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1, Department of
Nutritional Sciences and Food Hygiene, School of Xiangya Public Health of
Central-South University
2, Department of Nutrition, Guangdong Provincial People's Hospital, Guangzhou
*Correspondence to: Huang YM, Department of Nutritional Sciences and Food Hygiene, School of Xiangya Public Health of Central-South University, Changsha 41078, Hunan, P.R.China. Tel/Fax: 86-731-4805771 E mail: huangym@xysm.net
Supported by the Third 5-year National Scientechnic Key Problem Tackling Project, Geriatric Alerting and Prevention (No. 2001BA702B04)
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ABSTRACT |
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INTRODUCTION |
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MATERIALS AND METHODS |
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RESULTS |
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DISCUSSIONS |
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REFERENCES |
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ABSTRACT
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KEY WORDS trans-resveratrol; post menopausal osteoporosis; ovarectomized rats; bone mineral density;
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INTRODUCTION
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Most of Early-stage postmenopausal women suffer from osteoporosis.
Postmenopausal osteoporosis (PMOP),shows a rapid decrease in bone mineral
density (BMD), which can be due to estrogen deficiency after menopause, is a
serious public health problem worldwide[1~3].
Estrogen replace therapy (ERT) remains the mainstay for the prevention of
postmenopausal, however is challenged by its side effects, particularly the risk
of breast and uterine cancers[4~5]. Thus, it
is important to find alternatives to estrogen for postmenopausal women to
prevent osteoporosis.
Phytoestrogens have many beneficial effects on people's health. Trans-resveratrol
(RES), 3,5,4'-trihydroxylstibene, is a natural compound analogous with the
synthetic estrogen diethylstilbestrol and had documented a mixed
agonist/antagonist activity for estrogen receptors-α and β(Barry et al 1997, Ray
et al 1999, Jennifer et al 2000, Bagchi et al 2001) was demonstrated to have
beneficial effects on cardiovascular diseases, and may also the osteoporosis in
post-menopausal women because of its antioxidant activity[6-9].
The purpose of this study was to determine the effects of resveratrol on indices
of bone density, and bone formation and resorption in a rat model of aging and
menopause. The rats were ovariectomized as a model of peri- and postmenopausal
bone loss and replicates many aspects of the changes observed in humans.
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MATERIALS
AND METHODS
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1.1 Animals &Treatment
Female, healthy adult Sprague-Dawley rats were used in this study (supplied by Laboratory Animal Center,
Central south university, Changsha, Hunan, P.R.of China). All of these SD rats were three months of age and 254.91±
18.01 gram of weight at the beginning of the study. These animals were kept in a temperature- (22±4°C) ,
humidity 60%~65% and light (7:00-19:00) controlled room.
Forty-eight SD rats were divided into 6 groups (n = 8/group) after twenty-day adaptive feeding period with the standard
diet that had calcium content of 1.3%. The rats in five of the groups were ovariectomized and the rats in the other one
group were sham operated. The absence of ovarian tissue and plasma estrogen level confirmed the success of the ovariectomy
(Ovx). The rats were further divided into the following groups: sham rats fed the base diet (group A),
ovariectomized rats fed the base diet (group B), ovariectomized rats with diethylstilbestrol
0.03mg×kgbw-1×day-1(group C), ovariectomized rats with resveratrol
5mg×kgbw-1×day-1(group D), ovariectomized rats with resveratrol
15mg×kgbw-1×day-1(group E) and ovariectomized rats with resveratrol 45mg×kgbw-1×day-1(group F).
The rats were fed the diets and tap water and the study continued for 90 days. Food consumption and body weight were
measured every week
1.2 Bone mineral density
BMD was assessed by dual-energy X-ray absorptiometry (DEXA), with the Hologic
QDR-4500 A X-ray bone densitometer (Hologic, CO, USA). At the 45th and 90th day
after initiated the administration of trans-resveratrol,The total body BMD
(T-BMD), as well as the BMD of the second, third, fourth and fifth lumbar
vertebrae (mainly cancellous bone) were also scanned and the mean BMD measured.
1.3 Serum estradiol (E2)
Serum estradiol was measured with radioimmunoassay by the XH-6010 RIA counter,
(262 factory, Shangxi, P.R.of China). The intra-assay variation was 2.13%,
whereas the interassay variation 4.8%.
1.4 Plasma Resveratrol concentration
The resveratrol concentrations were assessed with liquid chromatography assays
by LC-6A HPLC (SHIMADZU corporation, Japan). The intra- and interassay
variations were both 3.16%
1.5 Statistical methods.
Results were expressed as means ±SD. All data were analyzed with SPSS 11.0
software (SPSS Inc, IL, USA). An ANOVA was first performed to test for any
significant differences among groups. When significant, the LSD multiple
comparison test were used to determine the specific differences between means.
Parametric ANOVA was performed when data were sampled from populations with
equal variance. Otherwise, nonparametric methods were selected. Thus, a
Kruskal-Wallis test was first performed. If it indicated a significant
difference among groups, the Dunnet's T3 test was used to determine specific
differences. To test for any significant differences among days within a group,
repeated measures ANOVA was performed and, when significant, the
Student-Newman-Keuls multiple comparison test was used to determine the specific
differences between means. The level of significance was set at P < 0.05 for all
statistical tests.
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RESULTS
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2.1 Body weight gain dynamics
The baseline body weight of the animal groups were similar (P>0.05); and all the animal groups had weight gain but not
overweighted throughout the experimental period (P>0.05). Body weight gain of the estrogen replacement treatment
control (C) group was significantly lesser than the other groups (P>0.05), and the 45 mg×kg-1×d-1
trans-resevestrol (F) group was lesser than the 5 mg×kg-1×d-1 (D) and 15 mg×kg-1×d-1 (E)
and the osteoporosis control (B) groups. The results were listed in Table 1.
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Table 1 Body weights of rats during the experiment
(g, ±s)
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2.2 Dynamic estradiol levels
After ovarectomy or shame operation and the twenty-day adaptive feeding period,
serum estradiol (E2) levels at the beginning of the experiment, the blank
control A group was significantly higher than of all the groups received
ovarectomy; and also at the end point of the 90-day experiment (P<0.05). It was
obvious that estradiol level alterations through the experimental period showed
no statistical significance (P>0.05), but the normal blank control A and
osteoporosis B groups had a little decrement, and the estrogen replacement and
the trans-resevarol treatment groups (C, D, E, and F) had a little increment,
however. The results were listed in Table 2.
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Table 2 Serum concentrations of estradiol (pg/mL,±s)
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2.3 The BMD indices dynamics
2.3.1 The in vitro whole body and lumbar vertebra BMD dynamics
Whole body and lumbar vertebral bone specific BMD were assayed during the 45th
and 90th day. The BMD parameters of the osteoporosis control(B)group was
significantly below the other groups on either whole body or the lumbar
vertebra, and either at the 45th or the 90th day of the experiment (P<0.05). The
estrogen replacement (C) group had BMD parameters higher than that of the
osteoporosis (B) group and approached the blank control (A) group (P>0.05)
except the whole body bone density (P<0.05). All the 3 trans-resvesatrol groups
approached whole body BMD of the blank control A group (P>0.05), but lower
lumbar vertebra BMD (P<0.05) except the 45 mg×kg-1×d-1 F group (P>0.05). The
actual numerical data of the 3 trans-resvesatrol groups were even higher than
that of the estrogen replacement group, but did not have the power to
demonstrate statistical significance. The results were listed in Table 3.
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Table 3 BMDs of the total body and lumbar vertebrae in
different periods during the experiment (g/cm2, ±s)
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2.3.2 BMD of the isolate lumbar vertebra at end of the 90-day experiment
At the end point of the 90-day experiment, the lower three lumbar vertebra bones
were isolated and had their BMD reassessed. The isolated 4th, 5th, and 6th
vertebra BMD of the osteoporosis control B group were lower than that of all the
other groups. The 5th lumbar vertebra BMD of the high dose veresatrol (F) group
was approximated the blank control (A) group; and all the 6th lumbar vertebrae
of the estrogen replacement C and the trans-resvesatrol middle and high dose E,
and F groups approximated A group (P>0.05) except the low dose 5 mg×kg-1×d-1 D
group (P<0.05). The results were listed in Table 4.
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Table 4 BMDs of the lumbar vertebrae in vitro at the
end of the experiment (g/cm2,±s)
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2.3.3 BMD of the femur and tibia bones evaluated as a whole and in the 7 femur
sensitive regions of interest (FROI)
The whole femur and tibia bones BMD of group A was significantly higher than all
the other groups (P>0.05) except the 45 mg×kg-1×d-1 high dose trans-resvesatrol
group F (P>0.005). When the femur and tibia bones were evaluated in 7 artificial
divided sensitive regions from the proximal terminal to the distal, all the TROI
parameters of the group B were the lowest (P<0.05). Both the FROI-1 and -2 of
the B, C, D, and E groups were significantly lower than that of the A group
(P<0.05), whereas the 45 mg×kg-1×d-1 high dose trans-resvesatrol group
approximated the A group (P>0.05). The BMDs of A and F group at both the FROI-6
and -7 showed no significant difference (P>0.05), and all the three
trans-resvesatrol groups had higher BMD density parameters than that of the
osteoporosis control group B, but only the group F in FORI-6 and group E and F
had the power to demonstrate statistical significance (P<0.05). The results were
listed in Table 5 and 6.
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Table 5 BMDs of the femur and the femur sensitive
regions of interest (g/cm2, ±s)
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Table 6 BMDs of the tibia and the tibia sensitive
regions of interest (g/cm2,±s)
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| DISCUSSIONS
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Trans-Resveratrol (resveratrol) has been shown in several studies to
significantly modulate biomarkers of bone metabolism. Mizutani et al found that
trans-resveratrol may promote bone formation by enhancing the osteoblasts
activity and stimulate osteoblasts proliferation and differentiation[10,11].
But, there is no direct evidence supporting its inhibitory effect towards bone
loss. Therefore, in present study, the effects of trans-resveratrol on bone
mineral density (BMD) and bone metabolism indices were examined in the
ovariectomized (OVX) rat model.
The present experiment used small, median, and high dose trans-resveratrol
groups in comparison with the estrogen replacement control to evaluate the
effect of trans-resveratrol on BMD of the rat PMOP model. The results
demonstrated that trans-resveratrol do provide protective effect on
ovarectomized rat BMD. The 3 different trans-resveratrol dose animals lumbar
vertebrae BMD was higher than that of the control model group and approximated
the normal blank control group during the 45th day, at the middle of the
experiment; at the end point, the 90th day, of this experiment, the
trans-resveratrol groups still exhibited positive effect on BMP, the whole body
BMD remained at the level of normal controls. In addition, as to the protective
effect on lumbar vertebra, the 45 mg×kg-1×d-1 trans-resveratrol group approximated
the normal control group level, and was surpassed the 0.03 mg×kg-1×d-1
ethylestradiol group.
Since the trabecular bone density decrement is more sensitive to
hypo-estrogenemia, the lumbar vertebra composed mainly trabecular bone and the
physis of long bones were of most important consideration in PMOP bone lose. At
the end point of this experiment, ethylestradiol and the 3 trans-resveratrol
groups showed significant protection on ovarectomy induced BMP losses, which was
approximated the normal controls. As to the individual lumbar vertebra, the
protective effect was progressively increasing caudally, with the best results
on the 6th, followed by the 5th vertebra, which were reached statistical
significance of P>0.05; except the 4th vertebra, which may suggest a site
specificity. The protective effect of trans-resveratrol on femur was better than
tibia as a whole. At the proximal end of tibia, the TROI-1, all -3 in
trans-resveratrol groups demonstrated significant protective effect; and the
same were demonstrated on FROI-1, -2, -6, and -7 of the femur by both the 15 and
45 mg×kg-1×d-1 trans-resveratrol groups. In summary, the phytoestrogen analogous
substance trans-resveratrol demonstrated protective effect on BMD lose in
ovarectomized rat model, as trans-resveratrol effectively preserved the BMD; and
the 45 mg×kg-1×d-1 dose group demonstrated the best protective effect, which might
suggests a dose-dependent manner, although the experimental design did not have
the power to demonstrate a statistical significance in all of the experimental
parameters.
Studies reported the enhanced expression of cytokines such as TGFs and eNOS by
trans-resveratrol, which had effects on skeletal tissue quality[12,13].
And also studies) reported significant inhibitive effects of trans-resveratrol
on the expression and/or production of cytokines such as IL-1, IL-6, TNF-α, and
PGE2, which enhance the osteoclasts activities and resultant in reduced bone
resorption on the background of estrogen deficiency[8,9,14,15].
In conclusion, the present study demonstrated that a daily resvertrol intake in
adult ovariectomized rats reduced bone turnover and also reverse a previous bone
loss. Furthermore, it appeared that the highest 45 mg×kg-1×d-1 resveratrol
administration levels were more effective in depressing the ovariectomy-induced
increase in bone turnover (and in bone resorption specifically) than other dose.
Therefore, ingestion levels of resveratrol should be considered to improve bone
health in a preventive rather than a curative approach of human postmenopausal
osteoporosis.
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REFERENCES
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