Mechanism of action of estrogen on intramembranous bone formation: regulation of osteoblast differentiation and activity.

Dynamic bone histomorphometry, [3H]thymidine radioautography, and Northern analysis for bone matrix proteins and insulin-like growth factor-I (IGF-I) were performed in calvariae of ovariectomized (OVX) and estrogen-treated OVX rats. Treatment of OVX rats with diethylstilbestrol (DES) for 2 weeks reduced the periosteal mineral apposition rate, osteoblast number, and osteoblast size in calvarial periosteum. DES treatment also reduced the number of preosteoblasts in the S phase of the cell cycle, suggesting that the decrease in osteoblast number was due in part to inhibition of proliferation of osteoprogenitor cells. One week after ovariectomy, there were small increases in mRNA levels for pre pro-alpha 2 (I) subunit of type I collagen (collagen), osteocalcin, and osteonectin and a large increase in the mRNA level for IGF-I. DES treatment resulted in rapid decreases (3 h) in the mRNA levels for osteonectin, osteocalcin, and IGF-I. In contrast, mRNA levels for collagen were virtually unchanged after short term DES treatment. Uterus and liver served as positive and negative control tissues, respectively, for the effects of DES on IGF-I mRNA levels in OVX rats; mRNA levels were increased in uterus and decreased in liver after hormone treatment. We conclude from these studies that estrogen reduces periosteal bone formation by inhibiting both the differentiation and activity of osteoblasts. Furthermore, down-regulation of mRNA levels for IGF-I and bone matrix proteins precedes the changes in dynamic bone histomorphometry.     

Dose-dependent effects of tamoxifen on long bones in growing rats: influence of ovarian status

Tamoxifen is a nonsteroidal antiestrogen which has been reported by various investigators to have estrogen agonist and antagonist effects on rat bone. These different interpretations may be due to differences in the ovarian status, estrogen levels, and/or tamoxifen levels of the rats. To address this issue, a dose response was determined for the effects of tamoxifen on bone histomorphometry in intact female and ovariectomized (OVX) rats. The results were compared with those obtained after treatment of OVX rats with estrogen alone or a combination of estrogen and tamoxifen. OVX resulted in increases in growth rate (weight gain) and periosteal bone formation rate and decreases in uterine weight and cancellous bone fractional volume (BV/TV). Treatment of OVX rats with estrogen resulted in dose-dependent decreases in growth rate and periosteal bone formation rate as well as dose-dependent increases in uterine weight and BV/TV. Similarly, tamoxifen treatment resulted in dose-dependent decreases in overall growth rate and periosteal bone formation rate in both OVX and intact rats. Tamoxifen treatment prevented the decrease in BV/TV after OVX, although the highest dose of tamoxifen resulted in a small decrease in BV/TV in intact female rats. In contrast to estrogen, tamoxifen treatment prevented the increase in uterine weight in intact female rats as well as the decrease in uterine weight in OVX rats. Tamoxifen treatment did not alter the effects of 17 beta-estradiol on the periosteal bone formation rate in OVX rats, but reduced the increase in BV/TV to values similar to those in intact rats. These results are consistent with tamoxifen behaving as a partial estrogen agonist on rat bone.     

Tamoxifen inhibits osteoclast-mediated resorption of trabecular bone in ovarian hormone-deficient rats

The effects of the nonsteroidal antiestrogen tamoxifen were determined on trabecular bone mass in the proximal tibial metaphysis of intact and ovariectomized rats. Rats were ovariectomized at the beginning of the study. On day 7 of the study, 5-mg slow release pellets of tamoxifen or placebo were implanted sc. All of the rats were killed on day 28 of the experiment. Sections of the proximal tibial metaphysis were stained for acid phosphatase and evaluated histomorphometrically. Ovariectomy resulted in marked loss of bone. Compared to the values in sham-operated animals, the trabecular bone at a sampling site in the secondary spongiosa of ovariectomized rats was reduced by more than 60%, the length of trabecular bone surface covered by osteoclasts was increased by 563%, the percentage of trabecular bone surface covered by osteoclasts was increased by 567%, the mean osteoclast size was increased by 84%, and the number of nuclei per osteoclast was increased by 38%. In contrast, treatment of ovariectomized rats for 3 weeks with tamoxifen restored the histomorphometric measurements to values comparable to those in sham-operated animals. 17 beta-Estradiol increased trabecular bone fractional area in ovariectomized and sham-operated rats, and administration of tamoxifen to estrogen-treated, ovariectomized, and sham-operated animals produced a further increase in trabecular bone. In summary, 1) ovariectomy resulted in large increases in both the number and activity of osteoclasts, 2) the increased bone resorption associated with ovariectomy produced a net loss of trabecular bone, and 3) treatment of ovariectomized rats with tamoxifen prevented these skeletal changes. The results indicate that in the rat, tamoxifen mimics the effects of estrogen on trabecular bone at concentrations that are not uterotropic.     

Disuse exaggerates the detrimental effects of alcohol on cortical bone

BACKGROUND: Alcohol abuse is associated with an increased risk for osteoporosis. However, comorbidity factors may play an important role in the pathogenesis of alcohol-related bone fractures. Suboptimal mechanical loading of the skeleton, an established risk factor for bone loss, may occur in some alcohol abusers due to reduced physical activity, muscle atrophy, or both. The effect of alcohol consumption and reduced physical activity on bone metabolism has not been well studied. The purpose of this study was to determine whether mechanical disuse alters bone metabolism in a rat model for chronic alcohol abuse. METHODS: Alcohol was administered in the diet (35% caloric intake) of 6-month-old male rats for 4 weeks. Rats were hindlimb-unloaded the final 2 weeks of the experiment to prevent dynamic weight bearing. Afterward, cortical bone histomorphometry was evaluated at the tibia-fibula synostosis. RESULTS: At the periosteal surface of the tibial diaphysis, alcohol and hindlimb unloading independently decreased the mineralizing perimeter, mineral apposition rate, and bone formation rate. In addition, alcohol, but not hindlimb unloading, increased endocortical bone resorption. The respective detrimental effects of alcohol and hindlimb unloading to inhibit bone formation were additive; there was no interaction between the two variables. CONCLUSIONS: Reduced weight bearing accentuates the detrimental effects of alcohol on cortical bone in adult male rats by further inhibiting bone formation. This finding suggests that reduced physical activity may be a comorbidity factor for osteoporosis in alcohol abusers.     

雌激素对大鼠去卵巢后白细胞介素-6介导的骨吸收的影响

目的观察雌激素对去卵巢大鼠骨髓细胞白细胞介素6(IL6)、IL6受体、gp130基因表达以及骨髓源性破骨细胞形成的影响。方法健康3月龄雌性SD大鼠72只,随机平均分为假手术对照组、去卵巢组和雌激素组(苯甲酸雌二醇02mg/kg,皮下注射,每周1次)。分别于术后2、4、6、12周每组各取6只大鼠骨髓细胞作细胞培养和提取RNA。培养第6天计数破骨细胞数,第12周取左侧胫骨作骨形态计量学检测。结果骨形态学显示去卵巢后出现骨吸收亢进,雌激素对其有抑制作用。去卵巢后2周,去卵巢组破骨细胞形成数即多于对照组(1450±169对901±141,P<005),骨髓细胞IL6和IL6受体mRNA表达均显著升高(P<005,P<001),第4～6周,上述改变达高峰,至第12周仍呈有意义增高;从2～12周,上述各指标雌激素组均明显低于去卵巢组(P<005,P<001)。各组未见gp130基因表达水平有明显变化。结论雌激素可以抑制大鼠去卵巢后骨髓源性破骨细胞的生成,这一效应可能与其抑制骨髓细胞在去卵巢后过度表达IL6、IL6受体基因有关。     

Restoration of bone mass in the severely osteopenic senescent rat

Studies in humans and rats suggest that age impairs the ability to form bone. This impairment may be due to a depletion or deficit in osteoprogenitor stem cells. Such a deficit would be expected to reduce the ability of the skeleton to respond to therapy designed to restore lost bone. This study evaluated whether severely osteopenic senescent rats are capable of responding to a potent anabolic factor in bone, prostaglandin E2 (PGE). Growing female Sprague Dawley rats were ovariectomized at 3 months and aged until the start of treatment at 23 months. Rats were treated daily with PGE (3 mg/kg sc) or vehicle for 56 days. Tibiae were harvested for bone histomorphometry and femora were obtained for mRNA analysis of bone matrix proteins. The cancellous bone area was fivefold greater in PGE-treated rats than in vehicle-treated controls and not different from age-matched ovary-intact rats. PGE approximately doubled the bone-forming surface and the mineral apposition rate and increased the bone formation rate fourfold. The increased cancellous bone area in PGE-treated rats was primarily due to an increase in osteoblasts over osteoclasts. One hundred percent of the endocortical surface and 72 +/- 9% of the periosteal surface of cortical bone was undergoing mineralization in PGE-treated rats, whereas no mineratization was evident in vehicle-treated rats. An architectural analysis of cancellous bone indicates that trabecular number and thickness were increased and separation decreased in the treated rats. Imaging by microcomputed tomography further revealed that with PGE treatment, trabeculae in the medial plane of the proximal tibial metaphysis were more robust and continuous with the endocortical surface. PGE also significantly induced message levels for the prepro-alpha (I) subunit of type I collagen (collagen), osteonectin, and osteocalcin. In summary, bone mass can be restored to severely osteopenic senescent rats, suggesting that aging does not necessarily diminish the capacity of the skeleton to form bone.     

Estrogen treatment prevents osteopenia and depresses bone turnover in ovariectomized rats

Female Sprague-Dawley rats were subjected to bilateral ovariectomy (OVX) or sham surgery (control). Groups of ovariectomized (OVX) and control rats were injected daily with low, medium, or high doses of 17 beta-estradiol (10, 25, or 50 micrograms/kg BW, respectively). An additional group of OVX and control rats was injected daily with vehicle alone. All rats were killed 35 days after OVX, and their proximal tibiae were processed undecalcified for quantitative bone histomorphometry. Trabecular bone volume was markedly reduced in vehicle-treated OVX rats relative to that in control rats (12.1% vs. 26.7%). This bone loss was associated with a 2-fold increase in osteoclast surface and a 4-fold increase in osteoblast surface. The bone formation rate, studied with fluorochrome labeling, was also significantly elevated in vehicle-treated OVX rats (0.111 vs. 0.026 micron3/micron2.day). In contrast, treatment of OVX rats with the three doses of estradiol resulted in normalization of tibial trabecular bone volume and a decline in histomorphometric indices of bone resorption and formation. Our results indicate that estrogen treatment provides complete protection against osteopenia in OVX rats. The protective mechanism involves estrogenic suppression of bone turnover. These findings are consistent with the skeletal effects of estrogen therapy in postmenopausal women.     

Opposite effects of insulin-like growth factor-I on the formation of trabecular and cortical bone in adult female rats.

We have previously found that in intact adult female rats, 17 beta-estradiol (E2) stimulates trabecular bone formation, which can be detected by triple fluorochrome labeling within a few days of commencing E2 treatment. We have also observed that E2 stimulates trabecular bone formation in ovariectomised (Ovx) rats given 3-amino-1-hydroxypropylidene bisphosphonate (AHPrBP). This anabolic action of E2 is presumably mediated through the local release of growth factors, of which insulin-like growth factor-I (IGF-I) is a strong contender. To assess the role of IGF-I as mediator of the anabolic action of E2 on rat trabecular bone, we examined the effect of daily sc administration of IGF-I (200 micrograms/kg) for 17 days on trabecular bone formation at the proximal tibial metaphysis in experiments using the above two models. Intact animals received fluorochrome labels on days 1, 8, and 15 of IGF-I treatment, and Ovx animals received AHPrBP (0.3 mg/kg) on days 1, 8, and 15 and fluorochrome labels on days 8 and 15. Trabecular surfaces covered by first and second labels only (termed arrested surfaces), second and third labels only (induction surfaces), and all three labels (persisting surfaces) were assessed in intact animals; double labeled surfaces were assessed in Ovx animals. We found that IGF-I increased the longitudinal growth rate in both intact rats and Ovx animals given AHPrBP. However, to our surprise, we found that IGF-I inhibited trabecular bone formation in intact animals, reducing both arrested and persisting trabecular surfaces by approximately 50%. This was associated with a doubling of periosteal bone formation, as measured at the tibial diaphysis. In Ovx animals given AHPrBP, the AHPrBP markedly inhibited trabecular bone formation compared with that in Ovx controls, and IGF-I was without effect. We conclude that, in contrast to E2, IGF-I acts to increase the length and circumference of long bones and, perhaps through reactive mechanisms such as mechanical compensation, reduces rather than stimulates trabecular bone formation.     

Novel bromomelatonin derivatives as potentially effective drugs to treat bone diseases

Several reports indicate that melatonin is involved in the regulation of bone metabolism. To examine the direct effect of melatonin on osteoclasts and osteoblasts, we developed an in vitro assay using fish scales that contain osteoclasts, osteoblasts, and bone matrix, all of which are similar to those found in mammalian membrane bone. Using the assay, we demonstrated that melatonin suppressed osteoclastic and osteoblastic activities. These findings are in agreement with the reports from in vivo studies in mice and rats. In an attempt to develop molecules that increase bone mass, novel bromomelatonin derivatives were synthesized, and the effects of these chemicals on osteoclasts and osteoblasts using the scale assay were examined. As a result, novel bromomelatonin derivatives with the ability to possibly increase bone formation were identified. In scale osteoclasts, particularly, 1-benzyl-2,4,6-tribromomelatonin had a more potent activity than melatonin. In reference to osteoblasts, this agent (10(-9)-10(-6)M) significantly activated osteoblasts. The effect of 1-benzyl-2,4,6-tribromomelatonin on bone formation was confirmed in ovariectomized rats. Thus, the oral administration of 1-benzyl-2,4,6-tribromomelatonin augmented the total bone mineral density of the femoral metaphysis of ovariectomized rats. The stress-strain index of the diaphysis in 1-benzyl-2,4,6-tribromomelatonin-treated rats significantly increased in comparison with that in ovariectomized rats. In rats fed a low-calcium diet, the total bone mineral density of the femoral metaphysis significantly increased following the oral administration of 1-benzyl-2,4,6-tribromomelatonin. These studies identified a melatonin derivative that may have potential use in the treatment of bone diseases, such as osteoporosis.     

Estrogen regulates the rate of bone turnover but bone balance in ovariectomized rats is modulated by prevailing mechanical strain

Estrogen deficiency induced bone loss is associated with increased bone turnover in rats and humans. The respective roles of increased bone turnover and altered balance between bone formation and bone resorption in mediating estrogen deficiency-induced cancellous bone loss was investigated in ovariectomized rats. Ovariectomy resulted in increased bone turnover in the distal femur. However, cancellous bone was preferentially lost in the metaphysis, a site that normally experiences low strain energy. No bone loss was observed in the epiphysis, a site experiencing higher strain energy. The role of mechanical strain in maintaining bone balance was investigated by altering the strain history. Mechanical strain was increased and decreased in long bones of ovariectomized rats by treadmill exercise and functional unloading, respectively. Functional unloading was achieved during orbital spaceflight and following unilateral sciatic neurotomy. Increasing mechanical loading reduced bone loss in the metaphysis. In contrast, decreasing loading accentuated bone loss in the metaphysis and resulted in bone loss in the epiphysis. Finally, administration of estrogen to ovariectomized rats reduced bone loss in the unloaded and prevented loss in the loaded limb following unilateral sciatic neurotomy in part by reducing indices of bone turnover. These results suggest that estrogen regulates the rate of bone turnover, but the overall balance between bone formation and bone resorption is influenced by prevailing levels of mechanical strain.     

Skeletal changes in type-2 diabetic Goto-Kakizaki rats

We characterized appendicular and axial bones in rats with type-2 diabetes in five female Goto-Kakizaki (GK) rats, a strain developed from the Wistar rat showing spontaneous type-2 diabetes, and five age- and sex-matched non-diabetic Wistar rats. The humerus, tibia, metatarsals and vertebral bodies were analysed by peripheral quantitative computerized tomography (pQCT). In diabetic rats, the height of the vertebral bodies and length of the humerus were decreased while the length of the metatarsals was increased. A decreased cross-sectional area was found in the vertebral end-plate region and the tibial metaphysis. Notably, the diaphysis in all long bones showed expansion of periosteal and endosteal circumference. In tibia this resulted in increased cortical thickness, whereas in humerus and metatarsal it was unchanged. Areal moment of inertia was increased in all diaphyses suggesting greater bending strength. The most conspicuous finding in diabetic rats pertained to trabecular osteopenia. Thus, trabecular bone mineral density was significantly reduced in all bones examined, by 33-53%. Our pQCT study of axial and appendicular bones suggests that the typical feature of diabetic osteopathy in the GK rat is loss of trabecular bone and expansion of the diaphysis. The loss of metaphyseal trabecular bone if also present in diabetic patients may prove to underlie the susceptibility to periarticular fracture and Charcot arthropathy. The findings suggest that the risk of fracture in diabetes varies according to the specific sub-regions of a bone. The approach described may prove to be useful in the early detection of osteopathy in diabetic patients who may be amenable to preventive treatment.     

Tissue-selective effects of continuous release of 2-hydroxyestrone and 16alpha-hydroxyestrone on bone, uterus and mammary gland in ovariectomized growing rats.

2-Hydroxyestrone (2-OHE(1)) and 16alpha-hydroxyestrone (16alpha-OHE(1)) have been reported to be risk factors for negative bone balance and breast cancer, respectively. The roles of these two metabolites of estrone as estrogen agonists or antagonists with respect to estrogen target tissues, or both, are poorly defined. The purpose of this study was to characterize metabolite and tissue-specific differences between the actions of hydroxylated estrones on selected reproductive and non-reproductive estrogen target tissues in growing rats. First, the effects of ovariectomy were determined. Ovariectomy had the expected effects, including increases in all dynamic bone measurements at the proximal tibial epiphysis, without induction of bone loss. Second, ovariectomized growing rats were continuously treated for 3 weeks with 2-OHE(1), 16alpha-OHE(1), 17beta-estradiol (E(2)), a combination of E(2) and 2-OHE(1) (E(2)+2-OHE(1)), or a combination of E(2) and 16alpha-OHE(1) (E(2)+16alpha-OHE(1)), using controlled release subcutaneous implanted pellets containing 5 mg 2-OHE(1), 5 mg 16alpha-OHE(1), 0.05 mg E(2) or placebo. E(2) reduced body weight gain and radial and longitudinal bone growth as well as indices of cancellous bone turnover, and increased serum cholesterol, uterine wet weight and epithelial cell height, and proliferative cell nuclear antigen labeling in mammary gland. The hydroxylated estrones did not alter uterine wet weight and 16alpha-OHE(1) antagonized the E(2)-stimulated increase in epithelial cell height. 2-OHE(1) had no effect on cortical bone, whereas 16alpha-OHE(1) was an estrogen agonist with respect to all cortical bone measurements. 16alpha-OHE(1) also behaved as an estrogen agonist with respect to serum cholesterol and cancellous bone measurements. 2-OHE(1) had no effect on most E(2)-regulated indices of cancellous bone growth and turnover, but was a weak estrogen agonist with respect to mineral apposition rate and bone formation rate. Neither estrogen metabolite influenced body weight gain. Third, weanling rats were treated for 1 week with vehicle, E(2) (200 microg/kg per day) or 16alpha-OHE(1) (30, 100, 300, 1000 and 3000 microg/kg per day) to confirm uterotropic effects of daily subcutaneous (s.c.) administration of 16alpha-OHE(1). 16alpha-OHE(1) increased uterine weight in a dose-response manner to values that did not differ from rats treated with E(2). We conclude that the estrogen metabolites 2-OHE(1) and 16alpha-OHE(1) have target tissue-specific biological activities which differ from one another as well as from E(2). These findings add further support to the concept that there are several classes of estrogens with distinct biological activities. Furthermore, differences in the route of administration could influence the tissue specificity of estrogen metabolites.     

Leptin reduces ovariectomy-induced bone loss in rats.

Bone mineral density increases with fat body mass, and obesity has a protective effect against osteoporosis. However, the relationship between fat body mass and bone mineral density is only partially explained by a combination of hormonal and mechanical factors. Serum leptin levels are strongly and directly related to fat body mass. We report here the effects of leptin administration compared with estrogen therapy on ovariectomy-induced bone loss in rats. Leptin was effective at reducing trabecular bone loss, trabecular architectural changes, and periosteal bone formation. Interestingly, the combination of estrogen and leptin further decreased bone turnover compared with that in estrogen-treated ovariectomized rats. Leptin also significantly increased osteoprotegerin mRNA steady state levels and protein secretion and decreased RANK ligand mRNA levels in human marrow stromal cells in vitro. Our findings suggest that leptin could modulate bone remodeling in favor of a better bone balance in rats. This study is the first evidence that leptin therapy has a significant effect in preventing ovariectomy-induced bone loss, and this effect may at least in part be mediated by the osteoprotegerin/RANK ligand pathway.     

雌激素对老年雄性大鼠植入骨新形成的影响

目的　研究雌激素对老年雄性哺乳动物的植入骨的新生骨骨面积及对全身骨代谢的影响。方法　骨基质骨片植入老年雄性大鼠 ,观察注射雌激素组、雄激素组和对照组骨组织计量学、骨生物力学、尿脱氧吡啶啉 /肌酐 (Dpd/Cr)比值 ,以及血和尿的钙、磷等的变化。结果 ( 1)新生骨骨面积 :雌激素组和雄激素组均比对照组明显增高 (P <0 0 5 ) ,雌激素组和雄激素组之间差异无显著性。 ( 2 )破骨细胞数 :雌激素组 ( 5 5± 3)个 /mm2 和雄激素组 ( 5 3± 3)个 /mm2 均显著高于对照组 ( 40± 3)个 /mm2 (P≤ 0 0 0 2 ) ,雌激素组和雄激素组之间差异无显著性。 ( 3)尿Dpd/Cr比值 (mmol/mol) :注药后5周 ,对照组 (注射溶剂 )比注药前明显升高 ( 198± 2 0vs 10 4± 7) ,雌激素组 ( 114± 16 )和雄激素组 ( 118± 19)均比对照组 ( 198± 2 0 )明显减低 ,与注药前无明显差异 ,雌激素和雄激素组之间差异无显著性。结论　雌激素和雄激素不仅能刺激老年雄性大白鼠植入骨的新生骨骨面积增加 ,也能抑制全身骨骼的骨吸收速率。本实验条件下 ,这两方面的影响 ,雌激素和雄激素组之间未见明显差异     

Ovariectomy selectively reduces the concentration of transforming growth factor beta in rat bone: implications for estrogen deficiency-associated bone loss.

Previous work showed that production of transforming growth factor beta (TGF-beta) by osteoblast-like rat UMR 106 cells was increased by 17 beta-estradiol at physiological concentrations. To determine whether ovariectomy alters the concentration of TGF-beta in rat long bones, female Sprague-Dawley rats were either sham-operated (n = 19) or ovariectomized (n = 19), pair-fed a semisynthetic diet for 6 weeks, and sacrificed. Tibial and femoral diaphyses were removed and extracted by demineralization. Ovariectomy lowered serum estrogen; did not alter body weight, serum magnesium, or serum 1,25-dihydroxyvitamin D; and produced only modest differences in serum calcium and phosphate concentrations. Hydroxyproline was higher and extractable protein was lower in bones from ovariectomized rats than in bones from sham-operated rats; calcium content did not differ between the two groups of animals. Ovariectomy lowered the concentration of TGF-beta in bone but did not change the concentration of insulin-like growth factors I or II compared with values in bone from control animals. The reduction of bone TGF-beta was evident 6 weeks after surgery but not at 3 weeks. Treatment of ovariectomized rats with estrogen eliminated the TGF-beta deficit. To determine whether 17 beta-estradiol increased TGF-beta production by normal bone cells, mouse osteoblasts were treated for 2 days with 17 beta-estradiol. The production of TGF-beta was increased almost 2-fold by 1 nM 17 beta-estradiol, and short-term treatment stimulated the intracellular accumulation of TGF-beta 1 mRNA. We conclude that ovariectomy reduces deposition of TGF-beta in rat bone and that diminished skeletal TGF-beta could play a role in the pathogenesis of bone loss, fractures, and microfractures that occur in estrogen-deficient states. Our results support the possibility that estrogen and bone TGF-beta may be necessary for normal maintenance of the skeleton in female rats.     

Long-term treatment of lasofoxifene preserves bone mass and bone strength and does not adversely affect the uterus in ovariectomized rats

The purpose of this study was to determine the long-term effects of lasofoxifene, a new selective estrogen receptor modulator, on bone mass, bone strength, and reproductive tissues in ovariectomized (OVX) rats. Sprague Dawley female rats at 3.5 months of age were OVX and treated orally with lasofoxifene (60, 150, or 300 microg/kg x d) for 52 wk. The urinary deoxypyridinoline/creatinine ratio was significantly lower in all lasofoxifene-treated OVX rats compared with OVX controls at wk 26. Peripheral quantitative computerized tomography analysis of proximal tibial metaphysis showed that the significant loss in trabecular content and density induced by OVX was significantly prevented by lasofoxifene treatment. Proximal tibial and lumber vertebral trabecular bone histomorphometric analysis showed that all doses of lasofoxifene significantly reduced OVX-induced bone loss by decreasing bone resorption and bone turnover. The ultimate strength, energy, and toughness of the fourth lumbar vertebral body in OVX rats treated with all doses of lasofoxifene were significantly higher compared with those in OVX controls, and did not differ significantly from those in sham controls. Uterine weight in OVX rats treated with lasofoxifene was slightly, but significantly, higher when compared with that in OVX controls, but was still much less than that in sham controls. No abnormal finding associated with lasofoxifene was observed with uterine histology examination. In summary, long-term treatment with lasofoxifene preserves bone mass and bone strength and does not adversely affect the uterus in OVX rats. These data suggest that lasofoxifene is an effective antiosteoporosis agent, and its efficacy and safety can be maintained over an extended period of time.     

Influence of glucocorticoid on bone in 3-, 6-, and 12-month-old rats as determined by bone mass and histomorphometry

The influence of glucocorticoid (GC) on bone in rats at different ages was investigated in order to provide insight into human glucocorticoid induced osteoporosis (GCOP). Three-, 6-, and 12-month-old female Wistar rats were divided into four groups: Zero-time control (ZT), vehicle (Cont), prednisolone (PSL) 2 mg/kg (P–L), PSL 20 mg/kg (P–H). PSL was subcutaneously administered every day for 4 weeks. Bone mineral density (BMD) at the proximal metaphysis and diaphysis of the tibia was measured by peripheral quantitative computed tomography. Histomorphometry of the tibia was performed for 3- and 6-month-old rats. GC increased trabecular and cortical BMD at the metaphysis in all 3-month-old rats with time. Trabecular BMD at the metaphysis in the P–L and P–H groups was significantly higher than in the control group. Histomorphometric parameters for both bone formation and resorption were also increased by GC treatment. In the 6-month-old rats, the metaphyseal trabecular BMD did not significantly change in any group, but the diaphyseal trabecular BMD significantly increased in the control group with time. The trabecular BMD of the metaphysis and diaphysis was significantly lower in the P–L and P–H groups than in the control group at week 4. Histomorphometric parameters for bone formation and resorption were both reduced by GC treatment. The BMD remained unchanged in all 12-month-old rats. Six-month-old rats treated with 20 mg/kg GC are suitable models for GC-induced osteoporosis with dominant cancellous bone decrease and reduced bone turnover. The pathology induced by 20 mg/kg prednisolone in 6-month-old female rats seems to be most similar to glucocorticoid-induced osteoporosis in humans.     

Endocrine and pharmacological suppressors of bone turnover protect against osteopenia in ovariectomized rats

This study was designed to test the hypothesis that endocrine and pharmacological suppressors of bone turnover prevent the development of osteopenia during estrogen deficiency. Sham-operated control and ovariectomized (OVX) rats were treated intermittently with vehicle alone, estrogen, or the diphosphonate compounds etidronate disodium (EHDP) and NE-58095 [2-(3-pyridinyl)2-hydroxyethylidene-1,1-bisphosphonate disodium] for 35 or 70 days after surgery. Their proximal tibiae were processed undecalcified for quantitative bone histomorphometry. Vehicle-treated OVX rats were characterized by decreased cancellous bone volume and 3- to 4-fold increases in osteoblast surface, osteoclast surface, bone formation rate, and bone resorption rate. Treatment of OVX rats with estrogen and NE-58095 provided complete protection against bone loss and significantly depressed all of the above indices of bone turnover. OVX rats treated with EHDP exhibited at least partial protection against bone loss and decreased bone turnover. EHDP induced a mild mineralization defect, as indicated by a prolonged mineralization lag time at the tibial endocortical surface. The new diphosphonate compound NE-58095 did not impair bone mineralization. Our results indicate that endocrine and pharmacological suppressors of bone turnover prevent the development of osteopenia during the early stages of estrogen deficiency. If confirmed by clinical trials in humans, diphosphonate compounds may prove to be an alternative to estrogen for the prevention of postmenopausal bone loss.     

Influence of glucocorticoid on bone in 3-, 6-, and 12-month-old rats as determined by bone mass and histomorphometry

Abstract

The influence of glucocorticoid (GC) on bone in rats at different ages was investigated in order to provide insight into human glucocorticoid induced osteoporosis (GCOP). Three-, 6-, and 12-month-old female Wistar rats were divided into four groups: Zero-time control (ZT), vehicle (Cont), prednisolone (PSL) 2 mg/kg (P–L), PSL 20 mg/kg (P–H). PSL was subcutaneously administered every day for 4 weeks. Bone mineral density (BMD) at the proximal metaphysis and diaphysis of the tibia was measured by peripheral quantitative computed tomography. Histomorphometry of the tibia was performed for 3- and 6-month-old rats. GC increased trabecular and cortical BMD at the metaphysis in all 3-month-old rats with time. Trabecular BMD at the metaphysis in the P–L and P–H groups was significantly higher than in the control group. Histomorphometric parameters for both bone formation and resorption were also increased by GC treatment. In the 6-month-old rats, the metaphyseal trabecular BMD did not significantly change in any group, but the diaphyseal trabecular BMD significantly increased in the control group with time. The trabecular BMD of the metaphysis and diaphysis was significantly lower in the P–L and P–H groups than in the control group at week 4. Histomorphometric parameters for bone formation and resorption were both reduced by GC treatment. The BMD remained unchanged in all 12-month-old rats. Six-month-old rats treated with 20 mg/kg GC are suitable models for GC-induced osteoporosis with dominant cancellous bone decrease and reduced bone turnover. The pathology induced by 20 mg/kg prednisolone in 6-month-old female rats seems to be most similar to glucocorticoid-induced osteoporosis in humans.     

Improved bone biomechanical properties in xylitol-fed aged rats.

Our previous studies have shown that dietary xylitol protects against weakening of bone biomechanical properties in experimental postmenopausal osteoporosis. To study whether xylitol preserves bone biomechanics also during aging, a long-term experimental study was performed with rats. Twenty-four male Sprague-Dawley rats were divided into 2 groups. The rats in the control group (NON-XYL group) were fed a basal rat and mouse no. 1 maintenance (RM1) diet, while the rats in the experimental group (XYL group) were continuously fed the same diet supplemented with 10% xylitol (wt/wt). The rats were killed after 20 months. Their femurs were prepared for biomechanical analyses and scanning analyses with peripheral quantitative computed tomography (pQCT). In 3-point bending of the femoral diaphysis, maximum load, maximum elastic load, stiffness, energy absorption, elastic energy absorption, ultimate stress, and yield stress were significantly greater in the XYL group than in the NON-XYL group. This indicates a xylitol-induced improvement of both structural and material strength properties of cortical bone. Accordingly, the maximum load of femoral neck was significantly greater in the XYL group. In the pQCT analysis of femoral diaphysis, cortical bone area, cortical thickness (CtTh) periosteal circumference, and cross-sectional moment of inertia were greater in the XYL group. The endosteal circumference was smaller in the XYL group. In the pQCT analysis of the femoral neck cortical area of the midneck was significantly greater in the XYL group. This data indicates that xylitol exerted beneficial effects on the cross-sectional architecture of the bones. In conclusion, continuous moderate dietary xylitol supplementation leads to improved bone biomechanical properties in aged rats concerning both bone structural and material strength properties.