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Query: UMLS:C0020438 (
hypercalciuria
)
2,502
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Occupational exposure to cadmium has for long been associated with renal tubular cell dysfunction, osteomalacia with osteoporosis,
hypercalciuria
and renal stone formation. High environmental exposure in Japan resulting from a stable diet of cadmium contaminated rice caused itai-itai disease, fractures occurring mainly in elderly multiparous women, with a form of osteomalacia, osteoporosis and renal dysfunction. More recently a population based study in Europe, in the vicinity of zinc smelters has shown that low to moderate exposure to cadmium, with a mean urinary excretion of cadmium of the order of 1 microg/g creatinine has been associated with a decrease in bone density, an increased risk of bone fractures in women and of height loss in men. In a population-based study of residents near a cadmium smelter in China, forearm bone density was shown to decrease linearly with age and urinary cadmium in both sexes, suggesting a dose effect relationship between cadmium dose and bone mineral density. A marked increase in the prevalence of fractures was shown in the cadmium-polluted area in both sexes. Concentrations of cadmium in blood and urine were taken as exposure biomarkers, and beta2-microglobulin, retinol binding protein and albumin as biomarkers of effect. A marked dose response relationship between these indicators of exposure and effect was shown.
Hypercalciuria
, which may progress to osteoporosis, has been taken as a sensitive renal-tubular biomarker of a low level of cadmium exposure. Cadmium may also act directly on bone. Animal studies have shown cadmium to stimulate the formation and activity of osteoclasts, breaking down the
collagen
matrix in bone. Osteoporosis is the main cause of fracures in post-menopausal women, a common occurrence worldwide, giving rise to disability and a high cost to health services. The identification of cadmium, an environmental pollutant, as one causal factor is highly significant in helping to control the incidence of this complex condition.
...
PMID:Cadmium, osteoporosis and calcium metabolism. 1568 52
Diabetes mellitus and osteoporosis affect a large proportion of older adults. In this context, diabetes may influence the bone in multiple pathways, some with contradictory effects. These mechanisms include changes in insulin and insulin-like growth factors levels,
hypercalciuria
associated with glycosuria, reduced renal function, obesity, higher concentrations of advanced glycation end products in
collagen
, angiopathies, neuropathies and inflammation. Although it is assumed that the decreased bone strength in diabetes may contribute to fracture risk, a very high number of available clinical and/or epidemiological studies as well as animal model studies brought about heterogeneous or even contradictory results on the skeletal involvement in patients with diabetes mellitus. In addition, bone mineral density (BMD) is a convenient predictor for fracture and the type 1 diabetes is associated with modest reductions in BMD. However, type 2 diabetes can be related to the elevated BMD. The immediate improvement in these discrepancies is to consider the complex pathophysiology of diabetes as well as influences of gender, age, treatment and duration of the disease. It is important also to improve further the choice of investigated biochemical markers and the standardization of the bone mass measurements. Along these lines, several recent cohort studies undeniably indicated that diabetes itself is associated with increased risk of osteoporosis.
...
PMID:The impact of diabetes mellitus on skeletal health: an established phenomenon with inestablished causes? 1631 62
Idiopathic hypercalciuria (IH) has been speculated to have a predisposing role in the development of urinary tract infection (UTI), due to the uroepithelial cell damage it leads to. In this study, we aimed to investigate the effects of
hypercalciuria
on the bladder, ureters, and kidneys in rats with experimentally induced
hypercalciuria
.Normocalcemic
hypercalciuria
was induced by furosemide (60 mg/100 mL of drinking water) administration to 16-week-old male Wistar Albino rats for 14 days. Calciuria (calcium/creatinine ratio, mg/mg, Ca/Cr) increased from 0.07+/-0.01 at the beginning of administration to 0.41+/-0.1 on day 14 (p=0.000). The Ca/Cr ratio was 0.14+/-0.06 at the beginning of the study and 0.25+/-0.06 on day 14 in the control group rats (p=0.002 vs. the hypercalciuric group rats on day 14). Bladder, ureter, and kidney specimens of the rats, dissected on the 14th day, were fixed in 10% formalin and 2.5% gluteraldehyde solutions for light and electron microscopic examination, respectively. Histopathological and ultrastructural examination of the hypercalciuric rats revealed proliferation and apical cytoplasmic vacuole formation in transitional epithelial cells, mitotic activity in the intermediate cell line, vasodilatation, edema, and separation of
collagen
fibers in the bladder and ureter specimens. Light microscopic examination of the kidney specimens revealed a lot of erythrocyte in the glomerular capillary lumen, while electron microscopy revealed vacuolization of proximal and distal tubules, tubular degeneration, interstitial edema, and vasodilatation.In this study,
hypercalciuria
was observed to have adverse effects on the cell architecture of the uroepithelium and disruption of the epithelial barrier of the bladder and ureters and all kidney structures, especially on the proximal epithelial cells.
...
PMID:Evaluation of histologic changes in the urinary tract of hypercalciuric rats. 1692 50
Diabetes mellitus (DM) and osteoporotic fractures are two of the most important causes of mortality and morbidity in older subjects. Recent data report a close association between fragility fracture risk and DM of both type 1 (DM1) and type 2 (DM2). However, DM1 is associated with reduced bone mineral density (BMD), whereas patients with DM2 generally have normal or increased BMD. This apparent paradox may be explained by the fact that, at a given level of BMD, diabetic patients present lower bone quality with respect to non-diabetics, as shown by several studies reporting that diabetes may affect bone tissue by means of various mechanisms, including hyperinsulinemia, deposition of advanced glycosylation endproducts (AGEs) in
collagen
, reduced serum levels of IGF-1,
hypercalciuria
, renal failure, microangiopathy and inflammation. In addition, the propensity to fall and several comorbidities may further explain the higher fracture incidence in DM patients with respect to the general population. It is reasonable to expect that close metabolic control of diabetes may improve bone status, although its effect on reduction of fracture risk has not yet been demonstrated. However, metformin has a direct effect on bone tissue by reducing AGE accumulation, whereas insulin acts directly on osteoclast activity, and thiazolidinediones (TZD) may have a negative effect by switching mesenchymal progenitor cells to adipose rather than bone tissue. New prospects include the incretins, a class of antidiabetic drugs which may play a role linking nutrition and bone metabolism. Better knowledge on how diabetes and its treatments influence bone tissue may lie at the basis of effective prevention of bone fracture in diabetic patients. Thus, close glycemic control, adequate intake of calcium and vitamin D, screening for low BMD, and prevention and treatment of diabetic complications are key elements in the management of osteoporosis in both DM1 and DM2. Attention should be paid to treating diabetes with TZD in women with DM2, particularly if elderly. Lastly, patients with osteoporosis and diabetes should be offered the same pharmacological treatments as non-diabetics, although specific trials on the effects of anti-osteoporotic drugs in the diabetic population are lacking.
...
PMID:Osteoporosis and risk of fracture in patients with diabetes: an update. 2174 87
Kidney stones develop attached to sub-epithelial plaques of calcium phosphate (CaP) crystals (termed Randall's plaque) and/or form as a result of occlusion of the openings of the Ducts of Bellini by stone-forming crystals (Randall's plugs). These plaques and plugs eventually extrude into the urinary space, acting as a nidus for crystal overgrowth and stone formation. To better understand these regulatory mechanisms and the pathophysiology of idiopathic calcium stone disease, this review provides in-depth descriptions of the morphology and potential origins of these plaques and plugs, summarizes existing animal models of renal papillary interstitial deposits, and describes factors that are believed to regulate plaque formation and calcium overgrowth. Based on evidence provided within this review and from the vascular calcification literature, we propose a "unified" theory of plaque formation-one similar to pathological biomineralization observed elsewhere in the body. Abnormal urinary conditions (
hypercalciuria
, hyperoxaluria, and hypocitraturia), renal stress or trauma, and perhaps even the normal aging process lead to transformation of renal epithelial cells into an osteoblastic phenotype. With this de-differentiation comes an increased production of bone-specific proteins (i.e., osteopontin), a reduction in crystallization inhibitors (such as fetuin and matrix Gla protein), and creation of matrix vesicles, which support nucleation of CaP crystals. These small deposits promote aggregation and calcification of surrounding
collagen
. Mineralization continues by calcification of membranous cellular degradation products and other fibers until the plaque reaches the papillary epithelium. Through the activity of matrix metalloproteinases or perhaps by brute physical force produced by the large sub-epithelial crystalline mass, the surface is breached and further stone growth occurs by organic matrix-associated nucleation of CaOx or by the transformation of the outer layer of CaP crystals into CaOx crystals. Should this theory hold true, developing an understanding of the cellular mechanisms involved in progression of a small, basic interstitial plaque to that of an expanding, penetrating plaque could assist in the development of new therapies for stone prevention.
...
PMID:Unified theory on the pathogenesis of Randall's plaques and plugs. 2511 6
Both types 1 and 2 diabetes mellitus (T1DM and T2DM) are associated with profound deterioration of calcium and bone metabolism, partly from impaired intestinal calcium absorption, leading to a reduction in calcium uptake into the body. T1DM is associated with low bone mineral density (BMD) and osteoporosis, whereas the skeletal changes in T2DM are variable, ranging from normal to increased and to decreased BMD. However, both types of DM eventually compromise bone quality through production of advanced glycation end products and misalignment of
collagen
fibrils (so-called matrix failure), thereby culminating in a reduction of bone strength. The underlying cellular mechanisms (cellular failure) are related to suppression of osteoblast-induced bone formation and bone calcium accretion, as well as to enhancement of osteoclast-induced bone resorption. Several other T2DM-related pathophysiological changes, e.g., osteoblast insulin resistance, impaired productions of osteogenic growth factors (particularly insulin-like growth factor 1 and bone morphogenetic proteins), overproduction of pro-inflammatory cytokines, hyperglycemia, and dyslipidemia, also aggravate diabetic osteopathy. In the kidney, DM and the resultant hyperglycemia lead to calciuresis and
hypercalciuria
in both humans and rodents. Furthermore, DM causes deranged functions of endocrine factors related to mineral metabolism, e.g., parathyroid hormone, 1,25-dihydroxyvitamin D
3
, and fibroblast growth factor-23. Despite the wealth of information regarding impaired bone remodeling in DM, the long-lasting effects of DM on calcium metabolism in young growing individuals, pregnant women, and neonates born to women with gestational DM have received scant attention, and their underlying mechanisms are almost unknown and worth exploring.
...
PMID:Derangement of calcium metabolism in diabetes mellitus: negative outcome from the synergy between impaired bone turnover and intestinal calcium absorption. 2767 1
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