UMLS:C0851184 - FACTA Search

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Query: UMLS:C0851184 (thinning)
11,252 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To investigate the pathogenesis of osteoporosis in male hypogonadism we have investigated a heterogeneous group of 13 men with hypogonadism: 7 men (median age 60, range 31-79) with two or more vertebral crush fractures and 6 men (median age 61.5, range 28-76) without vertebral fractures. The group with crush fractures had trabecular and cortical osteoporosis as assessed by Singh grade, iliac crest trabecular bone volume, and metacarpal cortical area/total area. This was accompanied by an altered trabecular architecture with a reduction in number of trabeculae but no change in trabecular width, which contrasts with age-related bone loss in men where there is no reduction in trabecular number but thinning of trabeculae. The fracture group had significantly lower plasma 1,25-dihydroxyvitamin D [1,25(OH)2D] concentrations than the nonfracture group, and this was associated with malabsorption of calcium. Irrespective of the presence or absence of osteoporosis, treatment with testosterone led to a significant increase in total and free plasma 1,25(OH)2D and an improvement in calcium absorption measured with radiocalcium and by balance techniques. In addition, urine biochemistry, metabolic balance studies, and bone biopsy suggest that skeletal retention of calcium and bone formation are increased by testosterone treatment. We conclude that male hypogonadism causes both cortical and trabecular osteoporosis and altered trabecular architecture. A major risk factor for the development of osteoporosis is reduction in plasma 1,25(OH)2D, leading to malabsorption of calcium and reduced bone formation.
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PMID:Osteoporosis in hypogonadal men: role of decreased plasma 1,25-dihydroxyvitamin D, calcium malabsorption, and low bone formation. 376 4

Replacement estrogen therapy for premenopausal women with secondary hypogonadism (exercise/weight loss amenorrheas) remains controversial. In a group of 14 women with anorexia nervosa, amenorrhea, and no evidence of other endocrinopathy or protein-calorie malnutrition, significant osteopenia was demonstrated as assessed by cortical thickness of carpal bones. The degree of bone thinning was related to the duration and age at onset of amenorrhea as well as abnormalities of pubertal milestone progression. In the young women with "constitutionally delayed" menarche, or with secondary amenorrhea and hypogonadism, significant osteopenia may also be present. For those women with (1) hypoestrogenism and amenorrhea of over 36 months' duration, (2) pubertal delay, and (3) early onset of secondary amenorrhea, evaluation of osteopenia radiographically, and serious consideration for estrogen replacement, is important.
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PMID:Osteopenia in hypoestrogenic young women with anorexia nervosa. 669 16

Hip fractures in men account for one third of all hip fractures and have a higher mortality than in women. The age-specific incidence of hip fractures is increasing so that the public health burden will increase out of proportion to the burden imposed by the increase in the numbers of elderly men in the community. Vertebral fractures are a public health problem of lesser magnitude in terms of morbidity, mortality, and cost, but they are debilitating and are seen commonly in clinical practice. (Forearm fractures should probably not be regarded as a public health problem.) The pattern of earlier gain/later loss of bone during ageing in healthy men is well documented. Peak bone mass is higher in men than women because men have bigger bones. Peak bone density is the same. The absolute amount of trabecular bone lost at the spine and iliac crest during ageing is similar in men and women. Cortical bone loss is less in men. It is less because endocortical resorption is less, and periosteal formation is greater, in men. Bone loss may accelerate in elderly men and women (rather than decelerate), perhaps because endocortical resorption and increasing cortical porosity increase the effective surface available for resorption in cortical bone. Thus, bone fragility is less in men because (a) the cross-sectional surface of the vertebral body is larger; (b) trabecular bone loss is less as a percentage of the higher peak bone mass; (c) trabecular bone loss occurs by thinning rather than perforation; and (d) periosteal appositional growth compensates for endocortical resorption by maintaining the bending strength of bone. Reduced bone density in men with fractures may be due to reduced peak bone density and bone loss. As found in women with spine fractures, men with fractures have smaller bone size. Bone loss occurs by reduced bone formation and increased bone resorption. Loss of connectivity appears to predominate in men with vertebral fractures; trabecular thinning appears to predominate in men with hip fractures. Whether men with fractures have increased bone fragility due to reduced periosteal appositional growth during ageing is unknown. The age-related decline in testosterone, adrenal androgens, growth hormone, and insulin-like growth factor 1 may be concomitants of ageing or may contribute to reduced bone-formation and bone loss. Men with vertebral fractures may be more deficient in growth hormone and insulin-like growth factor 1. Thy often have illness, hypogonadism, or illnesses associated with hypogonadism that should be sought with a high index of suspicion.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The dilemma of osteoporosis in men. 770 40

Testosterone has importance both as a sex hormone and as an anabolic steroid promoting bone formation. Osteoporosis is associated with both hypogonadism and corticosteroid therapy. Testosterone levels are reduced by long term prednisolone treatment. Although high dose inhaled corticosteroid therapy may cause a variety of systemic effects including adrenal suppression, dermal thinning and a reduction in total bone calcium, its effect on testosterone levels is not known. Testosterone, luteinizing hormone, follicle stimulating hormone and sex hormone binding globulin were therefore measured in 35 male patients with respiratory disease attending an outpatient clinic (median age 58, range 21-75 years). They were grouped according to steroid therapy and compared with 19 age matched controls. Mean (SD) testosterone levels were 33% lower in 12 men on long term oral prednisolone [14.5 (6.0) nmol 1-1] than in controls [21.7 (6.3) nmol 1-1], but were not significantly reduced in 10 patients on low dose inhaled beclomethasone [200-800 micrograms day-1: 19.7 (3.7)] nor in 13 men taking high dose inhaled beclomethasone [1500-2,250 micrograms day-1: 17.9 (5.6)]. Levels of luteinizing hormone, follicle stimulating hormone and sex hormone binding globulin were similar in all four groups. These cross sectional data confirm that long term systemic corticosteroid therapy reduces testosterone levels. However, testosterone was reduced by only 18% (NS) by long term inhaled corticosteroids. Other mechanisms to explain the disordered bone metabolism should now be explored.
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PMID:Testosterone levels during systemic and inhaled corticosteroid therapy. 780 37

Hip fractures in men account for one third of all hip fractures and have a higher mortality than in women. The public health burden will increase as the increase in the numbers of elderly men in the community increases. In addition, the age-specific incidence of hip fractures may be increasing in some, but not all, countries. Vertebral fractures may be a public health problem as recent studies suggest that the prevalence in the community is 20-30%, similar to that reported in women. Forearm fractures should probably not be regarded as a public health problem. Peak bone mass is higher in men than women because men have bigger bones. Peak bone mineral density is the same. The amount of trabecular bone lost at the spine and iliac crest during ageing is similar in men and women. Cortical bone loss is less in men because endocortical resorption is less and periosteal formation is greater. Bone loss accelerates in elderly men because endocortical resorption and increasing cortical porosity increase the surface available for resorption. Bone fragility is less in men than women because: (a) the cross-sectional surface of the bone is larger; (b) trabecular bone loss is less as a percentage of the higher peak bone mass; (c) trabecular bone loss occurs by thinning rather than perforation; and (d) periosteal appositional growth compensates for endocortical resorption by maintaining the bending strength of bone. Reduced BMD in men with fractures may be due to reduced peak bone size and mass, and bone loss. Bone loss occurs by reduced bone formation. Whether men with fractures have increased bone fragility due to reduced periosteal appositional growth during ageing is unknown. The age-related decline in testosterone, adrenal androgens, growth hormone, and insulin-like growth factor 1 may contribute to reduced bone formation and bone loss. Men with vertebral fractures often have hypogonadism or illnesses with few clinical features that should be considered with a high index of suspicion (alcoholism, myeloma, malabsorption, primary hyperparathyroidism, haemochromatosis, Cushing's disease). Secondary hyperparathyroidism may contribute to bone loss by activating bone turnover and so increasing the number of bone remodelling units with impaired bone formation in each. There is no proven treatment for osteoporosis in men because there have been no trials using anti-fracture efficacy as an end point. Testosterone replacement should be considered in men with proven hypogonadism and vitamin D deficiency should be corrected if present. Calcium supplements and bisphosphonates are reasonable options given the lack of information.
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PMID:Osteoporosis in men. 936 40

A 26 year-old woman, whose parents were consanguineously married, was admitted to our center because of bilateral juvenile cataract. The patient exhibited short stature, sclerodermalike appearance of the skin with a typical bird-like facies, thinning and graying of hair, high pitched voice and hypogonadism. Werner's syndrome, was diagnosed. History, pathogeny, clinical features, diagnosis and cataract surgery are discussed.
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PMID:[Werner syndrome. Apropos of a case]. 975 41

Fragility fractures in men are a public health problem. The increasing longevity in men is likely to increase the public health burden of fractures in men. This problem remains unrecognized by doctors, the public and governments. About one third of all hip fractures occur in men but the incidence and gender ratio varies from country to country for reasons that are not understood. The prevalence of spine fractures is about half that of women in most studies, but similar to that of women in several other studies. The incidence of spine fractures is uncertain but is likely to be about half that of women except in 80+ year olds, when it appears to be similar. The causes of the higher mortality in men than in women following hip or spine fracture are not well defined. Areal bone mineral density (aBMD) predicts fracture risk in men; the relative risk for spine and hip fracture conferred by a 1 SD lower aBMD, or by a prevalent fracture, is similar in men and women. The age-specific absolute risk (number of cases per 1,000 per year) conferred by a given hip aBMD is similar in men and women. The age-specific absolute risk conferred by aBMD at the calcaneus or radius for spine fracture is similar for men and women. If the absolute and relative risks are similar then the lower incidence of fractures in men than women may reflect the lower proportion of the male population distribution below a given structural determinant of bone fragility. That is, at any age, there may be fewer men than women with smaller bones, lower volumetric bone mineral density (vBMD), thinner trabeculae or cortices, architectural disruption, or higher remodeling rates. Higher mortality and fewer falls may also contribute to the lower incidence of fractures in men. This tail end of the male population distribution (for traits like bone size, vBMD, architecture, and remodeling rates) is the likely source of fracture cases in males. Hypogonadism is a risk factor for osteoporosis. However, the definition, prevalence, causes and structural consequence of hypogonadism are inadequately defined. At what level of testosterone is bone balance negative? What structural determinants of axial and appendicular strength are regulated by testosterone, estrogen, growth hormone (GH), insulin like growth factor 1 (IGF-1) (or their interactions)? Is reduced bone size in men with spine or hip fractures due to failed growth-related or age-related periosteal expansion? If reduced vBMD is due to reduced accrual, is this due to reduced cortical thickness? What factors regulate and coregulate the periosteal and endocortical modeling and remodeling? Are reduced trabecular numbers due to failed formation at the growth plate, excess resorption of primary trabeculae or reduced formation of secondary trabeculae? Is reduced trabecular thickness due to failed prepubertal or pubertal bone formation? Is reduced cortical and trabecular thickness during aging due to excessive endosteal resorption or reduced bone formation? If the former, is this due to increased remodeling sites or increased resorption depth? Most evidence favors reduced bone formation as the cause of bone loss with trabecular bone loss occurring by reduced formation and thinning more than by increased resorption and loss of connectivity. Cortical bone loss is less than in women because endocortical resorption is less and periosteal apposition is greater. If the reduced bone formation is most important, is this due to reduced osteoprogenitors, reduced osteoblast matrix synthesis or early osteoblast apoptosis? Anti-spine-fracture efficacy has been demonstrated in only one randomized heated with alendronate drug in men. The gaps in our knowledge remain large.
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PMID:Unresolved issues in osteoporosis in men. 1170 79

There is no one cause of bone fragility; genetic and environmental factors play a part in development of smaller bones, fewer or thinner trabeculae, and thin cortices, all of which result in low peak bone density. Material and structural strength is maintained in early adulthood by remodelling; the focal replacement of old with new bone. However, as age advances less new bone is formed than resorbed in each site remodelled, producing bone loss and structural damage. In women, menopause-related oestrogen deficiency increases remodelling, and at each remodelled site more bone is resorbed and less is formed, accelerating bone loss and causing trabecular thinning and disconnection, cortical thinning and porosity. There is no equivalent midlife event in men, though reduced bone formation and subsequent trabecular and cortical thinning do result in bone loss. Hypogonadism contributes to bone loss in 20-30% of elderly men, and in both sexes hyperparathyroidism secondary to calcium malabsorption increases remodelling, worsening the cortical thinning and porosity and predisposing to hip fractures. Concurrent bone formation on the outer (periosteal) cortical bone surface during ageing partly compensates for bone loss and is greater in men than in women, so internal bone loss is better offset in men. More women than men sustain fractures because their smaller skeleton incurs greater architectural damage and adapts less effectively by periosteal bone formation. The structural basis of bone fragility is determined before birth, takes root during growth, and gains full expression during ageing in both sexes.
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PMID:Pathogenesis of bone fragility in women and men. 1204 92

Patients with fragility fractures may have abnormalities in bone structural and material properties such as larger or smaller bone size, fewer and thinner trabeculae, thinned and porous cortices, and tissue mineral content that is either too high or too low. Bone models and remodels throughout life; however, with advancing age, less bone is replaced than was resorbed within each remodeling site. Estrogen deficiency at menopause increases remodeling intensity: a greater proportion of bone is remodeled on its endosteal (inner) surface, and within each of the many sites even more bone is lost as more bone is resorbed while less is replaced, accelerating architectural decay. In men, there is no midlife increase in remodeling. Bone loss within each remodeling site proceeds by reduced bone formation, producing trabecular and cortical thinning. Hypogonadism in 20-30% of elderly men contributes to bone loss. In both sexes, calcium malabsorption and secondary hyperparathyroidism increase remodeling: more bone is removed from an ever-diminishing bone mass. As bone is removed from the endosteal envelope, concurrent bone formation on the periosteal (outer) bone surface during aging partly offsets bone loss and increases bone's cross-sectional area. Periosteal apposition is less in women than in men; therefore, women have more net bone loss because they gain less on the periosteal surface, not because they resorb more on the endosteal surface. More women than men experience fractures because their smaller skeleton incurs greater architectural damage and adapts less by periosteal apposition.
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PMID:Invited Review: Pathogenesis of osteoporosis. 1455 75

Werner syndrome (WS) is a pleiotropic disease of premature aging involving short stature, tight, atrophied, and/or ulcerated skin; a characteristic 'birdlike' facies and high, squeaky or hoarse voice; premature greying and thinning of the hair; and early onset cataracts. Additional common symptoms include diabetes mellitus, hypogonadism, osteoporosis, osteosclerosis of the digits, soft tissue calcification, premature atherosclerosis, rare or multiple neoplasms, malformed teeth, and flat feet. Diagnosis can be difficult due to the variable presentation and rarity of the disorder. Transmission is usually autosomal recessive. The WS gene, WRN, is member of the RecQ DNA helicase family. Biallelic mutations of WRN are responsible for most patients. Although heterozygous missense mutations in the LMNA gene have been observed in severely affected WS patients, this only accounts for a small fraction of non-WRN patients. Eighteen WS cases were referred to us for molecular analysis. Eleven had definite and three had probable WS according to the University of Washington Registry clinical criteria. All exons of the WRN gene and their splice junctions were sequenced. Of the fourteen definite or probable cases, 11 had one or more WRN mutation. Thirteen different mutations were found, and ten of these were previously undescribed. There were few phenotypic differences between patients with WRN mutation(s) and those who met clinical criteria though lacking WRN mutations. However, patients with mutations tended to have more symptoms overall, and mutations were not observed in the two cases with cardiomyopathy.
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PMID:Werner syndrome and mutations of the WRN and LMNA genes in France. 1678 14

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