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Original Article 

Biosci. J., Uberlândia, v. 33, n. 3, p. 815-823, May/June. 2017 

POLYLACTIC/POLYGLYCOLIC ACID COPOLYMER IS A GOOD CARRIER 

FOR BMP-2 ON BONE REGENERATION? 
 

COPOLÍMERO DO ÁCIDO POLILÁTICO/POLIGLICÓLICO É UM BOM 
CARREADOR PARA BMP-2 NA REGENERAÇÃO ÓSSEA? 

 
Alexandre Ladeira Veloso dos ANJOS

1
; Roble Casares PEREZ

1
; Bárbara Maciel BRAGA

2
; 

Mariza Akemi MATSUMOTO
3
; Roberta OKAMOTO

3
; Patrícia Pinto SARAIVA

1
;  

Andréia Aparecida da SILVA
1
; Thiago Amadei PEGORARO

1 

1. Pró-reitoria de Pesquisa e Pós-Graduação, Universidade do Sagrado Coração, Bauru, SP, Brasil; 2. Centro de Ciências da Saúde, 
Universidade do Sagrado Coração, Bauru, SP, Brasil; 3. Departamento de Ciências Básicas, Universidade Estadual Paulista “Júlio de 

Mesquita Filho”, Araçatuba, SP, Brazil. ppbau@uol.com.br 
 

ABSTRACT: The aim of this work was to evaluate the role of polylactic /polyglycolic acid copolymer as 
carrier for BMP-2 on bone regeneration in rat calvarium. Forty five adult male rats underwent 5-mm critical defects in 
bone calvaria to be divided into three groups according to the filling materials: Control-blood clot; PLGA-polylactic acid 
Polyglycolic/copolymer; PLGA + BMP-2 -polylactic acid Polyglycolic/copolymer associated with BMP-2. Sacrifice of 
animals occurred at 5, 15 and 30 days after surgery The evaluation of new bone formation was obtained by 
histomorphometry, while OPG and RANKL proteins were observed by immunohistochemistry. Statistical analysis was 
performed by means of nonparametric tests based on quantitative variables of independent samples. Considering the 
amount of newly formed bone, significant difference was detected between PGLA (178,2±137,5µ m) and the other groups, 
at day 30. In PLGA + BMP-2 and control groups, the expression of RANKL was prevalent on the OPG in the periods of 
15 and 30 days, suggesting a favorable condition for bone reabsorption in these periods. Therefore, immunoexpression of 
RANKL and OPG and bone formation observed in different groups and periods of analysis showed that the 
polylactic/polyglycolic acid copolymer does not act as a good carrier for BMP-2. 

 

KEYWORDS: Bone tissue. Osteoprotegerin. RANKL. Immunohistochemistry. 
 

INTRODUCTION 
 

Bone morphogenetic proteins (BMPs) are 
known due to the satisfactory results in bone 
regeneration. In addition, BMPs are required for the 
maintenance of bone homeostasis in adulthood, as 
they maintain stem and osteoprogenitor cells niches 
(SCHMOEKEL et al., 2005). 

Although BMP-2 is recognized as one of the 
most effective treatments for inducing bone 
formation (YAMAMOTO et al., 2003), there is 
evidence that the BMPs may reduce bone mass 
through induction of osteoclastogenesis activation 
(ITOH et al., 2001). 

The treatment of osteoblastic cells with 
BMP-2 or RANKL results in the formation of 
tartrate-resistant acid phosphatase positive 
multinucleated cells (TRAP), indicating the 
formation and activation of cells responsible for 
resorption (GRANHOLM et al., 2013). On the other 
hand, in the absence of osteoblasts, BMP-2 appears 
to increase directly the formation and survival of the 
osteoclasts (TOTH et al., 2009). 

The recognition of the effect of BMP-2 on 
the activation of osteoclasts also has some 
divergences, indicating that its action is dependent 
on the concentration of BMPs used (ITOH et al., 

2001). In small local concentrations, BMP-2 induces 
the formation of bone tissue, and its excess is not 
desirable due to adverse effects such as induction of 
immunological response (CHUANG et al., 2010). 
The carrier can modify the availability of this 
protein, leading to a better use of the substance by 
bone tissue (ITOH et al., 2001). Several techniques 
have been employed to control the release of growth 
factors (GF). Some of these techniques involve the 
encapsulation of the GFs with biodegradable 
polymers, which are broken down by promoting the 
slow release of these factors (BLACKWOOD et al., 
2012). 

Some types of carriers present polyesters in 
their composition since it provides better control in 
their process of degradation. The polylactic 
/polyglycolic acid copolymer (PLGA) is widely 
used due to its biodegrading rate, which is 
compatible with tissue remodeling (DANIELS et al., 
1990).  

Based on the characteristics of these 
materials, the aim of this study was to evaluate 
PLGA as a carrier for BMP-2 on bone regeneration 
and its influence on RANKL/OPG ratio.  
 
 

Received: 31/10/16 
Accepted: 20/02/17 



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MATERIAL AND METHODS  
 

This study was approved by the Ethical 
Committee for Animal Care of Sagrado Coração 
University (protocol n° 8224140515). All 
experimental protocols involving animals’ 
management were carried out in accordance with 
the Principals of laboratory animal care (NIH), as 
well as of Brazilian Society of Laboratory Animal 
Science (COBEA). Forty-five male adult albinus 
Wistar rats, mean weight of 300 g, 2 months of age, 
underwent surgical confectioning of critical bone 
defects (5 mm in diameter) in their calvarial bone to 
be distributed in four groups, according to the filling 
materials, as follows: a) blood clot - control group; 
b) Polylactic /polyglycolic acid copolymer powder 
(Fisiograft®-Ghimas SPA, Italy) – PLGA Group; c) 
Polylactic /polyglycolic acid copolymer associated 
with BMP2 – PLGA+BMP-2 Group.  (PLGA plus 
5µg BMP-2 (R&D Systems, Inc., Minneapolis, MN, 
USA). After the addition of BMP-2 on the PGLA, 
mixing the components was immediately placed in 
the bone defect). 

 
Surgical procedures 

For the bone defects procedures, the animals 
were anesthetized with intramuscular ketamine (75 
mg/kg) and xylazine (10 mg/kg), and infiltration of 
local anesthetic with 2% mepivacaine with 
1:100.000 epinephrine (Scandicaine, Septodont, 
France), for hemostasis of the operative field. 

After trichotomy of the animals’ head and 
antisepsy with 1% polyvinylpyrrolidone, a linear 
longitudinal dermoperiostal incision at the 
calvarium was performed, in order to expose bone 
tissue. One defect was performed using a 5-mm 
diameter trephine bur (3i Implant Innovations, Inc., 
Palm Beach Gardens, Florida, USA) in the left side 
of the parietal bone under copious irrigation with 
0.9% saline solution (Darrow, Rio de Janeiro, 
Brazil), and filled with the above mentioned 
materials. 

The tissues were repositioned and sutured 
with nylon (Nylon 5.0, Mononylon, Ethicon, 
Johnson Prod, São José dos Campos, Brazil). 
Immediately after the surgery, the animals were 
given a single dose of Tramadol (5 mg/kg, IP). 

 
Histological Analysis  

After 5, 15 and 30 days, the animals were 
sacrifice by means of intraperitoneal injection of 
barbiturates (Thiopental), at a dose of 150 mg/kg, in 
association with lidocaine (10 mg/mL). The 
specimens were removed and immediately fixed in 
10% formalin for 48 hours and demineralized in 

4.7% EDTA, pH7, for 28 days (Merck, Darmstadt, 
Germany).  Five micrometers semi-serial coronal 
slices from the inner center of the circular defects 
were collected to be stained with hematoxylin and 
eosin (HE) and for immunohistochemistry.  

 
Histomorphometric analysis 

Four 40x magnification fields correspondent 
to the central area of the defects from each sample 
were  captured and registered by light microscope. 
The newly formed bone matrix quantification 
(Dempster et al., 2013) was accomplished using 
Image J software r 1.46 (developed by Wayne 
Rasband, National Institutes of Health, Bethesda, 
MD), using a 3000 pixels template containing 225 
non-coincident points. Only the points coincident 
with the bone matrix were considered.  
 
Immunohistochemical analysis 

Paraffin was removed with xylene from 
serial sections which were rehydrated in graded 
ethanol, and then pre- treated in a microwave with 
0.01 M citric acid buffer (pH 6) for three cycles of 5 
min each at 850 W for antigen retrieval. The 
material was preincubated with 0.3 % hydrogen 
peroxide in phosphate-buffered saline (PBS) 
solution for 5 min for inactivation of endogenous 
peroxidase and then blocked with 5% normal goat 
serum in PBS solution for 10 min. The specimens 
were then incubated with anti-OPG (P-17) 
polyclonal primary antibody (Santa Cruz 
Biotechnology, Santa Cruz, CA, USA) at a 
concentration of 1:100 or anti-RANKL (c-20) 
polyclonal primary antibody (Santa Cruz 
Biotechnology, Santa Cruz, CA, USA) both at a 
concentration of 1:100. Incubation was carried out 
overnight at 4°C in a refrigerator. This was followed 
by two washes in PBS for 10 min. The sections 
were then incubated with biotin-conjugated 
secondary antibody anti-rabbit IgG (Vector 
Laboratories, Burlingame, CA, USA) at a 
concentration of 1:200 in PBS for 1 h. The sections 
were washed twice with PBS, followed by the 
application of a preformed avidin–biotin complex 
conjugated to peroxidase (Vector Laboratories, 
Burlingame, CA, USA) for 45 min. The bound 
complexes were visualized by application of a 0.05 
% solution of 3–30-diaminobenzidine solution and 
counterstained with Harris hematoxylin. For control 
studies of the antibodies, the serial sections were 
treated with rabbit IgG (Vector Laboratories, 
Burlingame, CA, USA) at a concentration of 1:200 
in place of the primary antibody. Additionally, 
internal positive controls were performed with each 
staining bath. 



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The determination of immunolabeling levels 
for each antibody was  performed  semi-
quantitatively,  using  scores from   1   to   4   
(1=absent,   2=weak,   3=moderate, 4=intense) 
(PEDROSA JUNIOR et al., 2009).  The analysis 
was performed in 5 fields of the interface area, at a 
40x magnification  optical  microscope  (Nikon—
Eclipse  80i,  Tokyo, Japan),  by  two  calibrated  
evaluators  in  a  double-blind system. 

Bone histomorphometry data were assessed 
using the variance analysis test Levene’s test, 
followed by the analysis of independent samples by 
Mann–Whitney test. Immunohistochemistry data 
were assessed using the variance analysis Levene’s 
test, followed by the independent samples t-Student 
or Mann–Whitney tests, which were used in order to 
detect differences between control and NSAID 
groups for the same period and graft. After, the 
statistical difference among the periods for each 
group and protein was determined by ANOVA and 
Kruskal–Wallis non-parametric test, or ANOVA 
and Tukey test, according to the variance 

homogeneity. The level of statistical significance 
was set at 0.5 %. 

 

RESULTS 
 
Morphological microscopic analysis 

In all groups, it was not observed the 
formation of new bone after 5 days. In this period, 
in all groups it could be noted the formation of scar 
tissue in the area of the defect, being the PLGA and 
PLGA+BMP-2 groups possible to notice the 
presence of biomaterial, surrounded by an 
inflammatory process. In the period of 15 days, the 
control group presented newly formed tissue in the 
connective tissue area of the defect, but a small 
amount of bone tissue formed in the margin. This 
margin area presents itself lined with osteoblasts 
and few reverse lines. At 30 days it could be noted 
an increase in the production of bone matrix, with 
medullar characteristic and intense vascularization 
(Figure 1, A-B).  

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
 

 
 
 

 
Figure 1. New bone formation was observed between the healing connective tissue at 15 days (A) and defect 

margin (B), with few lines of reversion lines. New bone formation (BF) was observed on the margins 
of the defect, with the presence of reverse lines (arrows), at 15 and 30 days in the PLGA group (C, 
D). In the PLGA+BMP-2 group, new bone formation (BF) and remnants of the implanted material 
(*), both at 15 and 30 days (E, F) could be noted. Staining with H.E. 

 



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At 15 days, the PLGA group showed newly 
formed immature bone tissue on the defect, and 
rollback lines indicating a remodeling process. At 
30 days it could be noticed in the bone tissue 
formed, features of the organization of osteocytes 
around blood vessels. It was not observed remaining 
of the material in any periods (Figure 1, C-D). In the 
PLGA+BMP-2 Group, it could be noted newly 
immature bone tissue, as well as regions of the 
permanence of the material and inflammatory, 
infiltrate on its margin, in the two periods examined 
(Figure 1, E-F). 

Histomorphometric assessment 
Bone formation (B) in the region of defect 

has not been verified at 5 days. At 15 days B 
presented a similar pattern between the control and 
the other groups (PLGA and PLGA+BMP-2) in all 
periods, with no statistically significant differences 
(p>0.05). However, a difference (p<0.05) was 
detected in the period of 30 days between the PLGA 
group (178.2 ± 137.5) and control group (8.2 ± 7.7) 
and PLGA+BMP-2 group (4.8 ± 10.7) (Table 1). 

 
Table 1. Statistical results from histomorphometric evaluation of calvarial bone 

Periods Bone (µ m) 
Control 

Bone (µ m) 
 PLGA  

Bone (µ m) 
PLGA+BMP-2 

15 days 15,2±15,5aA 56,2±51,2aA 8,6±15,6aA 

30 days 8,2±7,7aA 178,2±137,5bA 4,8±10,7aA 

Different lowercase letters indicate statistical difference (p < 0.05) between groups (rows). No significant statistical differences detected 
(p>0.05) between the periods in each group, indicated by uppercase letters (columns). In the period of 5 days not observed formation of 
bone tissue. 
 
Immunohistochemistry 

Semi-quantitative analysis of the scores 
assigned to each protein markers analyzed (OPG 

and RANKL) is shown in Table 2. The statistical 
analysis carried out among the treatments occurred 
based on the different periods examined. 

 
Table 2. Semi-quantitative analysis for OPG and RANKL 

Tretments OPG RANKL 

5 days 

Control +++ + 

PLGA + + 

PLGA+BMP-2 + - 

15 days 

Control + +++ 

PLGA +++ + 

PLGA+BMP-2 + ++ 

30 days 

Control - + 

PLGA +++ - 

PLGA+BMP-2 ++ +++ 

Semi-quantitative analysis scores, ranging from "-" to the absence of the immunoexpression to “+, ++, +++" for weak, moderate and 
intense, respectively.  
 

At 5 days, the expression for OPG (Figure 
2) predominated in control and was significantly 
different from the other groups (p<0.05), in which 
the expression was weak. At 15 days the 
PLGA+BMP-2 and control groups show similar 
expression (p>0.05) but differed significantly 

(p<0.05) to the PLGA group, which presented the 
highest immunoexpression. At 30 days the 
expression of OPG in the PLGA group was intense 
(p<0.05) detected in the period, moderate in the 
PLGA+BMP-2 group, and absent in the control 
group. 

 



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Figure 2. Immunohistochemistry expression for OPG observed in bone matrix (arrows) of the control group at 

5 days (a). At 15 days, at the matrix, there was expression of the osteocytes (b), and at 30 days the 
expression was absent (c). For the PLGA group expression was weak in the matrix at 5 days (d). At 
15 and 30 days, expression occurred on matrix and osteocytes, with moderate intensity (e-f). The 
PLGA+BMP-2 group presented weak expression at 5 and 15 days in bone matrix (g), and in the 
matrix and osteocytes (h), respectively. At 30 days the expression becomes moderate (i).  40x 
magnification. 

 
For the RANKL (Figure 3), in the period of 

5 days, the expression in the PLGA and control 
groups was similar (p>0.05), and in the 
PLGA+BMP-2 group was absent. In PLGA + BMP-
2 and control groups, the markup of RANKL was 
prevalent on the OPG in the periods of 15 and 30 

days At 30 days, the immunoexpression in the 
PLGA group was absent. 

 

 
 
 
 
 
 
 

 

 

 

 
 

 

 

 

 

 
 

Figure 3. Immunohistochemistry expression for RANKL in the control group, at 5 days (a) was weak in bone 
matrix, becoming intense at 15 days, with expression at the bone matrix and osteocytes at 15 (b) and 
30 days (c), with intense and weak expression, respectively. In the PLGA group expression occurred 
only in the bone matrix, at 5 (d) and 15 days (e), with weak expression. At 30 days (f) there was no 
expression. The PLGA+BMP-2 group, at 5 days, there was no expression (g). In 15 days, the 
expression occurred in the array and osteocytes moderately, becoming intense to 30 days (i), only in 
the matrix. 40x magnification. 

 



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DISCUSSION 

 
This work aimed to evaluate the behavior of 

polylactic/polyglycolic acid copolymer as a carrier 
for the growth factor BMP-2, in the process of bone 
regeneration. However, it was noted that the 
association of PLGA to BMP-2 showed worst 
results when compared to the use of PLGA alone.  

The use of biomaterials that are associated 
with growth factors may help the healing process, 
being of fundamental importance to new bone 
formation (GAUTSCHI et al., 2007). Based on this 
concept, several biomaterials should be tested to 
evaluate their function as protein carrier. The choice 
of the materials for this study is justified by PLGA 
characteristics of biodegradability compatible with 
bone remodeling, and the BMP-2 act directly in the 
osteoblast differentiation (SEEHERMAN et al., 
2005). 

Although BMP-2 report good results in 
bone formation, its half-life is of about 6 to 7 
minutes in non-human primates, due to enzyme 
degradation and rapid rate of depuration (SAITO & 
TAKAOKA, 2003). Thus, to increase their 
effectiveness, BMPs must be combined with 
biocompatible vehicles as carriers to allow their 
gradual release over time. 

Between the various types of biodegradable 
polymers available, poly-alpha hydroxyl acids, such 
as PLA, PGA, and their copolymer PLGA, have 
emerged as a choice to act as carriers (YASUDA et 
al., 1998). 

In this study, critical bone defects were 
performed in calvarial bone of rats, so that there was 
no ability of spontaneous bone regeneration. These 
defects were filled by the clot, PLGA and PLGA 
associated with BMP-2, observed after 5, 15 and 30 
days.  

For verification of bone tissue activity, 
OPG/RANKL ratio was analyzed. The study of 
bone tissue resorption may occur by monitoring the 
proteins that actively participate in the activation of 
osteoclasts: the RANK/RANKL/OPG triad. The 
osteoclastogenesis is negatively regulated by OPG, 
which is a host that competes with RANK by the 
connection to RANKL (YASUDA et al., 1998). The 
control of the expression of these proteins provides 
important data for information of cellular activity of 
the target tissue, and consequently, of the repair 
process. 

At day 5, it was not observed the formation 
of new bone tissue from the results obtained from 
morphological and morphometric analysis, but scar 
connective tissue in the defect area. Although it was 
not observed the formation of bone matrix, OPG 

expression was prevalent to the RANKL expression 
on control and PLGA+BMP-2 groups, and remained 
proportional in PLGA group. Therefore, in this 
initial phase of the repair process, the use of carrier 
+ BMP-2 showed no difference from the control 
group. In this period it is still possible to view the 
presence of PLGA particles, indicating that 
degradation was partial. 

At 15 days it is clear the formation of new 
bone, observed in all groups. RANKL labeling 
observed was predominant in control and 
PLGA+BMP-2 groups indicating osteoclastic 
activation. These data corroborate with 
morphometric data, which shows similar results in 
these two groups. At this stage, the presence of 
reversion lines in control and PLGA groups were 
observed, but were absent in the PLGA+BMP-2 
group. Reversion lines represent bone remodeling 
process, characterizing a process of tissue 
reorganization. This reorganization activity in 
PLGA+BMP-2 group seems to have been late in 
relation to the other groups. 

The results found at day 15 contradicts the 
findings of Pan & Ding (2012), which stressed that 
despite being biocompatible, clinical application of 
PLGA alone disturbes bone regeneration by the lack 
of osteoconductivity. In our study, there was no 
difference in bone formation between PLGA group 
compared to the control group at day 15. Therefore, 
the use of PLGA does not appear to have hindered 
bone regeneration. The group that used the 
association of PLGA + BMP-2 also showed no 
difference in bone formation compared to the 
control group at day 15, although it was still 
possible to notice the presence of PLGA remnants in 
the area of the defect, which was not visible in the 
other treatments. At 30 days, the proteins analyzed 
showed a predominance of RANKL 
immunolabeling at control and PLGA+BMP-2 
groups, while OPG was prevalent in the PLGA 
group. Immunolabeling of these proteins coincides 
with the formation of bone matrix. In the groups 
where RANKL predominated, poorer matrix 
formation was detected. The highest formation of 
bone tissue statistically significant was observed in 
the PLGA group, precisely in which there was a 
predominance of OPG. 

Studies show different behaviors for the 
release of BMP-2, depending on the type of material 
used as a carrier. Kim et al. (2008), showed that the 
association of PLGA coated with apatite with BMP-
2 suspended in fibrin gel showed decreased protein 
release speed and increase in bone formation, in the 
same experimental model of the present study. Their 
results are contrary to ours, because although it still 



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has been observed remnants of PLGA in the long 
term, PLGA did not present improved bone 
formation with the association with BMP-2.  

Oest et al. (2007) also showed the difference 
between the carriers for BMP-2. The authors 
showed that the combination of BMP-2/PLGA with 
natural polymers, such as alginate hydrogel 
increases the femoral bone regeneration in a rat 
model. But the combinations of PLGA with 
synthetic polymers have been shown to decrease the 
rate of release of BMP-2 in vivo. Decreased release 
of BMP-2 can justify a lower control bone 
formation observed in this study. 

Luvizuto et al. (2011) evaluated the 
influence of BMP-2 associated with the PLGA, 
among other biomaterials. As well as in this study, 
they did not observe better results when the growth 
factor has been associated with the PLGA. Another 
study (CHAPPUIS et al., 2012), however, noted 
positive results when there was the association of 
BMP-2 to an allogeneic graft. Therefore, these data 
confirm the inefficiency of PLGA as carrier material 
for bone augmentation. 

Specific reports could also justify the 
absence of positive results when there was the 
addition of BMP-2 to PLGA verified in this 
experiment. ITOH et al. (2001) and GRANHOLM 
et al. (2013) indicate that the activity of BMP-2 can 
be associated with the activation of the 
osteoclastogenesis process. This activity was 

observed in the periods of 15 and 30 days of the 
study, in which the expression of RANKL 
predominated on the OPG. 

The best results for the formation of bone 
tissue on this study took place in the presence of the 
PLGA alone, although other study (LÜ et al., 2009)   
indicate that the polymer, by itself, would be inert, 
and do not promote a biological response in the 
bone tissue.  These data corroborate with the results 
found by Luvizuto et al. (2011) showing that the 
presence of BMP-2 decreases the osteoconductive 
properties of PLGA. 

The comparison between the analyzed 
groups shows that the PLGA increases bone 
formation when used without the association of 
BMP-2. When BMP-2 is incorporated into the 
PLGA, it apparently causes a delay in the healing 
process, rather than improve healing. 

Additional studies in different types of bone 
defects and animal models, must be performed in 
order to attest the effectiveness of the PLGA as 
carrier for BMP-2.  

 
CONCLUSION 

 
The polylactic /polyglycolic acid copolymer 

presents osteoinductive properties; however, does 
not behave properly as a good carrier for BMP-2. 

 

 
 

RESUMO: O objetivo deste estudo foi avaliar o copolímero do ácido polilático/poliglicólico como carreador 
para BMP-2 na regeneração óssea da calvária de ratos. Foram utilizados 45 ratos adultos machos. Defeitos ósseos críticos 
de 5mm de diâmetro foram realizados com uma broca trefina na calvária dos animais. Os animais foram divididos em três 
grupos, de acordo com o material de notas para preenchimento dos defeitos: Controle - coágulo; PLGA - copolímero ácido 
polilático/poliglicólico; PLGA + BMP-2 - copolímero do ácido polilático/poliglicólico associado a BMP-2.  O sacrifício 
ocorreu aos 5, 15 e 30 dias após a cirurgia. A avaliação da neoformação óssea foi obtida por histomorfometria, enquanto a 
análise de marcação para as proteínas OPG e RANKL foi observada por imunohistoquímica. Análises estatísticas foram 
realizadas por meio de testes não paramétricos de variáveis quantitativas em amostras independentes. Com relação à 
quantidade de tecido ósseo neoformado, observou-se diferença estatística significante entre o grupo PLGA 
(178,2±137,5µ m) e os demais, no período de 30 dias. Nos grupos PLGA+BMP-2 e Controle, a marcação de RANKL foi 
predominante sobre a marcação de OPG nos períodos de 15 e 30 dias, evidenciado uma condição favorável para a 
reabsorção óssea nestes períodos. Portanto, a marcação de RANKL e OPG, e a formação óssea observada nos diferentes 
grupos e tempos de análise mostrou que o copolímero de ácido polilático/poliglicólico não atua como um bom carreador 
para BMP-2. 

 
PALAVRAS-CHAVE: Reparo ósseo. BMP-2. Osteoprotegerina. RANKL. Imunohistoquímica. 

 
 
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