestablished 
properly. He was further oriented to execute good 
oral hygiene, brushing and flossing, and also to 
return to the dentist for prophylaxis every six 
months in order to detect any problems on the 
veneers as soon as possible.   

 

 
Figure 22. Final resting-lips position picture showing adequate tooth exposure. 



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Figure 23. Final smile picture showing teeth compatible with the patient’s age, without wear. 

 

 
Figure 24. Final face smiling picture showing a harmonious smile. 
 

A year and, then, two years later, this 
patient returned for examinations. No changes were 
observed in teeth without NCCL or in those with 
shallow or deep lesions, and the patient declared 

himself satisfied with the treatment (Figures 25-28). 
These results may show that the cause of the lesions 
was eliminated, and that the treatment was effective, 
at least in the short-term. 

 

 
Figure 25. Two years follow up of the ceramic veneers. 

 



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Figure 26. Close-up of teeth with previous NCCLs 13, 14, and 15, two years latter. 

 

 
Figure 27. Close-up of teeth with previous NCCLs 23, 24, and 25, two years latter. 

 

 
Figure 28. Patient smile after two years of the esthetic-functional treatment, with the veneers in very good 

conditions. 
 
DISCUSSION 

 
One origin of NCCLs is reported to be tooth 

deflection caused by excessive occlusal loads in 
lateral movements (POIATE et al., 2009). They are 
more frequently observed in upper premolars’ 

buccal surfaces (SOARES et al., 2015; TEIXEIRA 
et al., 2018), as seen in the clinical case reported. 
The mean prevalence varies from 27 to 85% and 
increases with age (TANAKA et al., 2003). Enamel 
in the cervical region is very thin, formed by a few 
layers of enamel prisms. These layers cannot bear 



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tensile stress, making this area more susceptible to 
NCCL formation (POIATE et al., 2009). This loss 
of dental structure in NCCLs, though lower than 5% 
(Figure 16), causes great changes in the dental 
components’ biomechanics. Thus, they must be 
restored to reestablish the mechanical balance and 
avoid NCCL progression (SOARES et al., 2015; 
SOARES; GRIPPO, 2017). Other factors could also 
relate to the formation of NCCLs, including age, 
gender, gastric diseases, brushing teeth, exogenous 
acid agents and more (SOUZA et al., 2017; 
TEIXEIRA et al., 2018). 

There is a consensus that NCCLs should be 
restored with adhesive materials with optical 
properties similar to the tooth (KIM et al., 2009; 
MACHADO et al., 2017), as they improve 
aesthetics and can minimize hypersensitivity 
(SOARES et al., 2008; FRON et al., 2011; CHEE; 
RICKMAN; SATTERTHWAITE, 2012; REIS et 
al., 2017; TEIXEIRA et al., 2018). If the restorative 
material presents mechanical properties similar to 
the tooth’s properties, it may also restore the 
biomechanical balance lost with the NCCL 
formation. Dental materials with mechanical 
properties much higher or lower than those of the 
tooth structure may lead to stress concentration and 
deformation in the affected area (MACHADO et al., 
2017). However, few studies analyze some possible 
restorative protocols for NCCLs (MACHADO et al., 
2017). 

FEA is a widely used numerical analysis 
that has been successfully applied in many areas of 
engineering and bioengineering since 1950 
(SOARES et al., 2012). Today, it is considered one 
of the broadest available methods to calculate the 
complex conditions of stress distribution in dental 
systems (VERSLUIS; TANTBIROJN, 2009). Thus, 
FEA makes it possible to analyze stresses observed 
in various clinical situations that could not be 
simulated in laboratory studies or evaluated 
clinically. It is possible to define the areas of stress 
concentration and the ones more likely to fail within 
a structure or material (SOARES et al., 2008; 
SOARES et al., 2012). 

Cases like the one presented are very 
common nowadays, as many patients suffer from 
occlusal disorders and may develop NCCLs in teeth 
under these occlusal forces (SAWLANI et al., 
2016). Another indicator of occlusal disorder in this 
case is the wear observed in the anterior teeth. The 
patient did not present alteration on the occlusal 
dimension, so the aesthetic rehabilitation with 
veneers was enough to solve his complaint and to 
rebuild the anterior guides, but it had to be planned 
correctly to avoid invasive preparations and 

unwanted tooth structure sacrifice, especially in the 
teeth with NCCLs. 

Considering the restorative material, 
composite resins are widely used to restore NCCLs 
because they do not require excessive wear, have a 
Young modulus comparable to dentin, a 
micromechanic retention by adhesion to the tooth 
structure and a good aesthetic (FERRACANE, 
2011; DEMARCO et al., 2017). Ceramic materials 
also present characteristics that justify their use in 
restoring NCCLs (MACHADO et al., 2017). For 
example, they conduct heat and electricity poorly, 
show little degradation from abrasion or 
biocorrosion, adhere to a tooth’s structure via a resin 
cement, and are excellent for polishing (MCCABE; 
WALLS, 2008). However, they present high 
flexural strength and Young modulus, making their 
mechanical behavior similar to enamel but very 
different from dentin (MCCABE; WALLS, 2008). 
Thus, an interesting restorative approach would be 
to use composites to replace dentin and use ceramics 
to replace enamel (MACHADO et al., 2017).  

When analyzing the FEA results, all the 
studied restorative approaches presented a 
biomechanical behavior similar to the sound tooth 
model, except for the L2IV model, which presented 
higher stresses in dentin on the von Mises criteria; 
rejecting the null hypothesis. This occurred mainly 
because the occlusal load was applied parallel to the 
tooth’s long axis, which corresponds to the best 
mechanical behavior of every tooth element. Other 
occlusal loads were not studied, as the authors 
assumed that veneers should not be placed in 
situations of unbalanced occlusions or in the 
presence of occlusal interferences. During the 
clinical function, occlusal interferences and higher 
magnitudes of occlusal forces could enhance the 
risk of rupture, anticipating the failure of the 
ceramic veneer, either on the resin cement interface 
or on ceramic (ARCHANGELO et al., 2011). 

Considering the similar biomechanical 
behavior, the choice of restorative technique should 
consider the FEA results and, most importantly, the 
preservation of tooth structure. The determination of 
the NCCL depth was important in order to decide 
for the best treatment indication, as differences were 
observed in the FEA analysis and also in the volume 
of tooth structure loss for the different approaches 
studied (ZEOLA et al., 2016). For the 1.0 mm 
lesion, the beveled model and the composite resin 
core models made it possible to save more tooth 
structure when compared to the other wear designs. 
Considering the difficulty of restoring this kind of 
lesion, especially due to location and humidity, a 
more practical clinical procedure would be to bevel 



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the NCCL. As there was no difference in 
biomechanical behavior or tooth structure loss, the 
bevel and minimal wear seems to be the most 
appropriate approach for this severity of NCCL, and 
this approach was chosen for the presented clinical 
case. 

Restoring the 2.5 mm NCCL with a 
composite resin core prior to veneer luting promotes 
more homogenous stress distribution (MACHADO 
et al., 2017). In this case, as previously discussed, 
the composite resin could mimic the mechanical 
behavior of dentin because ceramic played the role 
of enamel, resulting in a stress distribution very 
similar to a sound tooth (MACHADO et al., 2017). 
Furthermore, this approach could save more healthy 
dental structure, even when compared to the beveled 
model, and avoid a more invasive wear. Thus, that 
was the chosen restorative strategy for the case 
presented and may be the more appropriate clinical 
decision for such lesions.  

In this strategy, questions may be raised 
considering the ceramic luting over the composite 
resin core. Studies show that the bond strength 
between the core material and the resin cement is 
usually good, even when aging of the composite is 
carried out (GRESNIGT et al., 2012; POLAT et al., 
2015). Polat et al (2015) in their study, showed that 
the best surface treatment for the aged core 
composite, previous to luting, was Er:YAG laser 
irradiation. Although, 35% phosphoric acid etching 
led to bond strength values statistically similar to 
that of non-aged composite (control group). Another 
study evaluating the influence of proximal box 
elevation on the bond strength of composite inlays, 
showed that the presence of composite did not affect 
the results for a total etch resin cement (DA SILVA 
GONÇALVES et al., 2017). The same authors 
showed that the composite presence actually 
improved adhesion for a self-adhesive cement (DA 
SILVA GONÇALVES et al., 2017), supporting the 
use of the composite resin core for NCCL situations 
as well. 

The presence of a traumatic occlusion by 
nonaxial loads of occlusal interferences is 
considered a very important factor in the occurrence 
and development of abfractions (SAWLANI et al., 
2016). Thus, irrespective of the type of restoration 
performed, the removal of possible occlusal 
interferences and the reestablishment of occlusal 
balance are very important for stopping NCCLs’ 

development and avoiding the appearance of new 
lesions after treatment (SOARES et al., 2015). 
Possible biocorrosive or abrasive causes that might 
have led to the NCCLs should also be controlled to 
ensure a long-lasting treatment (SOARES et al., 
2015). 

Ceramic veneers presented high survival 
rates of almost 100% from 7 to 14 years 
(D’ARCANGELO et al., 2012; ARIF et al., 2019). 
The clinical behavior after two years is an important 
indicator of the short-term behavior of the treatment 
proposed, as many failures can be observed in the 
first months of follow-up (D’ARCANGELO et al., 
2012). The absence of new NCCLs, of ceramic 
fractures, chipping or staining shows that probably 
the NCCLs’ etiologic factors were adequately 
controlled. A longer observation period is necessary 
in order to verify the true effectiveness of the 
treatment proposed, specially the importance of the 
differentiation of deeper and shallower NCCLs. 

This study is limited as it presents results of 
one clinical case in the short term and a non-
destructive evaluating method (FEA), that considers 
homogeneous and static models, that do not 
represent the actual clinical situation. However, it 
presents a new approach for more complex 
evaluations in the area. Further clinical studies with 
the variables determined in this work should be 
carried out to further elucidate the subject. 
 
CONCLUSIONS 

 
The restorative decision for premolars with 

NCCLs that are going to receive veneers should 
consider the biomechanical behavior and, 
especially, the necessary tooth structure wear.  

For the case report presented, after two 
years of follow-up, no changes from the immediate 
result were observed, indicating that the cause of the 
lesions was eliminated, and that the treatment was 
effective, at least in the short-term.  

Restoring the premolar’s deeper NCCL with 
a composite resin core, prior to ceramic veneer 
impression, presented better mechanical behavior in 
FEA and less tooth wear. For the 1.0 mm NCCL, 
beveling the lesion promoted good stress 
distribution, less invasive wear and an easier clinical 
procedure because it did not involve a restorative 
procedure.  

 
 
RESUMO: Na reabilitação com facetas cerâmicas, dentes com lesões cervicais não cariosas (LCNC), 

especialmente pré-molares, estão frequentemente envolvidos. O preparo para remover a LCNC pode levar a um 
desgaste excessivo e a uma abordagem menos conservadora, o que vai contra os princípios atuais de mínimo 



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desgaste e máxima preservação. Entretanto, não existem evidências indicando qual técnica pode evitar o 
desgaste excessivo durante o preparo para facetas associado com LCNC. Portanto, esse artigo tem dois 
objetivos principais: 1) apresentar um tratamento estético com facetas cerâmicas e acompanhamento de 24 
meses de um paciente com vários níveis de severidade de LCNC e 2) avaliar vários protocolos de preparo para 
facetas cerâmicas associadas com LCNC por meio do Método de Elementos Finitos (MEF) para guiar e 
justificar a decisão clínica do caso clínico descrito. Um paciente de 37 anos, gênero masculino, compareceu 
para tratamento com desgaste nos dentes anteriores e com LCNC com vários graus de severidade nos dentes 
posteriores. Optou-se pela reabilitação com facetas cerâmicas nos dentes 15 a 25. A melhor abordagem 
restauradora para os dentes com LCNC foi avaliada por MEF, simulando vários protocolos e profundidades de 
lesão, além disso foi calculada a porcentagem de estrutura dental perdida. Restaurar a LCNC profunda de um 
pré-molar com um núcleo de resina composta, antes da moldagem para faceta cerâmica, apresentou melhor 
comportamento mecânico em MEF e menos desgaste dental. Para a LCNC de 1 mm, biselar a lesão promoveu 
boa distribuição de tensões, um desgaste menos invasivo e um procedimento clínico mais fácil, já que não 
envolveu um procedimento restaurador prévio. Pode-se concluir que a decisão restauradora para pré-molares 
com LCNC que irão receber facetas deve considerar o comportamento biomecânico do conjunto e, 
principalmente, o desgaste de estrutura dental necessário. Para o caso apresentado, após 2 anos de 
acompanhamento, nenhuma mudança foi observada, indicando que a causa das lesões foi eliminada, e que o 
tratamento foi efetivo, ao menos no curto prazo. Para MEF, restaurar a LCNC antes da moldagem para facetas, 
apresentou melhor comportamento mecânico e menor desgaste dentário. Para a LCNC de 1,0 mm, fazer o bisel 
na margem da lesão levou aos mesmos bons resultados. 

 
PALAVRAS-CHAVE: Desgaste dos dentes. Facetas dentárias. Análise de elementos finitos. 
 
 

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