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Query: UMLS:C0205700 (
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)
15,125
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
An experiment was conducted to evaluate the capabilities of dual photon absorptiometry (PA), radiographic photometry (RP), and ultrasound (U) to estimate bone mineral content (BMC) and bone strength of a group of bovine third metacarpals (McIII). Metacarpals were chosen for evaluating BMC and bone strength because of their accessibility and susceptibility to biomechanical stress. The right and left McIII of 14 Angus heifers (24 to 32 mo of age) were collected at slaughter and all soft tissues (including
periosteum
) were removed. The BMC was estimated at both the midpoint and 3 cm proximal to the midpoint on the McIII diaphysis. Metacarpals then were tested by three-point bending to determine breaking load (BL) and breaking strength (BS). Bones were reassembled and two 2-cm sections were removed, one at the midpoint and one 1 cm proximal to the midpoint section. Sections then were ashed and
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content was expressed as grams per 2-cm slice and defined as BMC. Correlation coefficients (r) between BMC vs PA, RP, and U were .908 (P less than .0001), .967 (P less than .0001), and .565 (P less than .0001), respectively; r values between BS vs PA, RP, and U were .406 (P less than .05), .429 (P less than .05), and .499 (P less than .01), respectively, and r values between BL vs PA, RP, and U were .870 (P less than .0001), .865 (P less than .0001), and .588 (P less than .001), respectively. These data indicate that noninvasive techniques are useful in predicting BMC and BL in the bovine.
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PMID:Criteria to evaluate bone mineralization in cattle: II. Noninvasive techniques. 206 Dec 54
Magnesium (Mg) makes up 0.5-1% of bone
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and is therefore not a trace element in the skeleton. Mg influences both mineral and matrix metabolism in bone by a combination of effects on hormones and other factors that regulate skeletal and mineral metabolism, and by direct effects on bone itself. The skeletal content of Mg is very variable both between and within species, and reported values range between 150 and 440 mmol/kg
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weight (AW). Dietary Mg has a direct influence and age an inverse influence on skeletal Mg content. It is unclear whether skeletal Mg content varies from region to region. In humans, reported values cluster around the 200 mmol/kg AW level, 30-40% lower than most rat data. Human iliac crest cortical bone has 10-20% less Mg per unit weight than iliac crest trabecular bone. Mg depletion adversely affects all phases of skeletal metabolism. In the rat, cessation of bone growth is noted with a decrease in both osteoblast and osteoblast activity, decreased bone formation, osteopenia, increased fragility and development of a form of 'aplastic bone disease'. The epiphyseal growth plate is thinned and the percent
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weight of the growth plate is increased, possibly due to enhanced crystallization of bone salt under conditions of Mg depletion. In contrast, in chicks and in rats with severe Mg deficiency, these 'antianabolic' effects are not observed but instead, predominant inhibition of bone resorption occurs with increased cortical thickness rather than osteopenia, and the occasional development of subperiosteal hyperplasia or of fibrous tumors of the
periosteum
. It is probable that this unusual response under conditions of severe Mg deficiency is in part an indirect effect secondary to a defect in secretion and/or skeletal responsiveness to parathyroid hormone (PTH) and vitamin D metabolites. Mg excess also has adverse biologic effects on bone. Crystallization of bone salt is severely impaired and an osteomalacia-like picture may be produced with decreased osteoblastic activity, widened growth plates, excessive osteoid seams and short, thickened bones. In some studies, especially in mice, Mg excess stimulates bone resorption, independently of PTH. The role of Mg deficiency and excess in human skeletal conditions requires more extensive investigation. Bone Mg is uniformly increased in renal insufficiency and may play a role in renal osteodystrophy since improvement has been noted in the osteomalacic component by normalizing the serum Mg. Decreased bone Mg has been reported in alcoholic patients, diabetes and in osteoporosis.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Effects of magnesium on skeletal metabolism. 218 30
Bimetallic devices composed of silver and platinum were placed in the
periosteum
of the right femora of 20 rats. In 40 additional rats silver or platinum rods were placed in the right femora. After six weeks there was an increase in
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weight and 85Sr activity in the femora from the animals with bimetallic rods as compared with those in which pure silver or platinum rods were implanted. After three months no differences were found between the groups.
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PMID:Effect of electrogalvanic elements on nonfractured bone. 670 92
The effect of parathyroid hormone (PTH(1-34)) on mid-diaphyseal femoral cortical bone was studied in 2-year-old male rats. The rats were treated with daily injections of 15 nmol/kg PTH(1-34) or vehicle for 56 days, and labelled with tetracycline and calcein on day 15 and day 40, respectively. The PTH(1-34) treatment did not affect the body weights or the lengths of the femora. Fluorescence microscopy showed large intracortical cavities in the old vehicle-treated rats. After PTH treatment, double labelling and new bone formation filling in these cavities were found. Furthermore, an increased bone formation rate was observed both at the
periosteum
and at the endosteum. This resulted in an increase in the cross-sectional area and a decrease in the medullary area. Three-point bending analysis revealed an increase in ultimate load, ultimate stiffness, energy absorption and ultimate stress after the PTH(1-34) treatment. No differences were found between the groups regarding the hydroxyproline concentration or apparent and real densities. The
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concentration was, however, slightly reduced after PTH(1-34) treatment. The PTH(1-34) treatment of old rats induced the formation of bone both from the
periosteum
and endosteum, with a pronounced filling in of intracortical cavities, and, furthermore, a marked increase in the biomechanical competence of the cortical bone.
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PMID:Human parathyroid hormone(1-34) increases bone formation and strength of cortical bone in aged rats. 813 Aug 97
The anabolic effect of intermittent treatment with parathyroid hormone (PTH) on cortical bone was investigated. Groups of rats were injected with human PTH (1-34) or PTH (1-84), 1.1, 3.3, 10, and 30 nmol/kg/day for 30 days. A dose-related increase in bone formation rate at the femoral middiaphysis was found at both the
periosteum
and the endosteum and also an increase in bone mass, with no change in the bone lengths or body weight gain of the rats. The highest mineral apposition rate, as analyzed by tetracycline labeling, was found at the periosteal postero-medial aspect and at the endosteal anterior aspect. This pattern of bone modeling was also found in the PTH-treated animals, although more and more areas were included in bone mineral apposition. The PTH treatments did not change the porosity of the cortical bone nor the concentration and biochemical stability of the collagen. The highest doses of PTH resulted in a slight reduction in the
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concentration of cortical bone. No differences were found between the effects of PTH (1-34) and PTH (1-84) on bone formation rate, bone mass, porosity, and biochemical parameters. Consequently, intermittent treatment with PTH increased the formation of cortical bone dose dependently, at both the
periosteum
and the endosteum and increased the bone mass of these growing rats, with no change in the body weight gain or femoral growth rate compared with the control animals. The responses of the cortical bone modeling were increased by the PTH treatments without changing its direction or pattern.
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PMID:Parathyroid hormone (1-34) and (1-84) stimulate cortical bone formation both from periosteum and endosteum. 829 53
Periosteum has been demonstrated to have cell populations, including chondroprogenitor and osteoprogenitor cells, that can form both cartilage and bone under appropriate conditions. In the present study,
periosteum
was harvested, expanded in cell culture, and used to repair critical size calvarial defects in a rabbit model. Periosteum was isolated from New Zealand White rabbits, grown in cell culture, labeled with the thymidine analog bromodeoxyuridine for later localization, and seeded into resorbable polyglycolic acid scaffold matrices. Thirty adult New Zealand White rabbits were divided into groups, and a single 15-mm diameter full-thickness calvarial defect was made in each animal. In group I, defects were repaired using resorbable polyglycolic acid implants seeded with periosteal cells. In group II, defects were repaired using untreated polyglycolic acid implants. In group III, the defects were left unrepaired. Rabbits were killed at 4 and 12 weeks postoperatively. Defect sites were then studied histologically, biochemically, and radiographically. In vitro analysis of the cultured periosteal cells indicated an osteoblastic phenotype, with production of osteocalcin upon 1,25(OH)2 vitamin D3 induction. In vivo results at 4 weeks showed islands of bone in the defects repaired with polyglycolic acid implants with periosteal cells (group I), whereas the defects repaired with untreated polyglycolic acid implants (group II) were filled with fibrous tissue. Collagen content was significantly increased in group I compared with group II (2.90 +/- 0.80 microg/mg dry weight versus 0.08 +/- 0.11 microg/mg dry weight, p < 0.006), as was the
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weight (0.58 +/- 0.11 mg/mg dry weight versus 0.35 +/- 0.06 mg/mg dry weight, p < 0.015). At 12 weeks there were large amounts of bone in group I, whereas there were scattered islands of bone in groups II and III. Radiodensitometry demonstrated significantly increased radiodensity of the defect sites in group I, compared with groups II and III (0.740 +/- 0.250 OD/mm2 versus 0.404 +/- 0.100 OD/mm2 and 0.266 +/- 0.150 OD/mm2, respectively, p < 0.05). Bromodeoxyuridine label, as detected by immunofluorescence, was identified in the newly formed bone in group I at both 4 and 12 weeks, confirming the contribution of the cultured periosteal cells to this bone formation. This study thus demonstrates a tissue-engineering approach to the repair of bone defects, which may have clinical applications in craniofacial and orthopedic surgery.
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PMID:Tissue engineered bone repair of calvarial defects using cultured periosteal cells. 950 Mar 73
When administered intermittently, parathyroid hormone (PTH) is a strong anabolic agent, increasing both bone mass and bone mechanical strength and competence. This study evaluates the fate of PTH-induced bone in vertebral bodies after withdrawal of PTH treatment in normal old rats. Sixty-seven 21-month-old male rats were treated with 62 microg/kg/day PTH(1-34) for 8 weeks, followed by saline or bisphosphonate (risedronate, 5 microg/kg twice a week) for another 8 weeks. The rats were scanned by dual-energy X-ray absorptiometry at intervals. The bone mineral content (BMC) of L2-5 increased by 33% during the PTH treatment. The BMC started decreasing shortly after withdrawal of PTH and continued to decline during the 8 weeks after withdrawal of PTH. Risedronate, however, prevented this decrease in BMC. All rats were labeled with tetracycline and calcein 3 weeks and 1 week before the cessation of PTH therapy. In the cancellous bone, PTH increased the mineralized surface: 32.9% +/- 2.8% (mean +/- standard error of the mean) vs. controls 12.0% +/- 1.5%, the mineral appositional rate (0.65 +/- 0.02 to 0.88 +/- 0.06 microm/day), and the cancellous bone volume (BV/TV: 14.5% +/- 0.7% to 27.5% +/- 1.7%). Withdrawal of PTH induced a fast and pronounced bone resorption, decreasing both the extent of the fluorochrome labels and the cancellous bone volume to control values. Risedronate prevented this resorption. In the cortical bone of the vertebral shell, PTH induced large increases in the endocortical mineralized surface, mineral appositional rate, and cortical area. The endocortical fluorochrome labels were, however, resorbed after withdrawal of PTH. Risedronate maintained both the fluorochrome labels and the cortical area. At the
periosteum
, the response to PTH was less evident, however, and hardly any labeling was seen at the
periosteum
facing the vertebral canal either in the controls or in the PTH-treated rats. The compressive strength of the vertebral body specimens increased with PTH treatment whether measured in newtons (317 +/- 23 to 623 +/- 54 N), normalized to cross-sectional area (23.0 +/- 1.4 to 44.7 +/- 2.5 N/mm2), or to
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content per millimeter height (58 +/- 2 to 76 +/- 2 N x mm/mg). Withdrawal of PTH decreased the compressive strength and competence to control values. Risedronate, however, maintained the PTH-induced mechanical strength and competence. The study discloses that even in very old rats withdrawal of PTH treatment causes a rapid and pronounced decline in the bone mass deposited during PTH treatment; treatment with risedronate can, however, maintain the PTH-induced bone properties in the axial skeleton of old rats.
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PMID:Withdrawal of parathyroid hormone treatment causes rapid resorption of newly formed vertebral cancellous and endocortical bone in old rats. 966 29
