Enhanced immunoreceptor tyrosine-based activation motif signaling is related to pathological bone resorption during critical illness.

Prolonged critically ill patients present with distinct alterations in calcium and bone metabolism. Circulating bone formation markers are reduced and bone resorption markers are substantially elevated, indicating an uncoupling between osteoclast and osteoblast activity, possibly resulting in pronounced bone loss, impaired traumatic or surgical fracture healing, and osteoporosis. In addition, we have previously shown that increased circulating osteoclast precursors in critically ill patients result in increased osteoclastogenesis in vitro, possibly through FcγRIII signaling. In the current study, we investigated the effects of sustained critical illness on bone metabolism at the tissue level in a standardized rabbit model of prolonged (7 days), burn injury-induced critical illness. This in vivo model showed a reduction in serum ionized calcium and osteocalcin levels, as is seen in humans. Trabecular area, bone mineral content, and -density were decreased in sick rabbits [by 43% (p<0.01), 31% (p<0.01), and 29% (p<0.05), respectively], as was the trabecular gene expression of osteoblast and angiogenesis markers, indicating decreased bone formation and impaired vascularization. There was no change in the expression of osteoclast differentiation markers from the canonical RANK/RANKL/OPG pathway, however, there was an increase in expression of markers from the non-canonical, immunoreceptor tyrosine-based activation motif (ITAM) signaling pathway, FcγRIII, and DAP12 (148% and 59%, respectively; p<0.01). The current study has shown a detrimental effect of prolonged critical illness on trabecular bone integrity, possibly explained by reduced osteoblast differentiation and angiogenesis, coupled with increased osteoclastogenesis signaling that may be mediated via the non-canonical immunoreceptor tyrosine-based activation motif signaling pathway.

[Electroconvulsive therapy for patients with intracranial aneurysms: a case study and literature review]. / Elektroconvulsietherapie bij patiënten met intracraniële aneurysmata: gevalsbespreking en overzicht van de literatuur.

BACKGROUND: Electroconvulsive therapy (ect) is an effective treatment for severe psychiatric disorders, such as mood disorders and schizophrenia. ect is a safe treatment, even in the presence of somatic comorbidity. There are no absolute contraindications to ect, although a few somatic conditions can constitute an increased risk. ect causes a transient increase in blood pressure and heart rate and an increase in cerebral blood flow. In the presence of intracranial vascular malformations such as aneurysms, these haemodynamic changes can, in theory, increase the risk of bleeding. AIM: To determine the safety of ect for patients with an intracranial aneurysm. METHODS: We performed a Medline-search of articles published from 1967 to 2007 using Mesh-terms 'electroconvulsive therapy', 'central nervous system vascular malformations', 'intracranial arteriovenous malformations' and 'intracranial aneurysm', and the search term 'intracranial vascular malformations'. The literature data was supplemented with a case report concerning a man with bipolar disorder and a treated aneurysm of the internal carotid artery, a ventriculoperitoneal drain and hypertension, who was treated with ect. RESULTS: The literature reported 15 cases in which ect was administered to patients with a treated or untreated aneurysm. In most cases blood-pressure-lowering steps were taken. There were no reports of any complications connected with the presence of the aneurysm. Even in the case described, ect was successful and without complications. CONCLUSION: The presence of intracranial aneurysms is no contraindication to ect. Blood pressure should be carefully monitored. It may be worth considering the use of antihypertensive agents and/or an anaesthetic with blood-pressure-lowering qualities. Prior to the application of ect careful attention should be given to the possible advantages and disadvantages of the treatment, and in addition the psychiatric and somatic state of the patient should be taken into account.

Bone and mineral metabolism in BB rats with long-term diabetes. Decreased bone turnover and osteoporosis.

The effect of long-term diabetes mellitus on bone and mineral metabolism was studied in BB rats. Diabetic rats were treated with 1 U of long-acting insulin every other day for 12 wk and compared with nondiabetic littermates. Urinary calcium excretion was increased greater than 10-fold, but serum total and diffusible calcium remained normal. Serum concentrations of both 1 alpha, 25-dihydroxyvitamin D3 and vitamin D-binding protein were significantly decreased in diabetic rats. The intestinal calbindin-D 9K concentration was decreased by nearly 50%, and active duodenal calcium absorption was totally abolished. Trabecular bone volume measured in the tibial metaphysis was decreased by 44%, and the osteoblast and osteoid surfaces were less than 10% of values observed in control rats, whereas the osteoclast surface was unchanged by diabetes. The daily bone formation (bone mineral apposition rate) measured by labeling twice with calcein was decreased by 86% in diabetic rats. The serum concentration of osteocalcin, a biochemical marker of osteoblast function, was similarly decreased (mean +/- SE 23 +/- 3 and 62 +/- 4 micrograms/L in diabetic [n = 15] and nondiabetic [n = 15] rats, respectively). Serum osteocalcin was significantly correlated with the serum concentration of insulinlike growth factor I (r = 0.89, P less than 0.001). Bone strength measured as the energy needed to fracture the femur was markedly decreased (5.3 +/- 1.4 and 8.4 +/- 1.3 N.m.degree in diabetic and nondiabetic rats, respectively; P less than 0.01). These histological, chemical, and biomechanical data clearly indicate that long-standing diabetes in BB rats results in severe low-turnover osteoporosis probably related to decreased osteoblast recruitment and/or function.

Evidence from the aged orchidectomized male rat model that 17beta-estradiol is a more effective bone-sparing and anabolic agent than 5alpha-dihydrotestosterone.

This study was designed to evaluate the impact of estrogen versus androgen action on orchidectomy (ORX)-induced bone loss and associated changes in body composition. During an experimental period of 4 months, aged (12-month-old) ORX rats were treated with 17beta-estradiol (E2; 0.75 microg/day) or different doses of the nonaromatizable androgen 5alpha-dihydrotestosterone (DHT; 45, 75, and 150 microg/day, respectively), via subcutaneous (sc) silastic implants. Low doses of DHT and E2 inhibited the ORX-induced rise of bone turnover markers (serum osteocalcin and urinary deoxypyridinoline [DPD]) to a similar extent. High-dose DHT prevented the ORX-induced decrease of trabecular bone density but had no significant effect on cortical thinning as assessed by peripheral quantitative computed tomography (pQCT). This bone-sparing action of DHT occurred at the expense of hypertrophy of the ventral prostate and seminal vesicles. On the other hand, E2 restored both trabecular bone density and cortical thickness in ORX rats and even prevented age-related bone loss. In contrast to DHT, E2 increased lean body mass and inhibited the ORX-associated increase of fat mass, as measured by DXA. Administration of E2 was associated with increased serum concentrations of insulin-like growth factor (IGF) I and decreased circulating levels of leptin. We conclude that, in the aged ORX rat model, E2 is more effective in preventing ORX-induced bone loss than DHT. Additionally, E2 has anabolic effects on muscle tissue and prevents the ORX-related increase of fat mass. Overall, these data suggest that androgen action on bone and body composition is dependent on stimulation of both androgen receptors (ARs) and estrogen receptors (ERs).

Increased bone formation in mice lacking plasminogen activators.

UNLABELLED: Plasminogen activators tPA and uPA are involved in tissue remodeling, but their role in bone growth is undefined. Mice lacking tPA and uPA show increased bone formation and bone mass. The noncollagenous components of bone matrix are also increased, probably from defective degradation. This study underlines the importance of controlled bone matrix remodeling for normal endochondral ossification. INTRODUCTION: Proteolytic pathways are suggested to play a role in endochondral ossification. To elucidate the involvement of the plasminogen activators tPA and uPA in this process, we characterized the long bone phenotype in mice deficient in both tPA and uPA (tPA-/-:uPA-/-). MATERIALS AND METHODS: Bones of 2- to 7-day-old tPA-/-:uPA-/- and wild-type (WT) mice were studied using bone histomorphometry, electron microscopy analysis, and biochemical assessment of bone matrix components. Cell-mediated degradation of metabolically labeled bone matrix, osteoblast proliferation, and osteoblast differentiation, both at the gene and protein level, were studied in vitro using cells derived from both genotypes. RESULTS: Deficiency of the plasminogen activators led to elongation of the bones and to increased bone mass (25% more trabecular bone in the proximal tibial metaphysis), without altering the morphology of the growth plate. In addition, the composition of bone matrix was modified in plasminogen activator deficient mice, because an increased amount of proteoglycans (2x), osteocalcin (+45%), and fibronectin (+36%) was detected. Matrix degradation assays showed that plasminogen activators, by generating plasmin, participate in osteoblast-mediated degradation of the noncollagenous components of bone matrix. In addition, proliferation of primary osteoblasts derived from plasminogen activator-deficient mice was increased by 35%. Finally, osteoblast differentiation and formation of a mineralized bone matrix were enhanced in osteoblast cultures derived from tPA-/-:uPA-/- mice. CONCLUSIONS: The data presented indicate the importance of the plasminogen system in degradation of the noncollagenous components of bone matrix and suggest that the accumulation of these proteins in bone matrix--as occurs during plasminogen activator deficiency--may in turn stimulate osteoblast function, resulting in increased bone formation.

Bone and mineral metabolism in the adult guinea pig: long-term effects of estrogen and androgen deficiency.

The effects of androgen and estrogen deficiency on skeletal homeostasis were studied in the guinea pig. Male and female adult (7 months old) guinea pigs were either sham operated (9 females and 7 males) or gonadectomized [9 ovariectomized (OVX) females and 6 orchidectomized (ORX) males] and sacrificed 4 months later for evaluation of bone mass, bone turnover, and serum calcium homeostasis. Parameters of bone turnover, calcium homeostasis, and vitamin D metabolites were similar in all groups except for increased serum IGF-I concentrations (+30%) in males compared to females. Gonadectomy resulted in a 50% decrease in serum IGF-I concentrations in males only (p < 0.001). Volume, total calcium content, and cortical density of the tibia were significant higher in males than in females. Estrogen deficiency had no effect on bone volume or calcium content. Androgen deficiency resulted in a significant lower volume and calcium content of the tibia and in a lower calcium content of the distal lumbar vertebrae. Single-photon absorptiometry of the tibia showed that only cortical, not trabecular bone density of the tibia was decreased after ORX. Histomorphometric studies of the tibial metaphysis also did not show significant differences in trabecular bone volume between sham-operated and ORX males. We conclude that in adult male guinea pigs androgen deficiency results in a decrease in (cortical) bone volume and content concomitant with decreased IGF-I levels. In female guinea pigs of the same age, estrogen deficiency did not affect total or regional bone mass.

Intestinal calcium transporter genes are upregulated by estrogens and the reproductive cycle through vitamin D receptor-independent mechanisms.

UNLABELLED: 1alpha,25(OH)2-vitamin D strongly regulates the expression of the epithelial calcium channel CaT1. CaT1 expression is reduced in ERKOalpha mice and induced by estrogen treatment, pregnancy, or lactation in VDR WT and KO mice. Estrogens and vitamin D are thus independent potent regulators of the expression of this calcium influx mechanism, which is involved in active intestinal calcium absorption. INTRODUCTION: Active duodenal calcium absorption consists of three major steps: calcium influx into, transfer through, and extrusion out of the enterocyte. These steps are carried out by the calcium transport protein 1 (CaT1), calbindin-D9K, and the plasma membrane calcium ATPase (PMCA1b), respectively. We investigated whether estrogens or hormonal changes during the female reproductive cycle influence the expression of these genes, and if so, whether these effects are vitamin D-vitamin D receptor (VDR) dependent. MATERIALS AND METHODS: We evaluated duodenal expression patterns in estrogen receptor (ER)alpha and -beta knockout (KO) mice, as well as in ovariectomized, estrogen-treated, pregnant, and lactating VDR wild-type (WT) and VDR KO mice. RESULTS: Expression of calcium transporter genes was not altered in ERKObeta mice. CaT1 mRNA expression was reduced by 55% in ERKOalpha mice, while the two other calcium transporter genes were not affected. Ovariectomy caused no change in duodenal expression pattern of VDR WT and KO mice, whereas treatment with a pharmacologic dose of estrogens induced CaT1 mRNA expression in VDR WT (4-fold) and KO (8-fold) mice. Pregnancy enhanced CaTI expression equally in VDR WT and KO mice (12-fold). Calbindin-D9K and PMCA1b expression increased to a lesser extent and solely in pregnant VDR WT animals. In lactating VDR WT and KO mice, CaT1 mRNA expression increased 13 times, which was associated with a smaller increase in calbindin-D9K protein content and PMCA1b mRNA expression. CONCLUSIONS: Estrogens or hormonal changes during pregnancy or lactation have distinct, vitamin D-independent effects at the genomic level on active duodenal calcium absorption mechanisms, mainly through a major upregulation of the calcium influx channel CaT1. The estrogen effects seem to be mediated solely by ERalpha.

Effects of recombinant human growth hormone and insulin-like growth factor-I, with or without 17 beta-estradiol, on bone and mineral homeostasis of aged ovariectomized rats.

This study aimed to evaluate whether recombinant human growth hormone (rhGH) or insulin-like growth factor-I (rhIGF-I) can reverse or prevent further bone loss in aged osteopenic ovariectomized (OVX) rats and to compare their effects with those of 17 beta-estradiol (E2). Twelve-month-old rats were OVX, remained untreated for 8 weeks, and subsequently received daily subcutaneous (SC) injections of rhGH (75 micrograms/day), rhIGF-I (250 micrograms/day), E2 (1.5 micrograms/day), and their respective combinations during 8 weeks, and were then compared with sham-operated, pretreatment OVX, and saline-treated OVX rats. A single sc injection of rhGH resulted in peak hGH concentrations after 90 minutes, with a half-life of 124 minutes; the highest plasma IGF-I concentrations were reached 45 minutes after rhIGF-I injection (+57% vs. baseline) with a gradual decline thereafter. Measurements included: biochemical parameters of bone remodeling (plasma osteocalcin and urinary pyridinolines); histomorphometry of proximal tibial metaphysis; DXA of femur; biomechanical analysis of femur and fifth lumbar vertebra (L5); plasma 1,25-dihydroxyvitamin D3 (1,25(OH)2D3), and calbindin-D9K in duodenal mucosa. Whereas all E2-treated OVX rats had much suppressed bone remodeling, rhGH or rhIGF-I had no effect on any biochemical or histomorphometrical parameter of remodeling. The bone mineral density (BMD) at the distal femoral metaphysis as well as parameters of strength at L5 were maintained at pretreatment values in OVX rats treated with E2, GH, or IGF-I, but not in saline-treated OVX rats; their effects were not additive, however. Trabecular bone volume in the tibial metaphysis was also higher in rats treated with these agents than in saline-treated rats, but this was more apparent at the primary than at the secondary spongiosa, suggesting that their mechanism of action is on primary spongiosa formation or breakdown. E2 alone was ineffective to augment the BMD at the femoral diaphysis; however, the diaphyseal BMD was 12-14% higher (p < 0.01) after 8 weeks of GH treatment than in pretreatment or saline-treated OVX rats and sham-operated rats, while IGF-I was less effective than GH, GH or IGF-I treatment had no effect on plasma 1,25(OH)2D3 or duodenal calbindin-D9K concentrations, but the combination of GH or IGF-I with E2 potentiated the effect of E2 to stimulate calbindin-D9K concentrations and urinary calcium excretion, indicating "hyperabsorption hypercalciuria." In conclusion, the administration of rhGH and rhIGF-I, like that of E2, into aged OVX rats prevents further loss of bone mass and strength at sites containing trabecular bone. In addition, rhGH increases cortical bone mass above pretreatment values.

Brittle bones in spontaneously diabetic female rats cannot be predicted by bone mineral measurements: studies in diabetic and ovariectomized rats.

Spontaneously diabetic BB rats were sham operated (SO) or ovariectomized (OVX) within days after onset and studied after 4, 8, and 12 weeks. Analyses included histomorphometry of proximal tibial metaphyses, biochemical analyses of humeri, DXA analyses, and biomechanical testing of femora. In SO diabetic rats, no osteoblasts, osteoid tissue, or osteoclasts were present on the trabecular bone surface, but trabecular bone volume (TBV) remained normal compared with control BB rats. The concentration of IGF-I per dry weight of humerus was decreased after 12 weeks of diabetes, whereas the concentrations of calcium and osteocalcin did not change. DXA analysis showed normal bone mineral density (BMD) at both diaphyseal and metaphyseal femoral areas. On biomechanical testing, angular deformation, energy absorption, and torsional strength of the femora were decreased after 8-12 weeks of diabetes, but stiffness was normal. Ovariectomy in diabetic rats caused a decrease in femoral BMD especially at the metaphysis, and there was a trend toward decreased TBV in the tibial metaphysis; TBV loss was less marked than in control OVX rats, however. The increase in BMD at the femoral diaphysis, measured after 12 weeks of OVX in control rats, was absent in diabetic rats. Multiple-regression analysis indicated that the presence of diabetes but not ovariectomy, weight, and mineral content correlated with decreased energy absorption, angular deformation, and strength of the femora. The data infer that the (near) absence of unmineralized bone matrix in severely diabetic rats alters bone microarchitecture and ultimately results in brittle bones, which is not predicted by BMC or BMD measurements.

Bone and mineral metabolism in the androgen-resistant (testicular feminized) male rat.

Androgens have important effects on bone in vivo, possibly by direct activation of the androgen receptors in osteoblasts. To test this hypothesis, calcium homeostasis, bone mass, and bone turnover were evaluated in mature (4-month-old) androgen-resistant (testicular feminized, TFM) male rats. Data were compared with data from both female and male littermates of the same age and strain. Compared to normal males, TFM had similar serum testosterone, twofold higher estradiol and estrone, and sixfold higher androstenedione concentrations. Compared to normal females, TFM rats showed lower estradiol but also elevated concentrations of androstenedione and estrone. Despite similar free 1,25-(OH)2D3 concentrations, both TFM and male rats maintained higher serum calcium and phosphate concentrations than their female littermates. Serum IGF-I concentrations in TFM rats were decreased compared to male rats (-12%) or female rats (-27%). Serum osteocalcin concentrations, however, were twofold higher in TFM rats than in females but not significantly different from males. Femoral length, diameter, and cortical thickness were intermediate between those of males and females. The cancellous bone density of the femur and cancellous bone volume of the proximal metaphysis of the tibia, however, were not significantly different between groups. The ash weight of the tibia was also not significantly different, and the ash weight of the four distal lumbar vertebrae ranged between male and female values. Bone mechanical properties as measured by torsional strength and energy absorption of the femur were lower in TFM than in females but not different from males.(ABSTRACT TRUNCATED AT 250 WORDS)

Pretreatment with growth hormone-releasing peptide-2 directly protects against the diastolic dysfunction of myocardial stunning in an isolated, blood-perfused rabbit heart model.

Brief coronary occlusion followed by reperfusion leads to reversible myocardial dysfunction (stunning) which can induce irreversible damage of other organ systems. We studied the effects of pretreatment with recombinant human GH (rhGH) and the GH-secretagogue GHRP-2 on myocardial stunning in a blood-perfused isolated rabbit heart model. In a first set of experiments, effects of bolus rhGH administration (3.5 mg/kg) (n = 5) into the aortic root of unpretreated animals were compared with those of saline (n = 6). In a second set, animals were pretreated for 14 days with SC rhGH 3.5 mg/kg x day (n = 9) or 160 microg/kg x day GHRP-2 (n = 8) in two divided doses. Body weight and plasma concentrations of rhGH, rabbit GH (rGH) and IGF-I were determined before and at the end of 14 days pretreatment. Hearts were excised and submitted to 15 min ischemia followed by 80 min reperfusion, after which postischemic recovery was compared with nonischemic hearts mounted into the same system. At study end, all hearts were snap-frozen to examine markers of apoptosis. Circulating levels of rabbit GH (rGH) remained identical in all animals. Pretreatment with rhGH for 14 days induced a 142 +/- 116% rise of serum IGF-I vs. 8 +/- 15% with GHRP-2 (P < 0.001) and increased body weight with 6.8 +/- 2.5% vs. 3.4 +/- 3.3% with GHRP-2 (P = 0.01). A bolus injection of rhGH did not alter myocardial function compared with saline allowing data from these experiments to be pooled into one ischemic control group for further analysis of the effect of pretreatment. No difference in postischemic recovery of left ventricular systolic function among the unpretreated, rhGH pretreated and GHRP-2 pretreated hearts was apparent. At the end of reperfusion, a 3-fold higher end-diastolic pressure (EDP) persisted in the unpretreated and rhGH pretreated hearts compared with the nonischemic hearts. In the GHRP-2 pretreated hearts, EDP decreased to half the pressure observed in unpretreated and rhGH pretreated hearts (all P < or = 0.02), a level which was indistinguishable from that in the non-ischemic hearts, suggesting full postischemic recovery of diastolic function. There were no signs of increased apoptosis in the experimental groups. In conclusion, 14 days pretreatment with GHRP-2, but not rhGH, protected selectively against the diastolic dysfunction of myocardial stunning in this model. This observation may open perspectives for GH-secretagogues as cardioprotective agents.

Aromatase inhibition impairs skeletal modeling and decreases bone mineral density in growing male rats.

Aromatization of androgens into estrogens may explain some of the skeletal action of androgens. We examined the effect of the aromatase inhibitor Vorozole (VOR) on skeletal growth and mineral accumulation in growing 6-week-old male Wistar rats. Rats were either Sham-operated (Sham) or Orchidectomized (Orch) and treated with or without the aromatase inhibitor VOR. One Sham-operated group was killed at Baseline (Base); the four other groups (Sham, Sham + VOR, Orch, Orch + VOR) were killed 18 weeks after surgery. As expected, all groups gained body weight, but body weight gain was significantly (-25%) lower in Orch, Orch + VOR, and Sham + VOR. Both bone formation, as assessed by serum osteocalcin, and bone resorption, as assessed by urinary (deoxy)pyridinoline, decreased significantly in all groups compared with Base. Orchidectomy resulted in a relative increase of biochemical markers of bone formation and resorption compared with Sham. Treatment with VOR, however, resulted only in a very moderate increase of (deoxy)pyridinoline compared with Sham. As expected, femoral length increased compared with Base, but orchidectomy reduced the relative growth of the femur whereas VOR did not influence femoral length. Ex vivo, densitometric and geometric properties of the femora were evaluated by peripheral computerized quantitative tomography (pQCT) and dual-energy x-ray absorptiometry (DXA). The lumbar vertebrae were measured by DXA. At the end of the experimental period, volumetric trabecular bone mineral density (vTBMD) measured at the distal end of the femur was significantly lower not only in both Orch groups but also in Sham + VOR. The decrease of cancellous bone density in Sham + VOR was lower than in the orchidectomized animals. A relative decrease of femoral inner and outer diameters compared with Sham and Base was observed in both Orch groups and in Sham + VOR, suggesting that both orchidectomy and VOR-treatment inhibited periosteal bone formation and endosteal bone resorption. Only orchidectomy, however, resulted in a decrease of cortical thickness. Bone area, mineral content, and density of both femora and lumbar vertebrae, measured by DXA, were decreased to a similar extent by VOR and Orch (bone mineral content of the femur was 467 +/- 18 mg in Orch and 461 +/- 10 mg in Sham +/- VOR vs. 521 +/- 11 mg in Sham; P < 0.001). In conclusion, treatment with the aromatase inhibitor VOR impairs body weight gain and skeletal modeling and decreases bone mineral density. Aromatase inhibition had similar final effects on bone mass and size as castration, but with less marked effects on bone turnover.

Bone and mineral metabolism in aged male rats: short and long term effects of androgen deficiency.

Both short and long term effects of androgen deficiency and steroid replacement therapy on skeletal homeostasis were investigated in aged (13-month-old) male rats. The animals were either sham operated (n = 28) or orchidectomized (orch; n = 89). The orch animals were divided into 5 groups; 26 rats received an empty sc Silastic implant (orch), all others received an implant containing testosterone (T), 5 alpha-dihydrotestosterone (DHT), 17 beta-estradiol (E2), or nandrolone (Nandro; 15-16 rats in each group). Half of the rats were killed 1 month (short term experiment) after implantation; the others were killed 4 months after implantation (long term experiment). Short term androgen deficiency caused a significant increase in both serum osteocalcin and histomorphometric parameters of bone turnover measured at the proximal tibial metaphysis, but not in a significant decrease in bone mass at this site. This increase in bone turnover was prevented not only by T and DHT, but also by E2 and Nandro. Long term androgen deficiency resulted in a decrease in the calcium content of both tibia and lumbar vertebrae. Cancellous bone volume in the proximal tibial metaphysis was +/- 50% lower in the orch group (P less than 0.001) 4 months after orchidectomy. At the same time, cortical bone was lost in orch rats; femoral cortical thickness was reduced by 12% (P less than 0.01), and cortical density tended to be lower. T, DHT, E2, or Nandro treatment completely prevented this decrease in cortical thickness and density. T and Nandro were also able to prevent the cancellous bone loss. DHT could only partly prevent cancellous bone loss. E2 treatment resulted not only in a sustained decrease in both serum osteocalcin concentrations and histomorphometric indices of bone turnover, but also in a net gain of cancellous bone volume (P less than 0.05 vs. sham). No significant differences in serum concentrations of vitamin D metabolites or nephrogenous cAMP were observed between groups in both short and long term experiments. We conclude that bone mass in aged male rats was significantly decreased 4 months after orchidectomy, preceded by an early increase in bone turnover. Both the early increase in bone turnover and the later decrease in bone mass were prevented by aromatizable and nonaromatizable androgens by estrogen and by nandralone.

An aged rat model of partial androgen deficiency: prevention of both loss of bone and lean body mass by low-dose androgen replacement.

The aim of this study was to evaluate the effects of different doses of androgen replacement, both on body composition and bone, in an aged male orchidectomized rat model. Testosterone was administered by 0.5, 1, and 2.5-cm sc SILASTIC implants (release of, respectively, 11.5, 23, and 55 microg/day) to aged (12 months old, +/- 550 g) male orchidectomized Wistar rats during a 15-week experimental period. T 0.5 only partially prevented decrease of ventral prostate and seminal vesicle weight, compared with an intact group that received an empty implant (Intact). The 1-cm implant (T 1) completely prevented decrease of both seminal vesicles and ventral prostate weight. The 2.5-cm implant (T 2.5) was clearly supraphysiological, as demonstrated by significant hypertrophy of both androgen-sensitive organs. Serum testosterone was lower in T 0.5 and T 1 (0.38 +/- 0.06 ng/ml and 0.92 +/- 0.06 ng/ml, respectively) and higher in T 2.5 (2.4 +/- 0.28. ng/ml), compared with both Intact (1.6 +/- 0.23 ng/ml) and the baseline group(1.6 +/- 0.11 ng/ml). As expected, orchidectomized rats that received an empty SILASTIC implant had significantly lower bone mineral content (-7.9%), apparent density (-5.7%), and lean body mass (-10.8%), as measured by dual-energy x-ray absorptiometry, without significant changes in body weight and fat mass, compared with Intact. Also, cancellous (-50.3%) and cortical (-1.8%) volumetric density, as measured by peripheral quantitative computed tomography, were decreased in the tibia. Bone turnover, as measured by serum osteocalcin and urinary deoxypyridinoline excretion, was increased in orchidectomized rats that received an empty SILASTIC implant. T 0.5 prevented all changes, not only in bone mineral content, density, and turnover but also in lean body mass. Moreover, there were no significant differences, for all these parameters, between the different doses of testosterone replacement. In conclusion, low-dose androgen replacement does not lead to lower bone mineral density, higher bone turnover, and lower lean body mass in aged male rats, whereas complete androgen deficiency does. Therefore, the threshold concentration of testosterone necessary for prevention of both bone and lean body mass loss in aged male rats is clearly lower than for prostate and seminal vesicles.

Influence of age, sex, and insulin on osteoblast function: osteoblast dysfunction in diabetes mellitus.

The osteoblast function was evaluated in normal and diabetic children and adults by measurements of the serum concentration of the carboxy-terminal extension peptide of procollagen (PICP), total and skeletal alkaline phosphatase (ALP), and osteocalcin. Moreover, the osteoblast-stimulating growth factor, insulin-like growth factor I (IGF-I), was measured in the same samples. In normal children (n = 420; age, 5-20 yr), a marked pubertal increase of serum IGF-I (peak values at age 14-16 yr in both sexes), osteocalcin, and total and skeletal ALP (peak values earlier in girls than in boys) and a small increase in PICP were observed. All osteoblast markers and IGF-I were markedly lower in normal adults (n = 229; age, 21-69 yr) than in children. All osteoblast parameters showed a high degree of correlation (P < 0.001) with each other. In adolescents (n = 104) treated for insulin-dependent diabetes mellitus (IDDM), serum IGF-I (-19%), osteocalcin (-28%), and skeletal ALP (-28%) were markedly decreased, whereas total ALP was significantly increased (29%), and serum PICP remained normal. In adult IDDM (n = 125), both serum IGF-I (-41%) and osteocalcin (-24%) were decreased, but skeletal ALP and PICP remained normal. A similar abnormality in serum IGF-I and osteocalcin was observed in white (n = 61) and Pima Indian (n = 16) non-IDDM patients. The concentration of skeletal ALP was highly significantly correlated (r > or = 0.9) with total ALP in both normal and diabetic subjects, but the slope of the regression was significantly different, indicating the presence of other, probably intestinal, ALP in all types of diabetes. In conclusion, the osteoblast function is significantly decreased in diabetic patients, which can best be characterized as a maturation defect, since the early osteoblast marker, PICP, remained normal in all types of diabetes, whereas a later marker, skeletal ALP, is frankly abnormal only in diabetic children. The most mature osteoblast marker, osteocalcin, is decreased in all types of diabetes irrespective of age.

Vanadate potentiates the glycogenic action of insulin-like growth factors on isolated diaphragm.

Na3VO4 (6.5 mumol/100 g rat weight), co-injected with a trace amount of [14C]glucose, increased within 15 min the incorporation of radiolabel in diaphragmal glycogen. After 2 h the vanadate-induced increases were 12-fold in the diaphragm and 7-8-fold in heart and liver. In contrast, when added to isolated diaphragms for up to 1 h, vanadate (0.1-5 mM) had no effect on the synthesis of glycogen from 5 mM glucose. In search of a putative mediator of vanadate's action in vivo, insulin and the insulin-like growth factors (IGFs) were considered. Their plasma concentration was not affected by vanadate treatment. In isolated diaphragms, 1 mM vanadate did not potentiate insulin-induced glycogen synthesis, but it caused a several-fold increase in glycogen synthesis in the presence of concentrations of IGF-I which, alone, had no effect. A similar synergism occurred between vanadate and IGF-II. We propose that the glycogenic action of vanadate in vivo, at least in some tissues, involves a potentiation of the action of IGF-I.

Recombinant human interleukin-11 does not modify biochemical parameters of bone remodeling and bone mineral density in adult ovariectomized rats.

Interleukin (IL)-11 stimulates osteoclast formation and inhibits osteoblast function in vitro and has been implicated in estrogen deficiency-induced bone loss. Herein we report the in vivo effect of recombinant human IL-11 (rHU-IL-11), administered s.c. in doses between 10 and 200 microg/kg/day for 6 weeks into 6-month-old rats after ovariectomy. There was no difference between vehicle-treated and rHu-IL-11 treated rats in the ovariectomy-induced increase in the urinary excretion of pyridinoline and deoxypyridinoline. Neither was there a significant effect of rHu-IL-11 on the plasma concentrations of osteocalcin and on bone mineral density (BMD) measured at a metaphyseal area of the distal femur after 6 weeks. At all dosages tested, rHu-IL-11 increased the femoral diaphyseal area. In conclusion, IL-11 has no deleterious in vivo effect on biochemical parameters of bone remodeling and BMD in estrogen-deficient rats.

Effects of exercise and disuse on bone remodeling, bone mass, and biomechanical competence in spontaneously diabetic female rats.

Diabetes is associated with low bone formation. In this study we investigate the effect of additional or reduced mechanical loading on indices of bone formation and resorption, bone mass, and biomechanical properties in spontaneously diabetic BB rats. Female diabetic (mean age 13 weeks) and age-matched control rats were each allocated to three experimental groups: no-intervention; supervised running exercise program (Ex); and unloading induced by unilateral sciatic neurectomy (USN). The study period was 8 weeks. We measured biochemical parameters of bone formation (plasma osteocalcin) and resorption (urinary deoxypyridinoline [Dpd]); bone mineral density (BMD) by dual-energy X-ray absorptiometry (DXA) at middiaphyseal and metaphyseal regions of the femur; histomorphometry of the proximal tibial metaphysis (PTM); and biomechanical properties of the femur (neck, diaphysis, and metaphysis) and lumbar vertebra (L-5). In nondiabetic rats, Ex did not affect parameters of bone formation/resorption and BMD, and had little effect on biomechanical properties. USN increased Dpd excretion, whereas there was a decreased trabecular bone formation rate (BFR) on morphometry of PTM in both paralyzed and intact limbs. Compared with intact limbs, paralyzed limbs of USN rats showed decreased trabecular bone volume at the PTM, and decreased BMD and biomechanical properties at the distal femoral metaphysis (DFM) and, to a lesser extent, femoral neck. Diabetic rats of the three experimental groups had low plasma osteocalcin levels and Dpd excretion, as well as low BFR on morphometry. The BMD and biomechanical properties of both femur and L-5 were unchanged in diabetic rats. Diabetic Ex rats, however, showed a lower maximum load and stress at DFM than control Ex rats. Diabetic USN rats showed no increase in Dpd excretion; their paralyzed limbs showed decreased maximum load at DFM, but there was no significant decrease in trabecular bone volume at PTM or BMD at DFM. Thus, the running exercise does not affect low bone formation in diabetic rats; however, trabecular bone loss caused by disuse is less pronounced in diabetic rats, probably as a result of low bone resorption.

Effects of long-term diabetes and/or high-dose 17 beta-estradiol on bone formation, bone mineral density, and strength in ovariectomized rats.

Long-term diabetes in female rats preserves the bone mineral density (BMD) but impairs the strength of the femur. In this study, we have compared the effects of diabetes and high-dose 17 beta-estradiol (E2), two conditions of low bone formation, in ovariectomized (ovx) rats. Spontaneously diabetic BB rats were ovx 0-3 days after onset, and nondiabetic ovx littermates were used as controls; the rats were either untreated or treated with E2 (30 micrograms/day, subcutaneously), for 6 or 12 weeks (n = 9 in each of the eight groups). Analysis included: plasma 1,25-dihydroxyvitamin D3, insulin-like growth factor-I (IGF-I), and osteocalcin concentrations; histomorphometry of the proximal tibial metaphysis (PTM); and DXA and biomechanical testing of the femur. Both E2 treatment and diabetes markedly lowered plasma IGF-I and osteocalcin concentrations, as well as dynamic morphometric parameters of bone formation in the PTM. Plasma IGF-I and osteocalcin were correlated (R2 = 0.55; p < 0.0001). E2 treatment in both control and diabetic ovx rats increased the trabecular bone volume in the PTM and the BMD in the metaphysis of the distal femur; there was no difference between control and diabetic rats, however. The diaphyseal area and BMC were decreased in E2-treated or/and diabetic ovx rats, but the diaphyseal BMD remained unchanged compared with untreated ovx rats. The biomechanical properties of the whole femur (strength, angular deformation, and stiffness) were decreased in E2-treated and diabetic E2-treated ovx rats after 12 weeks. The data indicate that in situations of chronic low bone formation, whole bone strength does not reflect total BMD but correlates better with bone size and bone mineral content measurements.

Skeletal effects of estrogen deficiency as induced by an aromatase inhibitor in an aged male rat model.

Aromatization of androgens into estrogens may be important for maintenance of the male skeleton. To address this hypothesis, we evaluated the skeletal effects of selective estrogen deficiency as induced by the aromatase inhibitor vorozole (Vor), with or without 17beta-estradiol (E(2)) administration (1.35 microg/day), in aged (12-month-old) male rats. A baseline group was killed at the start of the experiment (Base). The control group (Control), the group treated with vorozole alone (Vor), the group treated with E(2) alone (E(2)), or the group with a combination of both (Vor + E(2)) were killed 15 weeks later. Vorozole significantly increased serum testosterone (T) and reduced serum E(2) compared with Control. Body weight gain and serum insulin-like growth factor-I (IGF-I) were also lower in Vor, whereas significant weight loss and decrease of serum IGF-I occurred as a result of E(2) administration. Bone formation as assessed by serum osteocalcin was unaffected but osteoid surface in the proximal metaphysis of the tibia was increased in Vor-treated rats. Bone resorption as evaluated by urinary deoxypyridinoline excretion was increased in Vor. Biochemical parameters of bone turnover were reduced significantly in all E(2) treated rats. Premature closure of the growth plates and decreased osteoid and mineralizing surfaces were also observed in E(2) and Vor + E(2). Apparent bone density of lumbar vertebrae and femur, as measured by dual-energy X-ray absorptiometry (DXA), was significantly reduced in Vor. Vorozole decreased femoral bone density mainly in the distal femur (trabecular and cortical region). This decrease of bone density was not present in E(2) and Vor + E(2). Similar findings were observed when bone density was assessed by peripheral quantitative computed tomography (pQCT); that is, trabecular density of the distal femur, the proximal tibia, and the distal lumbar vertebra were all lower in Vor. This decrease in density was not observed in all E(2)-treated animals. In conclusion, administration of the aromatase inhibitor, vorozole, to aged male rats induces net trabecular bone loss in both the appendicular and axial skeleton, despite a concomitant increase in serum testosterone. E(2) administration is able to prevent this trabecular bone loss in vorozole-treated animals.