Among other factors, types of bisphosphonates and treatment regimens seem to be strongly 
associated with the success or failure of installation of osseointegrated implants. This 
study investigated the influence of two bisphosphonates, sodium alendronate (SA) and 
zoledronic acid (ZA), on the metabolism of osteoblasts. Human osteoblasts (Saos-2) were 
seeded onto machined or acid-treated titanium discs previously placed on 24-well plates 
in complete culture medium. After 24 h, cells were exposed to bisphosphonates at 0.5, 1 
or 5 μM for 24 h, 48 h or 7 days. The effects of SA and ZA on osteoblasts were assessed 
based on the adhesion of these cells to the titanium surfaces by direct fluorescence, cell 
viability, total protein and collagen synthesis. Alkaline phosphatase activity and mineral 
nodule deposition by these cells were also evaluated. Data were evaluated by ANOVA 
and Tukey tests (α=0.05). Decreased adhesion of cells to the titanium discs was observed 
when exposed to both bisphosphonates; however, this lack of cell adhesion was more 
evident for ZA-treated cells. In addition, the exposure of osteoblasts to ZA decreased 
the viability, ALP activity and mineral nodule deposition, which may be related to poor 
osseointegration after implant installation.

Inf luence of  Bisphosphonates 
on the Behavior of Osteoblasts 
Seeded  On to  T i t an ium D i s c s

Fernanda G. Basso1 , Taisa N. Pansani2 , Lais M. Cardoso2 , Josimeri 
Hebling2 , Rodrigo Paes Vila Real1 , Carlos Alberto de Souza Costa2 

1School of Dentistry, UNAERP - 
Universidade de Ribeirão Preto, 
Ribeirão Preto, SP, Brazil
2Araraquara School of Dentistry, 
UNESP - Universidade Estadual 
Paulista, Araraquara, SP, Brazil

Correspondence: Fernanda Gonçalves 
Basso, Avenida Costábile Romano, 
2201, 14096-900 Ribeirão Preto, 
SP, Brasil. Tel: +55-16-3603-6780. 
e-mail: fergbasso@gmail.com

Key Words: bisphosphonates, 
implantology, osseointegration, 
osteoblasts.

Brazilian Dental Journal (2020) 31(3): 304-309
http://dx.doi.org/10.1590/0103-6440202003128 ISSN 0103-6440

Introduction
Several drugs have been related to the development 

of maxillofacial osteonecrotic lesions (1,2), such as anti-
resorptive drugs and antiangiogenic drugs. For this reason, 
this condition is currently described as medication-related 
osteonecrosis of the jaw (MRONJ) (1).

Among the anti-resorptive drugs, bisphosphonates 
have been extensively related to the development of this 
pathological condition (1,3,4). These drugs are pyrophosphate 
analogues and present a high affinity for hydroxyapatite 
crystals, where approximately 80% accumulate after 
intake. Bisphosphonates are recommended for patients with 
underlying diseases that lead to unbalanced bone remodeling, 
such as osteoporosis and bone metastatic tumors (5). 

After a traumatic or inflammatory condition, these 
drugs are released from bone for months or even years. 
Once released, bisphosphonates act by inhibiting the 
maturation of pre-osteoclasts into osteoclasts, through the 
RANK-RANKL pathway, and also by inducing the apoptosis 
of osteoclasts via the mevalonate pathway (6). However, 
these drugs show poor specificity and may also harvest 
other cell lines, such as osteoblasts (6).

Previous studies have demonstrated that the inhibitory 
effects of bisphosphonates on osteoblasts could be related to 
the development of bisphosphonate-related osteonecrosis 
of the jaws (7-9). The incidence of osteonecrotic areas in 

the oral cavity following bisphosphonate treatment is 
related to the type of drug, frequency, dose and method 
of administration (7-9). For this reason, high-potency 
bisphosphonates such as zoledronate and the intravenous 
administration of such drugs are listed as being more 
predictive of the development of osteonecrosis (7-9). 
Among local factors, inflammatory and infectious conditions 
including trauma are also listed as predisposal factors for 
the development of areas of osteonecrotic bone (8). 

Due to the risk of development of osteonecrosis, the 
insertion of oral osseointegrated implants for patients under 
bisphosphonate treatment remains controversial (1,2,10), 
with different outcomes being described in the current 
literature (1,2,10). Among other factors, these variable 
outcomes seem to be related to the type and concentration 
of bisphosphonate used. However, the cellular and molecular 
events associated with the clinical success or failure of the 
insertion of dental implants for these patients have not 
been completely elucidated.

This study aimed to determine the roles of different 
concentrations of two bisphosphonates on the behavior of 
human osteoblasts seeded onto titanium surfaces. 

Material and Methods
Titanium Discs

Commercially pure titanium discs (grade IV, 13 x 1.5 

https://orcid.org/0000-0002-7170-2371
https://orcid.org/0000-0002-5931-6849
https://orcid.org/0000-0002-9886-8590
https://orcid.org/0000-0002-2846-2325
https://orcid.org/0000-0002-3979-304X
https://orcid.org/0000-0002-7455-6867


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mm) were ground wet with 400-, 600- and 1200-grit silicon 
carbide paper (3M do Brasil, Sumaré, SP, Brazil) to obtain 
standardized machined surfaces. For acid-treated surfaces, 
discs were treated with 10% hypochloric acid in deionized 
water. The surface roughness of both machined and acid-
treated discs was evaluated by confocal microscopy (ULS 
4000, Olympus Corporation, Center Valley, PA, USA). Then, 
discs were ultrasonically cleaned in 95% ethanol and 
deionized water and sterilized in an autoclave.

Cell Culture and Bisphosphonate Treatment
Before cells were seeded, titanium discs were allocated 

into wells of a 24-well cell culture plate. Then, 1 mL of 
Dulbecco’s Modified Culture Medium (DMEM, Gibco, 
Carlsbad, CA, USA), containing 1% of antibiotic solution 
(PenStrep, Gibco) and supplemented with 10% of fetal 
bovine serum (FBS), was applied to each well. Human 
osteoblasts (SaOs-2-ATCC #HTB85) were seeded onto each 
disc (5 x 104 cells/disc).

After 24 h, the culture medium was replaced by fresh 
serum-free DMEM containing different concentrations 
of each bisphosphonate, sodium alendronate (SA) or 
zoledronic acid (ZA) (0, 0.5 μM, 1 μM or 5 μM). This culture 
medium was supplemented with betaglycerophosphate 
and ascorbic acid (osteogenic medium) (Sigma-Aldrich, 
St. Louis, MO, USA). The doses of bisphosphonates were 
selected according to a study of Schepper et al. (11), 
which comparatively demonstrated the concentrations of 
bisphosphonates found in the oral cavity of patients under 
treatment with these drugs. Also, these concentrations were 
already evaluated in previous investigations of the group. 

Cells were treated for 48 h or 7 days, according to the 
selected protocols, and culture medium containing the 
drugs was replaced every 48 h. 

Cell Adhesion - Fluorescence
The adhesion of osteoblasts was also qualitatively 

and quantitatively assessed by fluorescence, with 
a cytoskeleton marker used for actin (Actin Probe, 
Molecular Probes, Carlsbad, CA, USA). Cells were fixed 
in 4% paraformaldehyde, subjected to permeabilization 
with 0.1% triton-x and incubated with the actin probe 
for 30 min in the absence of light. Nuclei were identified 
by incubation with a DNA intercalant (Hoechst - 1:5000) 
for 15 min. Then, samples were analyzed by fluorescence 
microscopy (EVOS FL Image System, Thermo Fisher 
Scientific, Waltham, MA, USA).

Cell Viability
The effects of bisphosphonates on osteoblasts were 

determined by the MTT assay, which provides the detection 
of the activity of a mitochondrial enzyme (succinic 

dehydrogenase), which corresponds to the metabolic cell 
rate. Cells were incubated with MTT solution (5 mg/mL in 
PBS) diluted at 10% in serum-free culture medium for 4 
h at 37oC and 5% CO2. After this period, 200-μL aliquots 
were transferred to a 96-well plate, and absorbance was 
determined by spectrophotometry at 570 nm (Synergy H1, 
BioTek, Winooski, VT, USA).

 
Total Protein Production and ALP Activity

Total protein production was determined by the Lowry 
colorimetric method and analyzed by spectrophotometry 
(655 nm). The protein production was used to determine 
the metabolism of cells as well as to normalize the ALP 
activity for each sample. ALP activity was assessed by end-
point assay based on the breakage of thymolphthalein 
and was evaluated by absorbance rate at 540 nm 
(Synergy H1).

Mineral Nodule Formation
The deposition of mineral nodules was evaluated by the 

Alizarin Red Method. Cells were fixed in 70% ethanol at   
4 °C for 1 h, after which mineral nodules were detected by 
alizarin red staining (40 mM) for 20 min under agitation. 
Then, samples were washed in deionized water, and, to 
facilitate quantitative analysis of mineral deposition, 
nodules were dissolved in cetylpyridinium (10%) for 15 
min under agitation. After this procedure, a purple solution 
was obtained and subjected to absorbance analysis at 562 
nm (Synergy H1).

Collagen Synthesis
Soluble collagen produced by osteoblasts was evaluated 

by the Sirius Red method, using the culture medium that 
remained in contact with cells (culture medium from all 
periods was stored at -20 °C). A 500-μL quantity of the 
culture medium of each sample was transferred to a 1.5-mL 
tube followed by the addition of Direct Red reagent at 1%. 
Samples were incubated for 1 h at room temperature under 
agitation (400 rpm; Thermomixer, Eppendorf, Hamburg, 
Germany). Then, samples were centrifuged at 12,000 rpm 
for 10 min. The supernatant fraction was discarded, and 
pellets were washed in hydrochloric acid (0.1 M) followed 
by centrifugation. After supernatant was discarded, pellets 
were re-suspended in sodium hydroxide (0.5 M) and were 
aliquoted to 96-well plates. Absorbance was determined 
by spectrophotometry at 555 nm (Synergy H1).

Statistical Analysis
The resulting data presented normal distribution 

(Shapiro-Wilk test, p<0.05); therefore, parametric tests 
(ANOVA and Tukey) were applied for statistical analysis. 
All statistical inferences were based on 5% as significant. 



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Results
Cell viability was not significantly affected when 

osteoblasts were exposed to bisphosphonates at all 
concentrations for 24 and 48 h (p>0.05) (Fig. 1A, 1B). 
However, after a 7-day period of continuous treatment, 
cells seeded onto titanium discs treated with ZA showed 
diminished viability for all concentrations (p<0.05) (Fig. 
1C). The cytotoxicity was higher as ZA concentrations 
were increased regardless of the type of titanium surface 
(machined or acid-treated discs) (p<0.05). For SA-treated 
cells, no significant effect on viability of human osteoblasts 
was observed (p>0.05). In contrast, at the 7-day period, 
cells seeded onto acid-treated titanium surfaces showed 
higher viability after SA treatment (p<0.05).

The adherence of osteoblasts to titanium surfaces 
was negatively affected by ZA at all concentrations used; 
however, the adhesion of SA-treated cells was hampered 
only at the highest concentration tested, as observed for 
the qualitative analysis by fluorescence (Fig. 2).

Despite decreased cell viability, collagen synthesis was 
not affected by treatment with both bisphosphonates 
(p>0.05) (Fig. 3A). Decreased total protein synthesis (Fig. 
3B) and ALP activity (Fig. 3C) were observed for ZA-treated 
cells seeded onto both types of titanium discs (p<0.05), 
in a concentration-dependent way. These cell activities 
were also negatively affected by SA, mainly at higher 
concentrations (p<0.05).

Decreased mineral nodule formation was observed for 
osteoblasts exposed for 7 days to both bisphosphonates 
(p<0.05); this effect was more intense as the concentrations 
of these drugs increased (Fig. 3D). Significant differences 
were observed when cells were seeded onto machined and 
acid-treated discs (p<0.05). 

Overall, for cells treated with the selected 
bisphosphonates, rougher surfaces did not provide a better 
environment for cell attachment or phenotype. 

Discussion
The insertion of oral implants for patients under 

bisphosphonate treatment has led to distinct clinical 
outcomes (1,2,10). Previous clinical reports and reviews 
demonstrated that these clinical procedures may result in 
successful prosthetic rehabilitation; however, some patients 
have experienced implant failure and development of 
osteonecrotic areas on maxillary bones (1,2,10). The distinct 
outcomes may be related to the patients’ underlying disease 
requiring bisphosphonate treatment, while this factor may 
be directly related to the type of bisphosphonate, the 
method of administration and doses (12,13). 

It has been shown that, after intake, bisphosphonates 
adhere to hydroxyapatite crystals of mineral tissues, and 
their release can be triggered by a traumatic, inflammatory 

or neoplastic condition that results in bone resorption 
(14). Once released, these drugs mainly inhibit osteoclast 
maturation and induce apoptosis of these cells; however, 
several studies have demonstrated that these drugs also 
show cytotoxic and cytopathic effects on osteoblasts 
(15-18). 

The long-term success of implantation depends on the 
effective osseointegration of titanium implants (19,20). The 
process of osseointegration itself is directly related to the 
adhesion of osteoblasts to titanium surfaces as well as the 

Figure 1. Viability of osteoblasts seeded onto titanium discs and 
treated with bisphosphonates at different concentrations for 24 h (A), 
48 h (B) and 7 days (C). n=6. Bars indicate mean values and standard 
deviation. Groups indicated by different symbols are statistically 
significantly different (Tukey, p<0.05).



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synthesis and mineralization of a collagen-rich matrix by 
these cells (21). Therefore, the adhesion and metabolism 
of osteoblasts to these surfaces, as well as the synthesis of 
collagen matrix and its mineralization, are the main cellular 
events during this process. Hence, the evaluation of these 
cellular and molecular events is crucial to determination 
of the influence of bisphosphonates on oral implantology.

The present investigation evaluated the influence of 
two bisphosphonates and their concentrations on the 
adhesion, viability and metabolism of osteoblasts seeded 
onto titanium surfaces. Results demonstrated that, for 

SA, which is a moderately potent orally administered 
bisphosphonate, slightly negative effects were observed 
in the cultured cells only when the higher concentration 
of this drug was used. Similar results had previously been 
demonstrated for SA at low concentrations; however, that 
may not represent the local concentrations of these drugs 
after months or years of intake (22). The maintenance of 
osteoblast viability and metabolism after SA treatment may 
suggest that the patients under treatment with this type 
of bisphosphonate may not experience negative outcomes 
regarding osseointegration after insertion of oral implants. 

Figure 2. Osteoblasts adhered to the machined and acid-treated titanium surfaces after a 7-day period of treatment with bisphosphonates at 
different concentrations.

Figure 3. Total protein production (A), collagen synthesis (B), ALP activity (C) and mineral nodule formation (D) by osteoblasts seeded onto 
titanium discs and treated with bisphosphonates at different concentrations for 7 days. n=6. Bars indicate mean values and standard deviation. 
Groups indicated by different symbols are statistically significantly different (Tukey, p<0.05).



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Indeed, patients undergoing SA treatment show few adverse 
effects after the insertion of oral implants (1). Still, the 
treatment protocol may directly affect the local release 
of this drug, so these patients must be handled carefully.

Conversely, few osteoblasts exposed to ZA adhered 
to the titanium surfaces, and these cells also showed 
decreased viability and metabolism, demonstrated by ALP 
activity and mineral nodule deposition, which are in vitro 
indicators of the mineralization capacity of these cells. 
The concentrations of bisphosphonates applied during 
this investigation were selected according to previous 
investigations (11,17,18). Therefore, we suggest that the 
presence of high concentrations of this drug may lead to 
poor osseointegration. Again, since the adherence and 
release of ZA can be influenced by several factors, the 
concentrations selected for this study may underestimate 
the concentration at the time of oral implant insertion and 
the effects of this drug on peri-implant tissues.

These results show a high similarity to the outcomes 
observed for in vivo and clinical studies, where patients 
under ZA treatment were the most affected by adverse 
effects following implant insertion, such as peri-implantitis 
and osteonecrotic areas (1,2).

In terms of surface topography, this investigation 
demonstrated that osteoblasts showed higher cell adhesion 
and metabolism when seeded onto the acid-treated 
titanium discs. Similar results have already been described 
in previous studies, in which the authors demonstrated that 
these cells exhibited higher viability and metabolic activity 
when seeded onto rough titanium surfaces compared with 
plain surfaces (23). 

However, in the present investigation, the osteoblasts 
demonstrated the same response to bisphosphonate 
treatment, suggesting that the implant surface may not 
play a fundamental role in the insertion of oral implants 
in patients under treatment with these drugs. These results 
also demonstrate that the use of acid-treated surfaces may 
not be a suitable strategy to improve osseointegration for 
patients receiving bisphosphonate treatment. 

Resulted data highlight the negative influence of 
zoledronic acid on osteoblasts seeded in this condition, 
demonstrated by decreased cell adhesion and metabolism 
when cells were exposed to this drug. Considering the 
limitations of this study, these effects may be associated 
to the negative outcomes observed for the installation of 
oral implants in patients with present or previous history 
of treatment with zoledronic acid. Thus, these results also 
bring to light the necessity of treatment strategies that can 
improve the interaction and metabolism of bone cells and 
also improve the sensitivity of these cells to the contact 
with bisphosphonates, mainly zoledronic acid. 

Resumo
Entre outros fatores, os tipos de bisfosfonatos bem como os regimes 
de tratamento parecem estar diretamente associados com o sucesso ou 
falhas na instalação de implantes osseointegrados. Este estudo avaliou 
a influência de dois bisfosfonatos, o alendronato de sódio (AS) e o ácido 
zoledrônico (AZ), no metabolismo de osteoblastos. Osteoblastos humanos 
(Saos-2) foram cultivados sobre discos de titânio polidos ou submetidos 
a tratamento ácido superficial, previamente alocados em placas de 24 
compartimentos, utilizando meio de cultura completo. Após 24 horas, 
as células foram expostas aos bisfosfonatos, nas concentrações de  0,5, 
1 ou 5 μM, por 24 h, 48 h, ou 7 dias. Os efeitos do AZ e AZ sobre os 
osteoblastos foram determinados considerando a adesão destas células 
às superfícies de titânio, por meio de fluorescência direta, a viabilidade 
celular, produção de proteína total e síntese de colágeno. A atividade 
de fosfatase alcalina e a deposição de nódulos mineralizados também 
foram avaliadas. Os dados foram analisados por meio do teste ANOVA 
complementado por Tukey (α = 0.05). Menor adesão dos osteoblastos foi 
observada quando estas células foram expostas a ambos os bisfosfonatos, 
porém, esta falha na adesão foi mais evidente para as células tratadas 
com AZ. Além disso, a exposição dos osteoblastos ao AZ também resultou 
em diminuição da viabilidade, atividade de ALP e deposição de nódulos 
mineralizados, o que pode estar relacionado a uma pobre osseointegração 
após a instalação do implante.

Acknowledgements 
The authors acknowledge the Conselho Nacional de Desenvolvimento 
Científico and Tecnológico - CNPq (grants: #442637/2014-4; 157779-
2015-7; 302108/2019-0) and São Paulo Research Foundation (FAPESP # 
2018/11211-6) for the financial support.

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Received October 29, 2019
Accepted June 10, 2020