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Introduction

Osteoporosis is a metabolic bone disease, which results from a disturbance in normal bone remodeling such that the balance shifts from bone formation to resorption; this in turn may lead to bone loss and the occurrence of fractures following mineral flux (1). Patients with osteoporosis exhibit a high frequency of fractures, and hip fractures in senile patients are particularly serious since they often limit the life of a patient (2). At present, osteoporosis affects ~25 million Americans (3). It has been estimated that a 50-year-old woman in the United States has an 11–18% lifetime risk of suffering a hip fracture (3).

Numerous attempts have been made to develop novel agents for the prevention and treatment of bone diseases (4). At present, anti-resorptive agents, including biophosphonate, estrogen and calcitonin, are widely used (5); however, there is a requirement for highly effective resorptive inhibitors with improved safety and efficacy profiles. Anabolic agents, which are able to stimulate bone formation, are less well-known (6); however, trials to develop anabolic agents have been conducted, and have improved current understanding of the mechanisms underlying osteoblast differentiation and bone formation (7).

The estrogen-deficient, ovariectomized (OVX) rat model of osteoporosis has been considered useful for the evaluation of osteoporotic drugs, since various parameters associated with osteoporosis have been shown to be markedly decreased within 4–6 weeks following an ovariectomy (8). The OVX rat model of osteoporosis was selected for the present study as it approximates postmenopausal bone loss, as demonstrated by previous studies (8–10). A rat model was selected in particular as a 4-month study of rats is considered to be comparable to a 1-year study of humans (11). The effects of a drug in the OVX rat model may be assessed by detecting histomorphometrical alterations in bone mass, formation and resorption, and changes in bone weight, blood chemistry, urinalysis, bone mineral content (BMC), bone mineral density (BMD) and failure load (FL) (12).

Bone remodeling by bone cells is crucial in determining and increasing the bone mass during pathological conditions, including bone disorders (13). There are two major therapeutic strategies for patients with osteoporosis: Reducing bone turnover or increasing mineral deposition at bones. Alendronate and other bisphosphonates, which inhibit bone-turnover, have been prescribed to millions of patients worldwide, and have exhibited good safety profiles, with reports of only minor side effects (14,15). Alendronate is a nitrogen-containing bisphosphonate and a potent inhibitor of bone resorption, which has been used to treat and prevent osteoporosis, in addition to exhibiting anti-osteoporosis effects in OVX animals and postmenopausal women (16,17). Conversely, the parathyroid hormone, which has been developed to treat osteoporosis, is able to stimulate osteoblastic bone formation, increase bone mass and prevent vertebral fractures (18). Similarly, bone formation may be induced by treatment with strontium ranelate (19). Our previous mouse and in vitro studies demonstrated that Polycan was able to prevent bone loss by reducing net bone resorption and bone turnover (20,21). In addition, an increase in bone-specific alkaline phosphatase (bALP) expression levels was indicative of an increase in bone formation following treatment with Polycan (20,21).

β-glucan is a fiber-type complex polysaccharide derived from the cell wall of baker's yeast, oat and barley fiber, and numerous medicinal mushrooms (22). β-glucan is primarily used to enhance the immune system (23) and lower blood cholesterol levels (24). Polycan, which is purified β-glucan derived from Aureobasidium pullulans SM-2001, predominantly consists of β-1,3/1,6-glucan, as well as other organic materials, including amino acids, mono- or di-unsaturated fatty acids (linoleic and linolenic acids) and fibrous polysaccharide (25). Previous studies have demonstrated that Polycan was able to exert anti-osteoporosis effects, including inhibiting bone loss and accelerating bone formation in vitro and in OVX mice (20,21), and promoting the healing of fractures (26). However, to the best of our knowledge, the effects of Polycan in a rat model of osteoporosis have yet to be evaluated. Therefore, the present study aimed to investigate the effects of Polycan (31.25, 62.5 and 125 mg/kg), in comparison with the effects of alendronate, in a rat model of ovariectomy-induced osteoporosis.

Materials and methods

Rats

A total of 96 virgin Sprague-Dawley pathogen-free female rats (age, 6 weeks; weight, 137–173 g; Charles River Laboratories, Inc., Yokohama, Japan) were used in the present study, following a 7-day acclimatization period. The rats were maintained in polycarbonate cages at 20–25°C and 30–35% humidity, under a 12-h light/dark cycle and with access to food (Samyang Foods Co., Ltd., Wonju, Korea) and water ad libitum. A total of 80 rats were assigned to the experimental group (OVX-induced osteoporosis) and 16 rats were assigned to the sham control group. Following the ovariectomy procedure, 48 rats were selected for inclusion in the study, based on their body weight and behavior, according to the Guide for the Care and Use of Laboratory Animals from the Institute for Laboratory Animal Research (Washington, D.C., USA). The present study was approved by the Institute of Laboratory Animal Resources at Daegu Haany University (DHU2011-015; Gyeongsan, Korea).

Test articles, grouping and dosing

Polycan derived from A. pullulans SM-2001 (Glucan Co., Ltd., Busan, Korea) was stored in a refrigerator at 4°C. The Polycan consisted of 13% β-1,3/1,6-glucan and 40% β-glucan, as demonstrated using analytical methods described in a previous study (25). The 48 rats were grouped as follows (n=8 rats/group): A sham control group, an OVX control group, an alendronate group, and 3 groups of rats treated with 31.25, 62.5 and 125 mg/kg polycan, respectively. The Polycan was diluted in distilled water to 62.5, 31.25 and 125 mg/kg, and was administered by gastric gavage using a 3-ml syringe. The Polycan was administered daily for 126 days, commencing one week following the ovariectomy procedure. A 10-mg/kg dose of alendronate (Merck & Co., Inc., Whitehouse Station, NJ, USA) was generated by dissolving the alendronate in distilled water.

Surgical procedure

The rats in the experimental group underwent a bilateral ovariectomy following intraperitoneal injection with 25 mg/kg Zoletile (Virbac S.A., Carros, France), as described in a previous study (27). In the sham control group, the bilateral ovariectomy procedure was conducted without removal of the ovaries. Following the surgical procedure, the rats were divided into 6 groups (8 rats/group; a sham control group, an OVX control group, an alendronate group, and 3 polycan groups with various dosages).

Bone labeling

For dynamic histomorphometry, all rats were treated subcutaneously with 30 mg/kg/ml tetracycline (Sigma-Aldrich, St. Louis, MO, USA) 13 days prior to sacrifice, and 8 mg/kg/ml calcein (Sigma-Aldrich) 3 days prior to sacrifice. Briefly, tetracycline binds to newly formed bone at the bone/osteoid (unmineralized bone) interface where it exhibits linear fluorescence. Fluorescence was observed under a UV light microscope (model Eclipse 80i; Nikon Corporation, Tokyo, Japan). Animal sacrifice was carried out under anesthesia with 0.05 ml/kg Zoletile by exsanguination from the caudal vena cava. Animals with unintended problems (including cachexia and abnormal clinical signs) were sacrificed by cervical dislocation.

Body weight alterations

The body weight of all rats was measured prior to the initial treatment and once per week during the experimental period, concluding at sacrifice as described above. Blood was collected from the caudal vena cava and centrifuged at 720 × g for 30 min. The supernatant was collected using a micropipette. Prior to the body weight measurements at the initial dosing and at sacrifice, the experimental animals were fasted overnight in order to reduce the occurrence of errors due to feeding. Alterations in the body weight were calculated as the body weight at sacrifice minus the body weight at the initial treatment, in order to eliminate individual differences.

Serum biochemistry

Blood samples (10 ml) were collected from the vena cava at sacrifice, and the serum was separated. All serum samples were frozen at −40°C until required for further experimentation. Serum levels of osteocalcin (ng/ml) were detected using an Osteocalcina Myria kit (Technogenetics Srl, Milan, Italy) and a Packard Cobra II γ-counter (GMI, Inc., Ramsey, MN, USA). Serum levels of bALP (U/L) were detected using the commercially available Enzyme-Immunoassay kit (Metra™ bALP kit; cat. no. 8012; Quidel Corporation, San Diego, CA, USA). The serum calcium (Ca) levels (mg/ml) were detected using the Orthocresolphthalein Complexone (OCPC) method and an automated blood analyzer (TBA 200FR; Toshiba, Tokyo, Japan). Briefly, the OCPC complexone (P5631; Sigma-Aldrich) method is based on the reaction of Ca2+ with o-cresolphthalein complexone in an alkaline solution, which forms an intense violet fluorescence which maximally absorbs at 577 nm. 8-hydroxyquionline is added to prevent interference by magnesium and iron. The serum phosphorus (P) levels were detected using the kinetic ultraviolet (UV) method using a blood biochemistry autoanalyzer (Dri-Chem NX500i; Fujifilm Medical System Co., Ltd., Tokyo, Japan).

Urinalysis

Urine from individual rats was collected over a 24-h period following the final treatment, and was centrifuged at 720 × g for 10 min to remove sediments. The levels of deoxypyridinoline (Dpd; nM) in the urine were detected using a commercial Enzyme-Immunoassay kit (Metra™ Dpd kit; cat. no. 8007; Quidel Corporation) and an enzyme-linked immunosorbent assay plate reader (Tecan Schweiz AG, Männedorf, Switzerland). The levels of creatinine (g/day) in the urine were detected using the Jaffe reaction and an automated urine analyzer (model TBA-2000FR; Toshiba). In addition, the Dpd/creatinine ratios were measured.

BMC

Following sacrifice, the right side of the femur and tibia, as well as the 4th lumbar vertebrae (L4), were harvested and dried at 120°C for 8 h. The dried tibiae underwent carbonization at 800°C for 6 h in a furnace, after which they were dissolved in nitric acid. In a dissolved solution, the Ca and P concentrations (mg/g) were calculated using the OCPC and kinetic UV methods, respectively. In addition, the Ca/P ratio was calculated using the following formula: Ca/P ratio = (bone Ca content/bone P content) × 100.

BMD and FL

The BMD (g/cm2) of the epiphyseal plates and body of the right femur and tibia was measured using dual-energy X-ray absorption (Lunar PIXImus; GE Healthcare Bio-Sciences, Pittsburgh, PA, USA). In addition, the BMD of the articulate regions and body of the L4 was determined prior to BMC measurement. The bone strength was measured in terms of FL. The FL (newtons, N) of the mid-shaft regions of the right femur and tibia was measured using a three-point bending test to failure on a computerized testing machine (Instron 6022; Instron, Norwood, MA, USA; speed, 20 mm/min). In addition, the FL of the L4 body was measured.

Histology and histomorphometry

The left side of the femur and tibia, and the 5th lumbar vertebrae (L5) of each rat were separated, dehydrated in a graded series of ethanol and xylene, and embedded undecalcified in modified methyl methacrylate (Araldite/Embed Embedding kit; cat. no. 13940; Electron Microscopy Sciences, Hatfield, PA, USA). Subsequently, the samples were sectioned (3–4 µm) and stained with hematoxylin and eosin staining. A section was left unstained for dynamic histomorphometry. For each prepared sample, the histological profiles (osteoporotic hole) were observed under a microscope (Carl Zeiss AG, Oberkochen, Germany).

Bone histomorphometry was conducted using automated image analysis processing software (analySIS® AUTO; SiS Sensoren Instrumente Systeme GmbH, Schwentinental, Germany), as outlined in a previous report (28). Briefly, in order to determine the bone mass and structure, the trabecular bone volume (Tb.Ar), thickness (Tb.Wi), number (N.Tb) and length (Tb.Pm), and the cortical bone thickness (Ct.Wi), were measured. In order to determine the extent of bone resorption, the osteoclast cell number (N.Oc) in uniform regions of the epiphyseal plates (N/epiphyseal), and the osteoclast cell surface/bone surface (Oc/BS%), were determined. In order to measure the rate of bone formation (µm/day), the mineral appositional rate (MAR) in the trabecular and cortical regions was determined by dividing the distance between the midpoints of the two labels by the time interval between the labeling periods (10 days). The single labeled surface (sL.Pm) corresponded to the trabecular or cortical surface covered with single label (tetracycline only), and was expressed as a percentage of the bone surface. The double labeled surface (dL.Pm) corresponded to the bone surface covered with both labels (tetracycline and calcein) and was expressed as a percentage of the bone surface. The mineralizing surface (Md.Pm) was calculated using the following equation: Md.Pm (%) = [(1/2 sL.PM) + dL.Pm]. The surface referent bone formation rate (BFR/BS), which corresponded to the amount of new bone mineralized at the tissue level per mm2 of bone surface area per day, was calculated using the following equation: BFR/BS (µm3/µm2/day) = Md.Pm × MAR.

Statistical analysis

Data are presented as the mean ± standard deviation. Data was analyzed using one-way analysis of variance, followed by a least-significant difference multiple comparison test, in order to determine which pairs of group comparisons were significantly different. When a significant difference was detected using the Kruskal-Wallis H test, a Mann-Whitney U test was conducted, in order to determine the specific pairs of group comparisons that were significantly different. Statistical analyses were performed using SPSS software version 14.0 (SPSS, Inc., Chicago, IL, USA). P<0.05 and P<0.01 were considered to indicate statistically significant and highly statistically significant differences, respectively.

Results

Alterations in body weight

A significant increase in body weight was detected in the OVX rats compared with the sham control group at 7 and 126 days following the initial treatment (P<0.01). There was no significant difference in body weight alterations between the treated groups (alendronate and Polycan-treated groups) and the OVX control group (Table I).

Table I. Rat body weight in the various groups.

Table I.

Rat body weight in the various groups.

	Body weight
Group	Day 0 (A)	Day 7	Day 126 (B)	Gain (B - A)
Sham control	181.63±5.48	207.75±3.92	283.13±13.05	101.50±12.81
OVX control	182.25±4.89	227.63±6.82a	337.88±25.95a	155.63±22.03a
Alendronate	178.75±10.59	225.25±16.15b	318.38±37.75	139.63±31.37a
Polycan
31.25 mg/kg	176.75±11.42	223.10±18.02b	329.88±41.27b	153.13±33.36a
62.5 mg/kg	178.25±4.65	227.88±8.63a	338.25±22.93a	160.00±21.73a
125 mg/kg	177.75±6.45	221.63±9.46a	333.00±32.26a	125.25±30.41

{ label (or @symbol) needed for fn[@id='tfn1-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats. All rats were fasted overnight prior to the first treatment and 126 days following the initial treatment.

a P<0.01

b P<0.05 vs. sham control group. OVX, ovariectomized.

Alterations in serum biochemistry

The serum levels of osteocalcin were significantly increased in the OVX control group compared with the sham control group (P<0.01; Table II). A significant reduction in the serum levels of bALP, Ca and P was detected in the OVX control group compared with the sham control group (P<0.01). Conversely, marked dose-dependent reductions in the serum levels of osteocalcin, and elevations in the serum levels of bALP, Ca and P were detected in the Polycan-treated groups compared with the OVX control group (P<0.05). The serum levels of osteocalcin were significantly decreased in the alendronate-treated group compared with the OVX control group (P<0.01); however, no significant differences in the serum levels of bALP, Ca and P were detected between the alendronate-treated group and the OVX control group (Table II).

Table II. Alterations in serum biochemistry.

Table II.

Alterations in serum biochemistry.

Group	Osteocalcin (ng/ml)	bALP (U/l)	Ca (mg/dl)	P (mg/dl)
Sham control	1.349±0.185	1.425±0.238	9.338±0.774	6.650±0.960
OVX control	2.031±0.205a	0.963±0.160a	8.400±0.288a	5.570±0.289a
Alendronate	1.621±0.276b	1.000±0.273a	8.738±0.667	5.286±0.576a
Polycan
31.25 mg/kg	1.908±0.086a	1.213±0.181c	8.863±0.555c	5.595±0.452a
62.5 mg/kg	1.801±0.141a,c	1.238±0.220b	8.963±0.504c	6.028±0.339c
125 mg/kg	1.760±0.167a,b	1.300±0.141b	9.013±0.344b	6.044±0.417

{ label (or @symbol) needed for fn[@id='tfn4-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01 vs. sham control group.

b P<0.01

c P<0.05 vs. OVX control group. OVX, ovariectomized; bALP, bone-specific alkaline phosphatase; Ca, calcium; P, phosphorus.

Alterations in urinalysis

Significantly increased urine Dpd levels and Dpd/creatinine ratios were detected in the OVX control group compared with the sham control group (P<0.01). Conversely, dose-dependent reductions in the urine Dpd levels and Dpd/creatinine ratios were detected in the Polycan-treated groups compared with the OVX control group (Table III).

Table III. Alterations in urinalysis.

Table III.

Alterations in urinalysis.

Group	Dpd (nM)	Creatinine (g/day)	Dpd/creatinine (nM/g/day)
Sham control	37.13±6.36	0.0061±0.0016	6,589.14±2,065.59
OVX control	57.53±4.99a	0.0059±0.0009	9,948.74±1,681.29a
Alendronate	35.94±12.75b	0.0057±0.0013	6,344.94±1,898.94c
Polycan
31.25 mg/kg	49.73±10.15d	0.0068±0.0019	7,858.53±2,496.99
62.5 mg/kg	49.73±5.33a,c	0.0065±0.0006	7,781.32±1,156.59b
125 mg/kg	49.69±8.70a,b	0.0065±0.0006	7,751.24±1,556.92b

{ label (or @symbol) needed for fn[@id='tfn8-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01

d P<0.05 vs. sham control group.

b P<0.05

c P<0.01 vs. OVX control group. OVX, ovariectomized; Dpd, deoxypyridinoline.

Alterations in BMC

Significantly decreased levels of Ca and P were detected in the femur, tibia and L4 of the OVX control group compared with the sham control group (P<0.01). Conversely, significant increases in the BMC were detected in all treated groups (P<0.05). No significant alterations in Ca/P ratios were detected in any of the groups (Table IV).

Table IV. Alterations in bone mineral contents.

Table IV.

Alterations in bone mineral contents.

				Polycan-treated groups
Bone	Sham control	OVX control	Alendronate	31.25 mg/kg	62.5 mg/kg	125 mg/kg
Femur
Ca mg/g bone	170.86±13.75	95.82±17.78a	120.95±12.40a,b	106.05±14.02c	125.12±9.03a,b	138.07±16.11a,b
P mg/g bone	98.71±7.56	57.29±11.04a	73.60±13.18a,b	63.19±9.20c	76.48±11.47a,d	83.30±10.28c,d
Ca/P ratio	1.74±0.16	1.70±0.34	1.69±0.34	1.70±0.28	1.67±0.29	1.68±0.29
Tibia
Ca mg/g bone	196.13±9.74	103.82±15.02a	133.37±21.61a,d	110.14±14.66c	128.77±10.45a,d	140.72±15.00a,d
P mg/g bone	99.66±11.83	52.67±7.66a	67.93±7.47a,d	55.54±6.04c	67.11±6.52a,d	70.00±7.12a,d
Ca/P ratio	1.99±0.22	1.99±0.31	1.99±0.42	2.00±0.31	1.93±0.17	2.03±0.28
L4
Ca mg/g bone	210.14±8.35a	124.41±12.48a	138.50±9.19a	138.10±13.87c	146.84±16.78a,b	155.79±11.09a,d
P mg/g bone	113.50±13.77a	66.91±8.53a	74.12±7.24a	75.61±12.46c	78.77±10.05a,b	83.25±6.81a,d
Ca/P ratio	1.87±0.23	1.90±0.45	1.88±0.20	1.87±0.38	1.88±0.23	1.88±0.16

{ label (or @symbol) needed for fn[@id='tfn13-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01

c P<0.05 vs. sham control group.

b P<0.05

d P<0.01 vs. OVX control group. OVX, ovariectomized; L₄, 4th lumbar vertebrae.

Alterations in BMD and FL

The BMD and FL of the tibia, femur and L4 were significantly decreased in the OVX control group compared with the sham control group (P<0.01). Conversely, significantly increased BMD and FL were detected in all three types of bone in the majority of the Polycan-treated groups compared with the OVX control group (P<0.05). However, the rats treated with 31.25 mg/kg Polycan did not exhibit significant increases in BMD and FL compared with the OVX control group (Table V).

Table V. Alterations in BMD and FL in the rat femur, tibia and L4 verterae.

Table V.

Alterations in BMD and FL in the rat femur, tibia and L4 verterae.

				Polycan-treated groups
Bone	Sham control	OVX control	Alendronate	31.25 mg/kg	62.5 mg/kg	125 mg/kg
Femur
Epiphyseal BMD	0.378±0.040	0.213±0.032a	0.513±0.107a,b	0.253±0.026a,c	0.286±0.030a,b	0.293±0.021a,b
Mid-shaft BMD	0.336±0.036	0.189±0.025a	0.224±0.027a,c	0.228±0.032a,c	0.251±0.037a,b	0.265±0.029a,b
FL	119.03±8.68	70.48±11.39a	83.50±7.70a,c	78.03±6.39a	86.30±6.08b,c	88.33±10.02a,c
Tibia
Epiphyseal BMD	0.305±0.023	0.199±0.017a	0.385±0.066a,b	0.221±0.034a	0.249±0.026a,b	0.268±0.046b
Mid-shaft BMD	0.291±0.015	0.179±0.023a	0.195±0.024a	0.209±0.020a,c	0.224±0.025a,b	0.243±0.042a,b
FL	79.61±2.44	50.96±6.27a	55.69±11.18a	57.25±4.78a	62.06±3.52a,b	63.41±5.05a,b
L4
Epiphyseal BMD	0.338±0.034	0.225±0.023a	0.255±0.030a,c	0.249±0.026a	0.258±0.025a,c	0.293±0.015a,b
Mid-shaft BMD	0.305±0.021	0.186±0.028a	0.199±0.022a	0.205±0.016a	0.238±0.019a,b	0.256±0.033a,b
FL	66.20±5.35	42.20±8.25a	50.06±11.14a	48.93±5.85a	50.60±6.03a,c	57.08±6.25b,d

{ label (or @symbol) needed for fn[@id='tfn18-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01

d P<0.05 vs. sham control group.

b P<0.01

c P<0.05 vs. OVX control group. OVX, ovariectomized; L₄, 4th lumbar vertebrae; BMD, bone mineral density; FL, failure load.

Alterations in bone histomorphometry

Relatively well-developed and compact trabecular and cortical bone regions were observed in the femur of the sham control group rats. Conversely, the OVX control group exhibited a histological profile that was typical for osteoporosis, including marked reductions in the trabecular and cortical bone masses, and increased levels of connective tissue in the periosteum of the cortical bone due to the resorption of osteoid tissues. Alterations in the bone histomorphometry were markedly decreased in the Polycan-treated groups, particularly within the cortical bone, as compared with the OVX control group (Fig. 1). In the OVX control group, an increased MAR, as indicated by the distance between the tetracycline and calcein labeling regions, was observed in the cortical and trabecular bone regions, as compared with the sham control group. Conversely, a dose-dependent increase in MAR was detected in the cortical and trabecular bone regions of the Polycan-treated groups, as compared with the OVX control group. In the alendronate-treated group, the MAR in all three bones tested was markedly decreased compared with the OVX control group (Fig. 2).

Figure 1. Histological profiles of the femur of the (A and B) sham, (C and D) ovariectomized control and (E and F) alendronate-treated groups, and the (G and H) 31.25, (I and J) 62.5 and (K and L) 125 mg/kg Polycan-treated groups. Polycan inhibited the ovariectomy-induced reduction in trabecular bone mass and cortical bone thickness in a dose-dependent manner. Conversely, alendronate attenuated the ovariectomy-induced reduction in trabecular bone mass only. A, C, E, G, I and K display epiphyseal plate-trabecular bone regions (magnification, ×25); B, D, F, H, J, and L display cortical bone regions (magnification, ×50). Arrows represent the cortical thickness. All sections were stained with hematoxylin and eosin.

Figure 2. Fluorescent histological profiles of the femur of the (A and B) sham, (C and D) ovariectomized (OVX) control and (E and F) alendronate-treated groups, and the (G and H) 31.25, (I and J) 62.5 and (K and L) 125 mg/kg Polycan-treated groups. The mineral apposition rate (MAR) was markedly increased in the trabecular and cortical bone regions of the femur in the Polycan-treated rats, in a dose-dependent manner, as compared with the OVX control group. Conversely, the MAR was markedly decreased in both bone regions of the femur in the alendronate-treated rats, as compared with the OVX control group. A, C, E, G, I and K display trabecular bone regions (magnification, ×200); B, D, F, H, J and L display cortical bone regions (magnification, ×200). Arrows indicate the tetracycline and calcein labeled lines. The distant between the arrows represents the MAR over a 10-day period.

Bone mass and structures

Significant reductions in the Tb.Ar, N.Tb, Tb.Wi, Tb.Pm and Ct.Wi were detected in the tibia, femur and L5 of the OVX control rats, as compared with the sham control rats (P<0.01). Conversely, significant (P<0.05) dose-dependent increases in the histomorphometric indices for bone mass and structure were detected in all three bones from the Polycan-treated rats compared with the OVX control, with the exception of the 31.25 mg/kg-treated group, in which no significant increases in these indices were observed (Tables VI–VIII).

Table VI. Alterations in femur histomorphometry.

Table VI.

Alterations in femur histomorphometry.

				Polycan treated groups
Indices	Sham control	OVX control	Alendronate	31.25 mg/kg	62.5 mg/kg	125 mg/kg
Bone mass and structure
Tb.Ar	42.66±5.11	16.48±4.03a	62.49±4.93a,b	20.62±3.78a	23.90±3.28a,b	25.91±4.99a,b
N.Tb	20.88±3.36	6.38±1.85a	40.38±8.18a,b	8.00±1.69a	10.50±1.51a,b	11.50±2.00a,b
Tb.Pm	1,895.31±306.08	949.62±152.97a	1,265.30±196.52a,b	1,069.78±145.09a	1,308.83±321.95a,c	1,326.88±271.85a,b
Tb.Wi	112.70±10.97	75.33±10.21a	76.35±13.93a	100.92±25.73c	103.86±20.33b	122.20±21.61b
Ct.Wi	454.86±67.54	210.30±26.04a	200.93±27.21a	329.64±79.46a,c	367.91±36.69a,b	370.46±83.22b
Bone resorption
N.Oc	13.00±1.41	27.00±3.63a	35.63±10.65a	27.13±3.52a	25.25±3.49a	20.25±2.25a,b
Oc/BS	4.72±0.79	10.96±1.22a	9.12±1.18a,c	10.62±1.53a	10.54±0.90a	9.13±1.15a,c
Trabecular bone formation
MAR	0.95±0.13	1.54±0.11a	0.71±0.08a,b	1.67±0.12a,b	1.82±0.20a,c	1.85±0.23a,b
sL.Pm	7.17±1.22	13.21±1.56a	4.29±0.38a,b	14.24±1.04a	15.87±2.36a,c	16.12±2.44a,c
dL.Pm	14.39±3.14	24.73±3.92a	7.96±0.97a,b	27.37±3.14a	29.41±3.23a,c	31.25±4.49a,b
Md.Pm	17.97±3.64	31.33±4.53a	10.11±1.14a,b	34.50±3.60a	37.35±4.20a,c	39.31±5.58a,b
BFR/BS	0.173±0.054	0.484±0.091a	0.072±0.013a,b	0.579±0.094a	0.685±0.138a,c	0.738±0.208a,b
Cortical bone formation
MAR	1.17±0.13	1.78±0.14a	0.76±0.09a,b	1.82±0.16a	1.98±0.08a,b	2.06±0.17a,b
sL.Pm	8.22±1.57	15.27±1.70a	4.21±0.96a,b	15.00±1.95a	17.27±1.25a,c	17.94±1.25a,b
dL.Pm	15.54±3.01	30.71±2.10a	7.76±1.87a,b	29.91±2.86a	34.18±2.72a,c	35.54±2.94a,b
Md.Pm	19.65±3.78	38.34±2.72a	9.86±2.32a,b	37.41±3.82a	42.82±3.28a,c	44.51±3.46a,b
BFR/BS	0.233±0.068	0.684±0.093a	0.076±0.026a,b	0.685±0.126a	0.850±0.091a,b	0.922±0.146a,b

{ label (or @symbol) needed for fn[@id='tfn23-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01 vs. sham control group.

b P<0.01

c P<0.05 vs. OVX control group. OVX, ovariectomy; Tb.Ar, trabecular bone volume (%); N.Tb, trabecular bone number; Tb.Pm, trabecular bone length (mm), Tb.Wi, trabecular bone thickness (µm); Ct.Wi, cortical bone thickness (µm); N.Oc, osteoclast cell number (no.); Oc/BS, osteoclast cell surface/bone surface (%); MAR, mineral appositional rate (µm/day); sL.Pm, single labeled surface (%); dL.Pm, double labeled surface (%); Md.Pm, mineralizing surface (%); BFR/BS, bone forming rate/bone surface referent (µm³/µm²/day).

Table VIII. Alterations in L5 histomorphometry.

Table VIII.

Alterations in L5 histomorphometry.

				Polycan treated groups
Indices	Sham control	OVX control	Alendronate	31.25 mg/kg	62.5 mg/kg	125 mg/kg
Bone mass and structure
Tb.Ar	40.20±6.73	20.30±4.07a	51.66±9.66a,c	23.78±2.71a,d	27.18±3.42a,c	30.31±2.44a,c
N.Tb	20.38±4.66	9.13±1.36a	28.00±4.34b,c	10.75±0.89a,d	11.88±0.64a,c	12.00±1.69a,c
Tb.Pm	1,597.39±311.46	900.66±158.97a	1,212.59±194.92b,d	1,239.49±239.10b,c	1,409.77±369.62c	1,538.50±211.31c
Tb.Wi	130.11±18.75	86.26±10.63a	69.03±5.64a,d	114.09±13.49c	124.98±26.79c	130.69±24.9c
Ct.Wi	221.60±28.28	120.44±34.25a	123.35±33.39a	154.38±23.34a,d	164.45±26.12a,c	166.47±45.03a,d
Bone resorption
N.Oc	11.63±1.41	23.00±2.14a	30.75±5.55a,c	23.63±2.20a	20.75±1.58a,d	19.63±2.62a,d
Oc/BS	3.90±0.68	12.09±0.86a	9.48±1.01a,c	11.61±1.30a	10.07±1.23a,c	9.57±0.92a,c
Trabecular bone formation
MAR	0.83±0.12	1.20±0.09a	0.77±0.10c	1.31±0.10a	1.33±0.15a	1.43±0.08a,c
sL.Pm	4.91±1.35	9.79±0.92a	4.07±0.59c	10.26±1.05a	11.22±1.34a,d	11.71±1.34a,c
dL.Pm	9.23±2.21	18.81±2.68a	7.92±1.09c	19.75±2.33a	22.36±2.21a,d	22.99±2.34a,c
Md.Pm	11.69±2.86	23.71±3.03a	9.95±1.33c	24.88±2.66a	27.97±2.79a,d	28.85±2.97a,c
BFR/BS	0.099±0.036	0.287±0.055a	0.078±0.017c	0.327±0.055a	0.374±0.074a,d	0.413±0.063b,c
Cortical bone formation
MAR	1.01±0.12	1.37±0.13a	0.84±0.13b,c	1.62±0.20a,c	1.78±0.14a,c	1.87±0.10a,c
sL.Pm	6.96±1.30	10.76±0.75a	5.87±1.52c	13.04±2.56a,d	14.62±1.35a,c	12.79±1.45a,c
dL.Pm	13.45±2.63	22.00±2.32a	10.57±2.39b,c	25.83±5.52a	28.66±2.53a,c	31.79±2.26a,c
Md.Pm	16.93±3.25	27.39±2.61a	13.50±3.15c	32.37±6.79a	35.97±2.80a,c	39.68±2.94a,c
BFR/BS	0.174±0.054	0.375±0.051a	0.117±0.043b,c	0.536±0.188a,d	0.640±0.081a,c	0.743±0.095b,c

{ label (or @symbol) needed for fn[@id='tfn32-etm-0-0-3485'] } Data are presented as the mean ± standard deviation of 8 rats.

a P<0.01

b P<0.05, vs. sham control group.

c P<0.01

d P<0.05, vs. OVX control group. OVX, ovariectomy; Tb.Ar, trabecular bone volume (%); N.Tb, trabecular bone number; Tb.Pm, trabecular bone length (mm), Tb.Wi, trabecular bone thickness (µm); Ct.Wi, cortical bone thickness (µm); N.Oc, osteoclast cell number (no.); Oc/BS, osteoclast cell surface/bone surface (%); MAR, mineral appositional rate (µm/day); sL.Pm, single labeled surface (%); dL.Pm, double labeled surface (%); Md.Pm, mineralizing surface (%); BFR/BS, bone forming rate/bone surface referent (µm³/µm²/day).

Bone resorption

Significant increases in N.Oc and Oc/BS were detected in all three bones from the OVX control group, as compared with the sham control group (P<0.01). However, they appeared to be significantly decreased by Polycan treatment in a dose-dependent manner (P<0.05; Tables VI–VIII).

Bone formation

Significant increases in the MAR, Md.Pm and BFR/BS were detected in the trabecular and cortical bone regions of all three bone types in the OVX control group compared with the sham control group (P<0.01). Conversely, the histomorphometrical indices for bone formation were significantly increased in the trabecular and cortical bone regions in the Polycan-treated groups compared with the OVX control group, in a dose-dependent manner. An exception was the 31.25 mg/kg Polycan-treated group, in which no significant increases in the histomorphometrical indices for bone formation were detected (P>0.05; Tables VI–VIII).

Discussion

The present study investigated the protective effects of Polycan in a rat model of ovariectomy-induced osteoporosis by measuring alterations in the BMC, BMD, FL, serum levels of osteocalcin, bALP, Ca and P, urine Dpd/creatinine ratios and histomorphometrical indices.

In a previous study, changes in the body weight (lean and/or fat mass) of OVX rodents was used to predict bone density (29); however, no significant ovariectomy-induced alterations in body weight were detected in the present study.

Osteocalcin is a protein secreted by mature osteoblasts, levels of which have previously been shown to correlate with active bone formation and resorption (30). In the present study, the serum levels of osteocalcin were significantly decreased in OVX mice following treatment with Polycan for 126 days; thus suggesting that Polycan may inhibit high bone turnover. bALP levels are generally accepted as a marker of bone formation (12). Decreased serum bALP levels by OVX were significantly and dose-dependently inhibited by Polycan treatment. Increased serum levels of Ca and P have previously been demonstrated to be a marker of bone formation in animal models of osteoporosis (31,32). In the present study, increased serum levels of Ca and P were detected in the Polycan-treated groups compared with the OVX control group; thus suggesting that Polycan was able to inhibit the OVX-induced reduction in serum Ca and P levels. These results suggested that Polycan may improve bone formation in a dose-dependent manner.

Urine Dpd levels, which are considered to be a marker of bone resorption, alter in response to alterations in the levels of creatinine, which is an indicator of kidney state (33). Therefore, urine Dpd/creatinine ratios are considered a valuable marker of bone resorption in osteoporosis (12). In the present study, Polycan markedly attenuated ovariectomy-induced increases in the urine Dpd/creatinine ratios; thus suggesting that Polycan was able to decrease ovariectomy-induced bone resorption. Similar effects have been observed in OVX rats treated with alendronate (34).

Patients with osteoporosis typically exhibit a significantly decreased BMC (35). Among the various minerals that comprise bone, the levels of Ca and P have been shown to be the most significantly decreased in osteoporotic bones, although the Ca/P ratio is not typically altered (36). In the present study, the concentrations of Ca and P in the tibia, femur and L4 bones of the Polycan-treated rats were significantly increased compared with the OVX control group, and this was associated with increases in bone strength and quantity, as determined by BMD.

BMD is considered to be a valuable clinical indicator of alterations in bone quality, and has been shown to be significantly decreased in animals with osteoporosis, regardless of the underlying cause. Furthermore, BMD has previously been used to predict the efficacy of anti-osteoporosis agents (37), and has provided diagnostic profiles of bone quality in human clinical research (38). In the present study, Polycan was able to inhibit ovariectomy-induced decreases in BMD; thus suggesting that Polycan may be used to prevent and/or treat osteoporosis-associated fractures.

FL is an key index for predicting the efficacy of anti-osteoporosis agents (39), since it has been directly correlated with cortical bone strength. In the present study, Polycan was able to improve the FL; thus suggesting that Polycan may directly inhibit ovariectomy-induced reductions in bone strength.

Bones may be observed under the microscope in order to analyze alterations in bone morphology (40). The histomorphometrical indices of bone mass and structure, and bone resorption, have been shown to be markedly decreased in patients with osteoporosis; thus they may be considered reliable markers for predicting the efficacy of anti-osteoporosis agents (41). In the present study, the histomorphometric indices for bone mass and structure, and bone resorption, were markedly reduced in the Polycan-treated rats. In a previous study, the histomorphometric indices for bone formation were increased in OVX animals due to an increase in bone turnover (42). In a previous study, dynamic histomorphometric indices have been shown to be a reliable indicator of whether a test compound is able to promote bone-formation (43). Therefore, the increase in the histomorphometric indices of bone formation in the Polycan-treated rats in the present study suggested that Polycan may exert bone anabolic effects. Increases in the histomorphometrical indices of bone formation have previously been demonstrated for other bone anabolic agents, including the parathyroid hormone analogs (44). However, they were not detected following treatment with selective estrogen receptor modulators (12) and bisphosphonate (45). Furthermore, alendronate has been shown to stabilize the indices for bone mass and structure and bone resorption; however, dynamic histomorphometry demonstrated that the indices for bone formation were markedly decreased following treatment with alendronate (45,46).

The results of the present study suggested that Polycan was able to effectively inhibit ovariectomy-induced changes associated with osteoporosis through the promotion of osteoblast differentiation and bone formation, and the inhibition of bone resorption and osteoclast activity, as has been previously demonstrated in mouse and in vitro studies (20,21). The present study demonstrated that Polycan was able to preserve bone mass and strength, and to increase the rate of bone formation in the trabecular and cortical bone regions in OVX rats; thus suggesting that Polycan may be considered a potentially effective anti-osteoporosis agent. Further studies are required in order to determined how Polycan is able to stimulate the biomarkers of bone formation and absorption.

Acknowledgements

The present study was supported by the National Research Foundation of Korea, and funded by the Korea government (grant no. 2011-0030124) and the Korea Healthcare Technology R&D Project, Ministry for Health, Welfare and Family Affairs, Korea (grant no. A091049-1012-0000400).

References