1Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

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Effects of strength training 
and raloxifene on femoral neck 
metabolism and microarchitecture 
of aging female Wistar rats
Camila Tami Stringhetta-Garcia1, Samuel Rodrigues Lourenço Morais1, Fernanda Fernandes1, 
Melise Jacon Perez-Ueno1, Ricardo de Paula Almeida1, Mário Jefferson Quirino Louzada1, 
Antonio Hernandes Chaves-Neto1,2, Edilson Ervolino2 & Rita Cássia Menegati Dornelles1,2

The aim of this study was to prevent female osteoporosis using strength training (ST), raloxifene 
(Ral) or a combination of ST plus Ral during the natural female aging process, specifically in the 
periestropause period. For a total of 120 days, aging female Wistar rats at 18-21 months of age 
performed ST on a ladder three times per week, and Ral was administered daily by gavage (1 mg/
kg/day). Bone microarchitecture, areal bone mineral density, bone strength of the femoral neck, 
immunohistochemistry, osteoclast and osteoblast surface were assessed. We found that the treatments 
modulate the bone remodeling cycle in different ways. Both ST and Ral treatment resulted in improved 
bone microarchitecture in the femoral neck of rats in late periestropause. However, only ST improved 
cortical microarchitecture and bone strength in the femoral neck. Thus, we suggest that performing ST 
during the late period of periestropause is a valid intervention to prevent age-associated osteoporosis in 
females.

Annually, there are more than 8.9 million bone fractures due to osteoporosis worldwide1,2. A 240% increase in the 
incidence of worldwide hip fractures is estimated by 20503, along with a 400–700%4 increase of fractures in Latin 
America because of population aging. Osteoporotic fractures result in lengthy hospital stays5, and among these 
fractures, a femoral neck injury is present in 75% of affected women4 and is associated with mortality along with 
varying degrees of morbidities6.

Estrogen deficiency that affects women during menopause is directly related to low bone mass, deteriora-
tion of bone microarchitecture7, associated with increased resorption and changes in the physiological bone 
remodeling cycle8. Steroid stimulating proteins such as receptor activator of NF kappaβ ligand (RANKL) and 
Osteoprotegerin (OPG)9 are crucial to the regulation of osteoclast differentiation, whereas transcription factors 
such as runt-related transcription factor 2 (Runx2)10 are important for osteoblasts. Bone matrix proteins such as 
alkaline phosphatase (ALP), bone sialoprotein (BSP) and osteocalcin (OCN) regulate bone mineralization. With 
the decrease in estrogen concentration, there is an imbalance in this bone signaling cascade: osteoclast survival 
increases, while osteoblast number decreases, and that results in more resorbed bone and less newly formed 
bone with a consequent negative balance in multinucleated basic units (BMUs)11,12. In BMUs, osteoblasts and 
osteoclasts belong to a single temporary structure and the synchronous activities of these cells are essential for 
maintaining bone homeostasis12.

Among the options for the prevention and control of osteoporosis are physical exercise13,14 and medica-
tion14–17. Raloxifene hydrochloride (Ral) is a selective estrogen receptor modulator (SERM) that displays agonist 
activity of the estrogen receptor (ER) in the bone tissue18 and prevents bone loss14. Regarding exercises, strength 
training (ST) is a simple, easily accessible, and cost-effective way to prevent the development of osteoporosis 
due to hypoestrogenism14. Data from our lab showed that ST was able to prevent bone loss in aging ovariecto-
mized rats, evidenced by microstructural, densitometry and biomechanical improvement14, even though there is 

1Programa de Pós-Graduação Multicêntrico em Ciências Fisiológicas, Departamento de Ciências Básicas, Araçatuba, 
16018-805, Brazil. 2Univ Estadual Paulista (Unesp), Faculdade de Odontologia, Departamento de Ciências Básicas, 
Araçatuba, 16018-805, Brazil. Correspondence and requests for materials should be addressed to C.T.S.-G. (email: 
camilatami@foa.unesp.br)

Received: 27 October 2016

Accepted: 19 September 2017

Published: xx xx xxxx

OPEN

mailto:camilatami@foa.unesp.br


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2Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

a decreased ER presence in aged rat bone cells, which could have decreased the cellular response to mechanical 
load and not have avoided the bone deterioration19–21.

Despite evidence of the negative effects of aging in the bones, there are few studies on primary osteoporosis 
that use naturally aged rats, which have a higher bone mass acquired22. Therefore, mechanisms of aging are still 
not entirely clear. Thus, we hypothesized that the damage to bone tissue, frequent in the natural female aging 
process, can be partially reversed with strength training, and that this reversal can be potentiated with the use 
of Ral plus ST. In the present study, we investigated the action of ST and Ral on bone microarchitecture, density, 
strength and proteins of aged rats.

Results
Physiological Parameters. The estrous cycle analysis of 17-month-old Wistar rats showed that the initial 
change that characterizes the period of periestropause in these animals was marked by increased variability in the 
length of the estrous cycle phases, with persistent diestrus lasting 10–12 days longer, with recurrence within 3 or 
4 cycles. After a 120-day intervention, no significant main effects caused by ST or Ral and no significant interac-
tions (ST*Ral) in body weight, uterus weight and estradiol plasma concentration were observed in 21-month-old 
rats (p > 0.05, Table 1).

Measurement of plasma levels of tartrate-resistant acid phosphatase (TRAP) and alkaline 
phosphate activity (ALP). A summary of the plasma bone biomarker levels in each treatment group 
is shown in Fig. 1. Main effects of Ral treatment (NT-Ral, p = 0.0332) and interaction ST*Ral (F(1,21) = 5.638, 
p = 0.0272) was observed in TRAP activity. ALP activity was not affected by treatments.

Femoral neck microarchitecture after ST or Ral treatment. To determine whether ST, Ral or ST*Ral 
could influence the bone microarchitecture of femoral neck we performed micro-CT and evaluated standard 
structural parameters of trabecular bone as well as parameters of cortical bone in this region. The representative 
3D reconstructed micro-CT images and the impact of ST, Ral treatment or ST*Ral for 120 days in femoral neck 
microarchitecture of aging female Wistar are shown in Fig. 2.

The analysis of bone volume fraction (BV/TV) in trabecular femoral neck (Fig. 3) showed significant effects 
after Ral treatment (p = 0.0290) and ST (p = 0.0266), but no interaction was observed. The post hoc analysis 
showed that NT-Ral (p = 0.0359), ST-Veh (p = 0.0338) and ST-Ral groups (p = 0.0243) have higher BV/TV com-
pared to NT-Veh group. ST had main effects on trabecular thickness (Tb.Th), but Ral did not, and no interaction 
between treatment effects was observed. Therefore, ST-Veh group had higher Tb.Th than NT-Veh (p = 0.0041) 
and NT-Ral groups (p = 0.0416). In this study, it was verified an interaction of Ral and ST on trabecular num-
ber (Tb.N; F(1,15) = 42.92, p < 0.0001) and separation (Tb.Sp; F(1,12) = 14.06, p = 0.0028) as well as effects of Ral 
(p < 0.0001 and p = 0.0030) and ST (p < 0.0001 and p = 0.0447) in two way ANOVA analysis. However, no inter-
actions of Ral and ST in Conn.Dn were revealed, although the effect of Ral (p < 0.0001) and ST (p = 0.0003) are 
significant. The pos hoc test showed that Conn.Dn was higher in NT-Ral (p = 0.0039), ST-Veh (p = 0.0238) and 
ST-Ral groups (p < 0.0001) compared to the NT-Veh group. SMI was not affected by treatments.

ST, Ral treatment or ST*Ral for 120 days in femoral neck cortical microarchitecture (Fig. 4) of aging 
female Wistar rats showed that cortical bone area (Ct.Ar) and average cortical thickness (Ct.Th) were affected 
by ST (p = 0.0115 and p = 0.0294, respectively) and by interaction of treatments (F(1,15) = 14.53, p = 0.0017 
and F(1,11) = 8.943, p = 0.0123, respectively). No main effects in NT-Ral group were observed. Furthermore, 
the maximum moment of inertia (Imax) and polar moment of inertia (J) were affected in ST-Veh (p = 0.0010 
and p = 0.0311, respectively) and there was an interaction between ST*Ral (F(1,12) = 16.95, p = 0.0014 and 
F(1,16) = 5.683, p = 0.0299), while no main effects for Ral in NT-Ral group were observed. The minimum moment 
of inertia (Imin) was not affected by treatments.

Femoral neck maximum load and bone mass after ST or Ral treatment. To evaluate whether ST, 
Ral or ST*Ral could influence the bone strength, we assessed areal bone mineral density (aBMD) by dual-energy 
X-ray absorptiometry (DEXA) and maximum load testing measured in femurs (Fig. 5). The Ral treatment 
(p < 0.0001) and ST*Ral interaction (F(1,26) = 10.46, p = 0.0033) affected the bone mass in femoral neck of aging 
female Wistar rats. However, maximum load was affected only by ST (p = 0.0078), no main effects of Ral (NT-Ral) 

Group Final Weight (g) Uterus Weight (g)
Estradiol (pg/
mL)

NT-Veh 377.2 ± 19.93 0.1817 ± 0.005 32.28 ± 1.35

NT-Ral 376.0 ± 11.66 0.1910 ± 0.009 31.87 ± 2.29

ST-Veh 371.3 ± 8.75 0.1550 ± 0.016 32.91 ± 1.15

ST-Ral 323.3 ± 14.59 0.1450 ± 0.009 33.25 ± 0.45

Table 1. Final body weight, uterine weight/100 g of body weight and estradiol plasma concentration (n = 10) 
of aged female Wistar rats (21 month) that performed or not strength training, treated for 16 weeks with Veh 
or Ral (n = 10). Statistical analysis was performed with two-way ANOVA, followed by Tukey post-hoc testing 
(p < 0.05) to analyze the effect of strength training (ST) and raloxifene (Ral) treatment, and any interactions 
(ST*Ral). Abbreviations: Veh = vehicle, Ral = raloxifene, NT-Veh = non-trained and treated with vehicle; 
NT-Ral = non-trained and treated with raloxifene; ST-Veh = strength training and treated with vehicle; ST-
Ral = strength training and treated with raloxifene.



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3Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

or interaction (ST*Ral) between groups were observed. The pos hoc test showed that ST-Veh (p = 0.0067) group 
increased maximum load in comparison to the NT-Veh group.

Femoral neck bone biomarkers after ST or Ral treatment. The antibodies used to detect OCN, TRAP 
and SOST in the immunohistochemical method showed high specificity for these proteins, which was confirmed 
by the complete absence of immunolabeling in the negative control. Immunolabeling for OCN was predomi-
nantly found in the cytosol of osteoblasts, TRAP in multinucleated osteoclasts and SOST in osteocytes and some 
osteoclasts. The pattern of immunolabeling and immunohistochemical analyses for all biomarkers are shown in 
Fig. 6.

TRAP (ST-Veh; p = 0.0294) and SOST (p = 0.0048) immunolabeling were decreased in the cortical site of the 
femoral neck, in the ST group, while no differences were observed after Ral and ST*Ral. However, pos hoc analysis 
showed decreased immunolabeling for cortical TRAP in ST-Veh group (p = 0.0437) compared to NT-Veh group 
and decreased cortical SOST immunolabeling in ST-Veh (p = 0.0386) and ST-Ral groups (p = 0.0287) in relation 
to NT-Veh group. Immunolabeling for OCN in this region was not affect by treatments.

In trabecular bone of femoral neck, the interaction of ST and Ral was observed in the immunolabeling for 
OCN (F(1,19) = 8.549, p = 0.0087), TRAP (F(1,15) = 10.88, p = 0.0049) and SOST (F(1,19) = 22.62, p = 0.0001). 
Moreover, two way ANOVA showed that Ral and ST affected the immunolabeling for OCN (p = 0.0009; 
p = 0.0006) and SOST (p = 0.0001; p < 0.0001).

Femoral neck surface of osteoclasts and osteoblasts. The analysis of osteoclast (Oc.Pm/Tb.Pm) and 
osteoblast (Ob.Pm/Tb.Pm) perimeter in trabecular femoral neck (Fig. 7) showed main effects after Ral (NT-Ral; 
p = 0.0022 and p = 0.0022, respectively) treatment and interaction effects of ST*Ral (F(1,12) = 20.55, p = 0.0007 
and F(1,12) = 20.57, p = 0.0007, respectively). Oc.Pm/Tb.Pm and Ob.Pm/Tb.Pm were not significantly affected by 
ST.

Figure 1. Plasma bone biomarkers in aged female Wistar rats after ST realization, Ral treatment or association 
of ST and Ral. (A) TRAP, (B) ALP and (C) summary of p values in two way ANOVA analysis, n = 8–10 animal/
group. Abbreviations and symbols: +main effect of Ral, *interaction of ST plus Ral. TRAP = tartrate-resistant 
acid phosphatase and, ALP = alkaline phosphates, ST = strength training, Ral = raloxifene, NT-Veh = non-
trained and treated with vehicle; NT-Ral = non-trained and treated with raloxifene; ST-Veh = strength training 
and treated with vehicle; ST-Ral = strength training and treated with raloxifene.



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4Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

Discussion
Our results clearly demonstrate that ST and Ral modulate bone remodeling cycle in a different manner, with 
improved microarchitecture, and are valid options to prevent age-related bone damage. During late periestr-
opause (age 21 months), we observed bone deterioration in the femoral neck of females rats with decreased 
bone tissue and more separated trabeculae, similar to that found in women during menopause12. Concomitantly, 
decreased cortical polar moment of inertia, predictor of ultimate load23, was observed and, together with the 
trabecular decline, we confirmed the deterioration of the femoral neck in aging rats (see supplementary material).

The results of the present study provide relevant information to the literature, since they show that bone 
microarchitecture can be a better tool to predict bone strength than bone densitometry. Although BMD assessed 
by DXA is a widely used tool to prevent fracture risk, it does not directly assess other elements that may contrib-
ute to bone strength, such as size, shape, geometry, and amount of bone in the cortical and trabecular compart-
ments. Therefore, the increased aBMD in animals of the NT-Veh and NT-Ral groups could be due to the retention 
of “old” bone, with loss of heterogeneity, increased size of crystals, what reflects an increased aBMD but not an 
increased bone strength. Osteoporosis results from decreased bone formation with consequent decrease in acid 
phosphate replacement, which varies inversely with crystallinity (crystal size and perfection), and this loss of 
heterogenicity of the material is associated with increased brittleness and increased risk of fracture24. Due to the 
fact that most of the fractures occur in sites with normal BMD, there is the need to consider that other factors may 
determine bone strength and, thus, fracture risk, other than BMD. In this perspective, QCT allows the 3D recon-
struction of the hip and offers a promising alternative for humans to assess aspects of structure more precisely and 
to evaluate separately the contribution of cortical and trabecular bone to hip fracture risk25.

We highlight that the use of maximum voluntary carrying capacity (MVCC) individualizes ST, but measuring 
the exact strain stimulus that each bone has undergone is a great difficulty, and it is a limitation of studies in vivo. 
However, the capacity of the bone to respond to exercise by improving bone turnover and microarchitecture 
appears to have a key importance. The adaptive capacity of skeletal tissue provides clear evidence of the impact 
of mechanical loading, a regulatory process that is further emphasized by the consequences of removing physical 
signals as reflected by the rapid onset of osteopenia13,26. The results of this study showed that mechanical loading 
plays an important role in bone homeostasis when estrogen levels are decreased. We evaluated the trabecular and 
cortical bone in the same region, and found that ST can prevent trabecular and cortical deterioration, culminat-
ing in an increased maximum load. Considering that the ultimate load and extrinsic stiffness are associated with 

Figure 2. Characterization of 3D morphometric analysis. (A) Scanned image of proximal epiphysis, with 
dimensions of the region of interest (femoral neck) indicated. The region of interest in the trabecular femoral 
neck is marked by crosshatched and the cortical femoral neck is marked by*. The 3D images show a typical 
example of trabecular and cortical bone in the femoral neck of animals that did not undergo strength training 
(NT-Veh – B and F), animals who did not undergo strength training but received raloxifene (NT-Ral – C 
and G), animals who underwent strength training (ST-Veh – D and H) and animals who underwent strength 
training and received raloxifene (ST-Ral – E and I).



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average principal moment of inertia and maximum polar moment of inertia, the increase in these parameters 
in the femoral neck of aging rats after ST is very important. Interestingly, this was the only experimental group 
that showed increased cortical microarchitecture and maximum load, indicating that this parameter is a truly 
good predictor of ultimate load. The decrease of SOST immunolabeling in the cortical and trabecular femoral 
neck of aged female rats after ST evidences the modulation of SOST by mechanical loading, and the osteogenic 
response to physical exercise related to this protein. Through this, we attribute ST as responsible, at least partially, 
for the fact that ST-Veh animals showed increased bone strength. Therefore, this set of results suggests that bone 

Figure 3. Ex vivo trabecular bone microarchitecture. (A) BV/TV, (B) Tb.Th, (C) Tb.N, (D) Conn.Dn, (E) 
Tb.Sp, (F) SMI, (G) summary of p values in two way ANOVA analysis, n = 7 animals/group. Data of the femoral 
neck assessed by microCT. Each column represents mean ± standard error of the mean (SEM). Statistical 
analysis was performed with two-way ANOVA, followed by Tukey post-hoc testing (p < 0.05) to analyze the 
effect of strength training (ST) and raloxifene (Ral) treatment, and any interactions (ST*Ral). Abbreviations 
and symbols: +main effect of Ral, #main effect of ST, *interaction of ST plus Rala, vs NT-Veh; bvs NT-Ral; cvs 
ST-Veh. NT-Veh = non-trained and treated with vehicle; NT-Ral = non-trained and treated with raloxifene; 
ST-Veh = strength training and treated with vehicle; ST-Ral = strength training and treated with raloxifene; BV/
TV = bone volume fraction; Tb.Th = trabecular thickness; Tb.N = trabecular number; Conn.Dn = connectivity 
density; Tb.Sp = trabecular separation; SMI = structure model index.



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6Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

response to an increased mechanical load favors bone turnover and bone microarchitecture of the femoral neck 
of rats in the aging period and culminates in better resistance to loading challenges.

Treatment with Ral did not prevent the negative effects verified in aged female, such as minor bone mechan-
ical strength of femoral neck, as much as ST. Ral provided an increase in the trabecular microarchitecture, but it 
did not affect the cortical parameters or maximum load. Classically, Ral is an antiresorptive drug that diminishes 
bone turnover. We can confirm this fact with the decrease of plasma TRAP activity and osteoclast surface in this 
work. This treatment, promoted decreased immunolabeling of SOST in trabecular femoral neck bone of late 
periestropaused rats, besides increased OCN, as well as decreased perimeter of osteoclasts, corroborating with 
findings from our lab14. Furthermore, cortical bone strength is important for the prevention of fragility fractures 
since cortical bone represents a substantial amount of the total bone mass in the appendicular skeleton27. Thus, 
after treatment, the analysis of this region showed that Ral had limited effect on cortical bone remodeling in aged 
rats, since the drug did not decrease SOST in the cortical region of the femoral neck and was not able to prevent 
the decrease in Ct.Th, resulting in reduced bone and minor structurally effective bone architecture.

Some authors have investigated the role of ST and antiresorptive drugs in bone health and the results did not 
show an additive effect of the therapies28,29. To our knowledge, this study was the first to show that Ral treatment 
associated with ST provides interactive effects in aging rats bone. This association led to an interactive response in 
Tb.N, Tb.Sp, aBMD, increased OCN immunolabeling and Ob.Pm/Tb.Pm, decreased TRAP and SOST immuno-
labeling in the trabecular femoral neck bone, decreased Oc.Pm/Tb.Pm and plasma TRAP activity, showing that 

Figure 4. Ex vivo cortical bone microarchitecture. Data of the femoral neck assessed by microCT. (A) Ct.Ar, 
(B) Ct.Th, (C) Imax, (D) Imin, (E) J, (F) summary of p values in two way ANOVA analysis, n = 7 animals/
group. Each column represents mean ± standard error of the mean (SEM). Statistical analysis was performed 
with two-way ANOVA, followed by Tukey post-hoc testing (p < 0.05) to analyze the effect of strength training 
(ST) and raloxifene (Ral) treatment, and any interactions (ST*Ral). Abbreviations and symbols: +main effect of 
Ral, #main effect of ST, *interaction of ST plus Rala, vs NT-Veh; bvs NT-Ral; cvs ST-Veh. NT-Ral = non-trained 
and treated with raloxifene; ST-Veh = strength training and treated with vehicle; ST-Ral = strength training 
and treated with raloxifene; Ct.Ar = cortical bone area; Ct.Th = average cortical thickness; Imax = maximum 
moment of inertia; Imin = minimum moment of inertia; J = polar moment of inertia.



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the treatments did not act individually for these parameters. Although the interaction between the treatments in 
the previously mentioned parameters was beneficial, we did not observe improvement in the cortical microarchi-
tecture, perhaps because TRAP immunolabeling did not decrease in this area. All the dynamics of the remodeling 
process triggered by the association of therapies were not able to respond into improvement of cortical microar-
chitecture and bone strength. In fact, in this group (ST-Ral), we observed a loss of the response that exercise 
brought alone. This can be attributed to a strain-related proliferation that is mediated by estrogen receptor ER, in 
a manner that does not compete with estrogen but can be blocked by ER modulators30.

A previous study from our group using rats in initial periestropause (14 to 18 months of age) where estrogen 
was decreased abruptly by OVX, 120 days of treatment with ST or Ral triggered similar responses in the femoral 
neck, but the combination of the interventions (ST + Ral) did not bring additional benefits to the bone14. In con-
trast, this study investigated the effects of these treatments in naturally aged animals, during late periestropause 
(18 to 21 months of age) and found that with a gradual decrease of plasma estrogen, ST can be used to prevent 
bone loss in this period. Treatment with Ral is also a valid strategy for this prevention, but appears to be less effec-
tive than ST, and combining the two therapies provided some additional interactions but did not bring additional 
effects that justify their dual use.

We can conclude that bone loss in late periestropause can be reversed with the use of ST, as ST alone is able 
to prevent bone loss and improve cortical bone. The conclusion is that ST can be a systemic intervention for 
osteoporosis, taking into account the fact that mechanical load generated by ST also affects non-skeletal tissues. 
However, ST should be used carefully for the prevention and treatment of osteoporosis, because the frequency of 
exercise and load intensity are essential factors to consider. These results add new information about interven-
tions to prevent age-associated osteoporosis in females and provide good basis for preclinical studies.

Material and Methods
Animals. All animal procedures were approved (Protocol Number 2014–00267) by the Institutional Animal 
Care and Use Committee of the Faculty of Dentistry (Univ. Estadual Paulista – Unesp, Araçatuba, SP, Brazil), and 
complied with the Guide for Care and Use of Laboratory Animals.

Figure 5. Ex vivo areal bone mineral density (aBMD) and maximum load. (A) Data of the femoral neck 
assessed by DXA. (B) Ex vivo maximum load data of the femoral neck, data assessed by biomechanical 
compression bending testing. (C) Summary of p values in two way ANOVA analysis, n = 7 animals/group. Each 
column represents mean ± standard error of the mean (SEM). Statistical analysis was performed with two-
way ANOVA, followed by Tukey post-hoc testing (p < 0.05) to analyze the effect of strength training (ST) and 
raloxifene (Ral) treatment, and any interactions (ST*Ral). Abbreviations and symbols: + main effect of Ral, # 
main effect of ST, *interaction of ST plus Rala, vs NT-Veh; bvs NT-Ral; cvs ST-Veh. NT-Veh = non-trained and 
treated with vehicle; NT-Ral = non-trained and treated with raloxifene; ST-Veh = strength training and treated 
with vehicle; ST-Ral = strength training and treated with raloxifene.



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Forty female Wistar rats from the central animal creation of the Faculty of Dentistry of Araçatuba, aged 17–21 
month, were housed at 22 °C (±2 °C) and kept under a 12:12 hour light:dark cycle. The animals were allowed free 
access to water and a commercial pellet diet (Presence® Ratos e Camundongos, Paulínia, SP, Brazil). All female 
rats were multiparous as this was an inclusion criterion. The reproductive life of these animals was on average 
from 2 to 8 months of age, reaching 3 to 4 pregnancies. The general health of the rats was monitored on a daily 
basis and the estrous cycle was checked during the 17th month, to determine acyclicity. Data from our labora-
tory showed that Wistar female rats in their 18th month had decreased plasma concentrations of estrogen and 
increased plasma concentrations of luteinizing hormone (LH), characterizing periestropause, which is a period 
similar to perimenopause in women31.

Thus, throughout the 17 months, the experimental animals had their estrous cycles monitored daily, and 
after confirmation of estrous acyclicity, rats were randomly assigned to one of four groups:1: non-trained plus 
vehicle (NT-Veh); 2: non-trained plus raloxifene (NT-Ral, n = 10); 3: strength training plus vehicle (ST-Veh); 
or 4: strength training plus raloxifene (ST-Ral, n = 10). After 120 days from the beginning of the treatments, the 
animals were sacrificed with an anesthetic overdose and the material was collected for further analysis.

Raloxifene and vehicle administration. At the beginning of the 18th month, animals in the NT-Ral and 
ST-Ral groups received 1 mg/kg/day of Ral14 (Sigma Aldrich, Munich, Germany) in 0.3 mL of physiological saline 
solution administered daily by gavage for 120 days. Animals in the other treatment groups received a physiologi-
cal saline solution (0.3 mL) daily by gavage for the same time period.

Maximum voluntary carrying capacity (MVCC) and strength training. ST-Veh and ST-Ral groups 
performed ST with a ladder (1.13 × 0.18 m; 2 cm grid; 80° angle; with a resting area at the top [20 × 20 × 20 cm 
diameter])32, three times per week for 120 days14. At the beginning of the 18th month, the animals underwent 1 

Figure 6. Immunolabeling for OCN, TRAP and SOST assessed by immunohistochemistry. (A–D) 
Photomicrographs showing osteoblasts OCN-positive (A), osteoclast TRAP-positive (B), osteocytes SOST-
positive (C) and osteoclast SOST-positive. (E–J): Graphs showing the distribution of scores for OCN (E and 
H), TRAP (F and I) and SOST (G and J) in cortical and trabecular bone in the different experimental groups. 
(K) summary of p values in two way ANOVA analysis, n = 7 animals/group. Statistical analysis was performed 
with two-way ANOVA, followed by Tukey post-hoc testing (p < 0.05) to analyze the effect of strength training 
(ST) and raloxifene (Ral) treatment, and any interactions (ST*Ral). Abbreviations and symbols: +main effect 
of Ral, #main effect of ST, *interaction of ST plus Rala, vs NT-Veh; bvs NT-Ral; cvs ST-Veh. OCN = osteocalcin, 
TRAP = tartrate-resistant acid phosphatase and SOST = sclerostin. NT-Veh = non-trained and treated with 
vehicle; NT-Ral = non-trained and treated with raloxifene; ST-Veh = strength training and treated with vehicle; 
ST-Ral = strength training and treated with raloxifene.



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week of acclimatization. Subsequently, the MVCC of each animal was evaluated with the use of two weighted 
tubes (steel spheres) attached to the tail. When evaluating MVCC, the initial load was 75% of the body weight of 
the animal. The animals had two minutes of rest between sets and each new series to be held added 30 grams of 
weight32. This procedure was performed until the animal was not able to fully complete the upward movement. 
The burden on the previous climb in which the movement failed was considered the maximum stocking rate, and 
it was used as the basis for the calculation of overhead to be applied during the training period that was initiated 
forty-eight hours after the MVCC test completion. During 120 days, the animals performed three weekly sessions 
of ST on alternate days, with each session consisting of six series and two-minute intervals between each series. 
During the first week, the animals underwent the training with overhead corresponding to 60% of MVCC, which 
was increased to 70% of MVCC in the second week and 80% of MVCC in the third week. From the 4th week until 
the end of the proposed period, the animals underwent ST overload at 80% of MVCC. Each month, a new MVCC 
test was carried out to obtain and maintain the maximum strength capacity of the animals. No animals were 
excluded due to physical injuries or disorders in the estrous cycle.

Measurement of body and uterus weight. After 120 days of treatment, all animals were anesthetized 
(ketamine 80 mg/kg was associated with xylazine 10 mg/kg, intraperitoneally) and weighed. After this, they were 
sacrificed by decapitation. Immediately after decapitation and collection of femurs, the uteri were weighed on a 
precision scale to check for possible treatment effects.

Measurement of plasma levels of estradiol and bone turnover biomarkers. Blood (4 mL) was 
collected, immediately centrifuged (2256 × g; 15 min; 4 °C), and the plasma was stored (−20 °C). Estradiol levels 
were measured by employing a rat-specific quantitative sandwich enzyme-linked immunosorbent assay (ELISA, 
IBL international GMBH, Hamburg, Germany) in accordance with the manufacturer’s instructions. All samples 
were assayed in duplicate and in the same assay to avoid inter-assay error. The minimum detectable dose of estra-
diol was 0.28 ng/mL.

The plasma bone formation marker alkaline phosphatase (ALP) was determined using the colorimetric assay 
that measured the time-dependent formation of p-nitrophenyl (pNP) from pNPP in accordance with a protocol 
adapted from Chaves Neto et al.33. The protocol used 25 µL of plasma in a total volume of 0.5 mL containing 2.5 
mMpNPP, 2 mM MgCl2, 25 mM glycine buffer, pH 9.4. The reaction was initiated by adding the substrate, and it 
proceeded for 30 min at 37 °C in a water bath. Assay was terminated by adding 0.25 mL of 1 M NaOH solution, 

Figure 7. Osteoclast perimeter/Trabecular perimeter (Oc.Pm/Tb.Pm) and Osteoblast perimeter/Trabecular 
perimeter (Ob.Pm/Tb.Pm) assessed in TRAP positive cells by immunohistochemistry counterstaining with 
hematoxilin and eosin, analyzed by Image J. (A) Oc.Pm/Tb.Pm (%), (B) Ob.Pm/Tb.Pm (%), (C) summary of 
p values in two way ANOVA analysis, n = 7 animals/group. Abbreviations and symbols +main effect of Ral, 
*interaction of ST plus Ral. NT-Veh = non-trained and treated with vehicle; NT-Ral = non-trained and treated 
with raloxifene; ST-Veh = strength training and treated with vehicle; ST-Ral = strength training and treated with 
raloxifene.



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1 0Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

and the absorbance determined at 405 nm to determine the amount of pNP formed during the reaction. One unit 
of enzyme activity is defined as the amount of enzyme that is required to hydrolyze 1 μmol of pNPP per min at 
37 °C. Plasma tartrate – resistant acid phosphatase (TRAP) activity was determined by colorimetric assay using 
protocol adapted from Granjeiro et al.34 and Janckila et al.35. Briefly, an aliquot of 25 µL of plasma was assayed in 
0.5 mL of reaction mixture consisting of 10 m Mp-nitrophenyl phosphate (pNPP), 100 mM sodium acetate, pH 
5.8, 50 mM sodium tartrate and 1 mMp-hydroxy mercury benzoate (pHMB), the latter acts by inhibiting of low 
molecular weight acid phosphatases36. The reaction was initiated by adding of the substrate, and was usually pro-
ceeded for 1 h at 37 °C in a water bath. Assay was terminated by adding 0.25 mL of 1 M NaOH, and the absorbance 
determined at 405 nm to determine the amount of p-nitrophenolate (pNP) formed during the reaction. Controls 
without enzyme were included with each assay to adjust the non-enzymatic hydrolysis of pNPP. One unit of 
enzyme activity is defined as the amount of enzyme that is required to hydrolyze 1 μmol of pNPP per min at 37 °C.

Microtomography. Immediately after being euthanized, the femurs of experimental animals were removed, 
cleaned with soft tissue, and immediately stored in cryotubes with physiological saline solution at −20 °C for 
microtomography (micro-CT), bone mineral density and biomechanical compression bending measurements. 
Twenty-four hours before the micro-CT, the cryotubes with femurs were removed from the −20 °C freezer and 
placed in the refrigerator (4 °C) to defrost, and 6 hours prior to the micro-CT, they were left at room temperature.

Micro-CT of the femurs was performed using a microtomograph SkyScan 1272 device (SkyScan, Belgium) at 
the following settings: X-ray voltage 70 kV, X-ray current 143 mA, filter 0.5mm, image pixels size 10 µm, camera 
resolution setting 2016 × 1344, tomographic rotation 180°, rotation step 0.4°, frame average 3, and scan dura-
tion 55 minutes. Each femur was positioned in the cranio-caudal orientation to obtain slices. The images were 
imported into NRecon software (SkyScan, Leuven, Belgium) and converted from gray scale into Digital Imaging 
and Communications in Medicine (DICOM) format. To obtain the trabecular and cortical bone of femoral neck, 
we quantified the volumes of interest (VOI) from the three-dimensional structure of trabecular bone in the fem-
oral neck of all animals and extracted measurements from each dataset in the CT-Analyser (SkyScan, Leuven, 
Belgium) software. The trabecular and cortical bone of the femoral neck were defined using the polygon selection 
tool. An interpolation tool was used on the selected region of trabecular and cortical bone. Trabecular bone of the 
femoral neck was limited by cortical bone in the mediolateral direction. Therefore, greater fidelity for the selected 
area was acquired using a dynamic interpolation tool. Trabecular and cortical bone was selected and inspected 
using a binary imaging tool to ensure the use of appropriate threshold values, and was used for all subsequent 
morphometric analyses. Image processing was required for 3D analysis of the bone morphometric parameters 
that influence mechanical and structural properties. These parameters were calculated using the CT-Analyser 
(SkyScan, Leuven, Belgium) 3D software based on a volume model. Segmentation of each femoral neck was per-
formed using the same software.

Abbreviations were used for 3D bone morphometric analysis37 and the measurement parameters of micro-CT 
analyses for trabecular and cortical bone were: bone volume fraction (BV/TV; %), trabecular thickness (Tb.Th; 
mm), trabecular number (Tb.N; 1/mm), trabecular separation (Tb.Sp; mm), structure model index (SMI), con-
nectivity density (Conn.Dn; 1/mm3), cortical bone area (Ct.Ar; mm2), average cortical thickness (Ct.Th; mm), 
maximum moment of inertia (Imax; mm4), minimum moment of inertia (Imin; mm4) and polar moment of 
inertia (J; mm4)38.

Bone mineral density measurements. For the areal bone mineral density (aBMD), femurs were thawed 
and positioned in the frontal plane and anterior posterior view on the scanner table, all oriented the same way, 
fully scanned in a bowl with 2 cm of water, according to manufacturer instructions. The aBMD of femurs was 
assessed using dual energy X-ray absorptiometry (Lunar DPX Alpha, WI, USA) and a software for measuring 
BMD in small animals. The equipment was calibrated according to the manufacturer’s instructions. The same 
investigator analyzed all scans. For analysis of the femoral neck, a region of interest (ROI) was identified using a 
square with a known area (0.72 mm2), which was located in the femoral neck region of all specimens14.

Biomechanical compression bending testing. The biomechanical properties of the femur were assessed 
with a compression test, using a Universal Testing Machine (DL 3000, EMIC®, São José dos Pinhais, PR, Brazil). 
Each femur was placed in a metallic apparatus and maintained in a vertically fixed position (long axis). The load 
was applied to the area of the femoral head whose vector line of action force was parallel to the long axis of the 
femur, causing a bending movement in the femoral neck region. The deformation rate was 5 mm/min with stand-
ardized parameters of loaded cells set to 2000 N of capacity39. Load was applied until the bone fractured. The load 
and displacement of the machine crossbar was monitored and recorded using device software.

Immunohistochemistry. Immunohistochemical evaluation of OCN, TRAP and SOST immunolabeling 
were performed by fixing specimens in 4% formaldehyde for 24 h at room temperature, and decalcifying in 10% 
ethylenediaminetetraacetic acid (changed weekly) for 8 weeks. Decalcified samples were processed in a con-
ventional manner, embedded in paraffin, and submitted to microtomy (3 µm thick), so that the sections were 
performed along the coronal plane of the proximal femur.

Histology slides with samples from all experimental groups were then submitted to indirect immunoperox-
idase technique and the primary antibodies (Santa Cruz Biotechnology, Santa Cruz, CA, USA) anti-OCN (SC 
30044; 1:100), anti-TRAP (SC 30833; 1:200), and anti-SOST (obb 100911; 1:500; Biorbyt, São Francisco, CA, 
USA). The dilution of primary antibodies was based on a titration test. Immunohistochemical processing fol-
lowed the protocol described by Stringhetta-Garcia et al.14.

Histological sections (trabecular and cortical femoral neck bone) were examined under bright field illumina-
tion on a light microscope (Optiphot-2, Nikon, Japan) by investigators who were blind to treatment assignments. 



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1 1Scientific RepoRts | 7: 14410  | DOI:10.1038/s41598-017-13098-5

The scores for TRAP immunolabeling pattern were modified from Stringhetta-Garcia et al.14: score 3 indicates 
high pattern, over 8 immunoreactive (IR) cells per area; score 2 indicates moderate pattern, 3 to 7 IR cells per area; 
score 1 indicates low pattern, less than 3 IR cells per area; and score 0 indicates the absence of immunolabeling. 
The scores for OCN and SOST immunolabeling patterns were adapted from Stringhetta-Garcia et al.14: score 3, 
high pattern, approximately 75% of IR cells per area; score 2, moderate pattern, approximately 50% IR cells per 
area; score 1, low pattern, approximately 25% IR cells per area; and score 0, absence of immunolabeling. These 
immunolabeling scores were compared among experimental groups.

Femoral neck surface of osteoclasts and osteoblasts. The TRAP-positive slides were submitted to the 
indirect immunoperoxidase technique and were counterstained with hematoxylin and eosin for surface measure-
ment of osteoclasts and osteoblasts. The surface occupied by TRAP-positive osteoclasts, the surface occupied by 
osteoblast and bone lining cells in the total perimeter of the bone trabeculae were measured using the software 
Image J and were expressed as % of the mean and standard error of the mean.

Statistical analysis. Statistical analysis was performed using two-way ANOVA. Tukey’s post-hoc test 
was performed for analyzes where no interactions were observed, p values <0.05 were considered statistically 
significant. Data are presented as mean ± SEM of independent replicates (n = 8–10 animals for physiological 
parameters, measurement of estradiol, TRAP and ALP; n = 7 for micro-CT, densitometry, biomechanical, immu-
nohistochemistry and osteoblast/osteoclast surface analysis). Statistical analyses were conducted using GraphPad 
Prism (version 6.01; GraphPad Software, Inc.).

Institution that approved the experimental protocols. All animal procedures were approved by the 
Institutional Animal Care and Use Committee of the Faculty of Dentistry of Universidade Estadual Paulista Júlio 
de Mesquita Filho – UNESP, Araçatuba, SP, Brazil (Protocol Number 2014-00267) and performed in accordance 
with the Guide for Care and Use of Laboratory Animals.

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Acknowledgements
We thank the Universidade Estadual Paulista “Júlio de Mesquita Filho,” Multiuser Laboratory for Biotechnology 
and Bioengineering (MUBIO) of Araçatuba Dental School, FINEP (FINEP/CT-INFRA – Convênio FINEP: 
01.12.0530.00-PROINFRA 01/2011), research foundations (Coordenação de Aperfeiçoamento de Pessoal de 
Nível Superior - CAPES) and the Brazilian Society of Physiology for supporting the present study. We would 
also like to thank Dr. Heitor Marques Honório (Faculty of Dentistry of Bauru - FOB – Universidade de São 
Paulo (USP) / SP, Bauru, SP, Brazil) for the statistical support of the study, and Dr. Sergio Diniz Garcia (Faculty 
of Veterinary Medicine, UNESP, Araçatuba, SP, Brazil) for monitoring and helping with the care of animals 
during the aging process. CAPES (Coordination of Improvement of Higher Education Personal) supported this 
work. This study used financial support from the Fundação de Amparo à Pesquisa do Estado de São Paulo, Brazil 
(FAPESP Grant n° 2013/18907-2).

Author Contributions
Camila Tami Stringhetta-Garcia: care of experimental animals, data collection, data analysis, data tabulation, 
discussion of results, paper editing. Samuel Rodrigues Lourenço Morais: data collection and discussion of results. 
Fernanda Fernandes: data collection, data analysis and discussion of results. Melise Jacon Perez-Ueno: data 
analysis and discussion of results. Ricardo de Paula Almeida: data collection of supplementary materials and 
discussion of results. Mário Jefferson Quirino Louzada: Standardization of bone density, mechanical testing and 
discussion of results. Antonio Hernandes Chaves-Neto: Standardization of bone biomarkers activity TRAP and 
ALP and discussion of results. Edilson Ervolino: standardization and discussion of the immunohistochemistry 
analysis. Rita Cássia Menegati Dornelles: Guidance and monitoring of all experimental steps, data analysis, data 
tabulation, discussion of results, paper editing. Previous Interactions. We have had no previous interactions about 
this manuscript with the following Editorial Board Member.

Additional Information
Supplementary information accompanies this paper at https://doi.org/10.1038/s41598-017-13098-5.
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	Effects of strength training and raloxifene on femoral neck metabolism and microarchitecture of aging female Wistar rats
	Results
	Physiological Parameters. 
	Measurement of plasma levels of tartrate-resistant acid phosphatase (TRAP) and alkaline phosphate activity (ALP). 
	Femoral neck microarchitecture after ST or Ral treatment. 
	Femoral neck maximum load and bone mass after ST or Ral treatment. 
	Femoral neck bone biomarkers after ST or Ral treatment. 
	Femoral neck surface of osteoclasts and osteoblasts. 

	Discussion
	Material and Methods
	Animals. 
	Raloxifene and vehicle administration. 
	Maximum voluntary carrying capacity (MVCC) and strength training. 
	Measurement of body and uterus weight. 
	Measurement of plasma levels of estradiol and bone turnover biomarkers. 
	Microtomography. 
	Bone mineral density measurements. 
	Biomechanical compression bending testing. 
	Immunohistochemistry. 
	Femoral neck surface of osteoclasts and osteoblasts. 
	Statistical analysis. 
	Institution that approved the experimental protocols. 

	Acknowledgements
	Figure 1 Plasma bone biomarkers in aged female Wistar rats after ST realization, Ral treatment or association of ST and Ral.
	Figure 2 Characterization of 3D morphometric analysis.
	Figure 3 Ex vivo trabecular bone microarchitecture.
	Figure 4 Ex vivo cortical bone microarchitecture.
	Figure 5 Ex vivo areal bone mineral density (aBMD) and maximum load.
	Figure 6 Immunolabeling for OCN, TRAP and SOST assessed by immunohistochemistry.
	Figure 7 Osteoclast perimeter/Trabecular perimeter (Oc.
	Table 1 Final body weight, uterine weight/100 g of body weight and estradiol plasma concentration (n = 10) of aged female Wistar rats (21 month) that performed or not strength training, treated for 16 weeks with Veh or Ral (n = 10).