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Query: UMLS:C0020438 (
hypercalciuria
)
2,502
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have investigated an 18-yr-old hypercalciuric female with features of both renal
hypercalciuria
and pseudohypoparathyroidism. She had increased circulating parathyroid hormone levels, which are common to both diseases. She also had a modest hypocalcemia and low normal basal cAMP excretion, both of which are more likely to occur in pseudohypoparathyroidism. She also had Albright's osteodystrophy, which is frequent in patients with pseudohypoparathyroidism and has never been reported in patients with renal
hypercalciuria
. In contrast to patients with pseudohypoparathyroidism, her serum 1,25-dihydroxycholecalciferol level was increased and her renal responses to parathyroid hormone infusion, including renal
calcium
reabsorption, were normal. This patient, therefore, raises the possibility that some patients with renal hyperalciuria may have a forme fruste of pseudohypoparathyroidism.
...
PMID:Albright's osteodystrophy in a patient with renal hypercalciuria. 22 62
Idiopathic hypercalciuria constitutes two major variants-absorptive
hypercalciuria
, characterized by a primary intestinal hyperabsorption of
calcium
, and renal
hypercalciuria
, in which renal tubular reabsorption of
calcium
is primarily impaired. The two forms of
hypercalciuria
may be distinguished from each other, since a) parathyroid function is stimualted in renal
hypercalciuria
, but normal or suppressed in absorptive
hypercalciuria
, b) the renal leak of
calcium
is present in renal
hypercalciuria
, but not in absorptive
hypercalciuria
, c) intestinal
calcium
absorption is probably increased primarily in absorptive
hypercalciuria
, and secondarily in renal
hypercalciuria
(from parathyroid hormone excess), d) the increased
calcium
absorption in renal
hypercalciuria
probably results from the parathyroid hormone-dependent stimulation of 1,25-dihydroxyvitamin D synthesis, whereas that in absorptive
hypercalciuria
may be vitamin D-independent, e) the response of the two conditions to certain treatments is unique, and f) the sequelae of parathyroid hormone excess, such as low bone density and negative
calcium
balance, may be present in renal
hypercalciuria
, but not in absorptive
hypercalciuria
. These findings provide a physiological basis for the consideration of absorptive and renal hypercalciurias as distinct and separate entities.
...
PMID:Physiological basis for absorptive and renal hypercalciurias. 22 36
Twenty-one unselected patients with recurrent nephrolithiasis and normocalcemic
hypercalciuria
with or without hypophosphatemia and 18 normal subjects were studied with an oral
calcium
tolerance test and for 3- to 5-day periods while consuming a low normal (400 mg) and high-normal (1000 mg)
calcium
intake. The oral
calcium
tolerance test consisted of the measurement of the calcemic, calciuric, and parathyroid (assessed by determinations of serum immunoreactive parathyroid hormone and nephrogenous cAMP) responses to acute 1000- or 350-mg doses of
calcium
. Nineteen patients displayed normal results for basal serum
calcium
, parathyroid function, and fasting
calcium
excretion, and striking calcemic (mean increase in serum
calcium
, 0.9 vs. 0.2 mg/dl in the normal subjects) and calciuric (mean increase in urinary
calcium
, 0.33 vs. 0.15 mg
calcium
/100 ml GF in the normal subjects) responses to the 1000-mg
calcium
tolerance test, associated with a mean 54% suppression in nephrogenous cAMP. These patients were operationally defined as having "absorptive"
hypercalciuria
. The variable occurrence of hypophosphatemia in this group suggested that the pathogenesis of "absorptive"
hypercalciuria
may be complex and/or multifactorial. There were strong positive correlations between the calciuric response to the
calcium
tolerance test and fractional isotopic
calcium
absorption (r = 0.75, P less than 0.00), the calcemic responses to the test (r = 0.71, P less than 0.001) and the calciuric responses noted on the 1000- vs. the 400-mg daily
calcium
intake (r = 0.78, P less than 0.001). Two patients displayed low or low normal basal serum
calcium
, increased parathyroid function, increased fasting
calcium
excretion, and a striking calciuric but minimal calcemic response to the 1000-mg
calcium
tolerance test, associated with a moderate suppression in nephrogenous cAMP. These patients were operationally defined as having "renal"
hypercalciuria
. Several lines of evidence indicated that the hyperparathyroidism in these patients was physiological or secondary, including the near normalization of parathyroid function on the daily 1000-mg
calcium
intake. A steep slope of
calcium
excretion on
calcium
intake (due to increased
calcium
absorption) was noted in all hypercalciuric patients and accounted for the significantly improved diagnostic accuracy of screening patients for
hypercalciuria
on the high-normal
calcium
intake. The simple measurement of total cAMP excretion (nanomoles per 100 ml GF) and urinary
calcium
on the 1000-mg daily
calcium
intake seemed to provide reliable separation of patients with "renal" from those with "absorptive"
hypercalciuria
. A physiological (350 mg) dose of oral
calcium
produced a 30% suppression of nephrogenous cAMP in normal subjects; this suggests that dietary
calcium
exerts an important control of parathyroid function under physiological circumstances.
...
PMID:Pathophysiological studies in idiopathic hypercalciuria: use of an oral calcium tolerance test to characterize distinctive hypercalciuric subgroups. 23 82
Three indices of circulating parathyroid hormone (PTH) activity were compared between two groups: the first a group of 23 patients from three large kindreds with autosomal dominant hypercalcemia without
hypercalciuria
[familial hypocalciuric hypercalcemia (FHH)] and the second a group of 64 patients with typical primary hyperparathyroidism (1HPT) manifesting comparable hypercalcemia. The group with 1HPT differed from normal with respect to plasma PTH 1HPT concentration (normal, less 0.2 ng/ml), urinary cAMP excretion per 100 ml glomerular filtrate (U cAMP/GF) (normal, 2.3 x/divided by 0.6 nmol/100 ml glomerular filtrate; mean, x/divided 1 SD), and renal tubular maximum of phosphate transport corrected for glomerular filtration rate (TMP/GFR; normal, 3.4 +/- 0.4 mg/dl; mean, +/- 1 SD). The group with 1HPT also diverged significantly from the group with FHH for all three indices: for PTH, 0.37 x/divided by .48 vs. 0.25 x/divided .46 (P less than 0.05); for UcAMP/GF, 4.3 x/divided by .53 vs. 2.6 x/divided .60 (P less than 0.0005); and for TMP/GFR, 2.0 +/- 0.6 vs. 2.6 +/- 0.7 (P less than 0.01). The between-group differences for all three indices were also significant after adjustment for their variation with serum
calcium
. However, only the difference in TMP/GFR remained significant after adjustment for covariance attributable to serum
calcium
concentration, age, and creatinine clearance. The group with FHH differed from normal for TMP/GFR but not for UcAMP/GF. However, analysis of changes in UcAMP/GF and serum
calcium
concentration around the time of parathyroidectomy in three patients with FHH suggested that the parathyroid glands contributed to the abnormalities of mineral homeostasis in at least one. It was concluded that higher serum concentrations of PTH do not account for the lower renal clearance of
calcium
and magnesium in FHH
calcium
concentration, the group with FHH showed indices suggesting lower circulating PTH activity than the group with 1HPT.
...
PMID:Circulating parathyroid hormone activity: familial hypocalciuric hypercalcemia versus typical primary hyperparathyroidism. 23 92
Using a whole body radiation detector, we have measured the total body retention of 47-Ca 7 days after oral administration of the isotope to patients with various disorders of calcium metabolism. The percent retention of 47-Ca given with 90 mg of unlabeled (carrier)
calcium
varied with the
calcium
metabolic status as follows: normals (n equals 14), 33-43 percent (mean 38); primary hyperparathyroidism (n equals 28), 32-74 percent (mean 52); idiopathic
hypercalciuria
(n equals 9), 34-49 percent (mean 42); and hypercalcemia of other etiology (n equals 3), 23-26 percent (mean 25). Almost half (13/28) of those with hyperparathyroidism showed a retention above 55 percent, distinguishing them from subjects with idiopathic
hypercalciuria
. Retention of 47-Ca correlated poorly with clinical measures of severity of hyperparathyroidism. When isotope was diluted with a smaller amount of carrier
calcium
(20 mg), retention was increaseed in normals (n equals 5) to 46-54 percent (mean 50) and in hyperparathyroidism (n equals 5) to 64-87 percent (mean 73). After surgical cure of hyperparathyroidism retention of isotope returned toward normal in 5 of 7 subjects. Whole body retention of orally administered 47-Ca may prove useful in detecting hyperparathyroidism in subjects with mild hypercalcemia or
hypercalciuria
.
...
PMID:Total body retention of orally administered 47-calcium in primary hyperparathyroidism. 23 21
Effects of oral sodium cellulose phosphate therapy (5 g three times a day with meals for 4 days) on renal excretion of oxalate and on the crystallization of
calcium
oxalate in urine were examined in six patients with absorptive
hypercalciuria
on a constant metabolic dietary regimen. During treatment, urinary oxalate increased by 9-50 mg/day. However, urinary
calcium
decreased by 138-225 mg/day (50%-70%). Thus, the state of saturation of urine with respect to
calcium
oxalate decreased or did not change significantly. There was no consistent or significant change in the formation product ratio (limit of metastability) or in the crystal growth of
calcium
oxalate in urine.
...
PMID:Effect of sodium cellulose phosphate therapy on crystallization of calcium oxalate in urine. 24 92
A longitudinal 9-year retrospective study of 24-hour urinary
calcium
values has been made in a metabolic stone clinic amongst patients with idiopathic
hypercalciuria
. No seasonal variations could be observed in contrast ot a previous study from Leeds, A prospective longitudinal study was made of 24-hour urinary
calcium
values in a small group of normal subjects. No seasonal variation could be ovserved. In the prospective study no seasonal variations in urinary oxalate could be observed. In a 2-year longitudinal study of stone patients with idiopathic
hypercalciuria
, urinary oxalate was found to be higher in the summer than in the winter. This was attributed to the combination of a higher intake of oxalate-rich foods in the summer, and the low
calcium
diet with which they were treated.
...
PMID:Seasonal variations in urinary excretion of calcium and oxalate in normal subjects in patients with idiopathic hyperclaciuria. 31 63
Catecholamines induce bone resorption and hypercalcaemia by the beta-adrenergic effect in bone and
hypercalciuria
by the alpha adrenergic effect in kidney. The interplay between the alpha-adrenergic
hypercalciuria
and beta-adrenergic hypercalcaemia explains why in some, but not all, phaeochromocytomas hypercalcaemia occurs. The hypothesis predicts
hypercalciuria
in both phaeochromocytoma and neuroblastoma. In hyperthyroidism, negative
calcium
balance and hypercalcaemia cannot be attributed to the direct effect of thyroid hormones on the bone but can be explained by augmentation of the catecholamine effects on bone and kidney by thyroid hormones. The hypothesis offers a solution for an apparent paradox in hyperthyroidism of increased urinary cAMP while nephrogenous cAMP is decreased. It also explains why propranolol corrects hypercalcaemia without influencing renal
calcium
loss.
...
PMID:Catecholamines cause the hypercalciuria and hypercalcaemia in phaeochromocytoma and in hyperthyroidism. 33 Oct 32
The calciuric response to an oral glucose load (100 g) was determined in 16 patients with
calcium
oxalate urolithiasis (seven with renal
hypercalciuria
and nine with absorptive
hypercalciuria
) and seven normal subjects. The rates of renal
calcium
excretion increased significantly after glucose ingestion in all three groups. The calciuric response in patients with absorptive
hypercalciuria
and intestinal hyperabsorption of
calcium
was indistinguishable from that of normal subjects. However, the
calcium
excretions were significantly higher during 1 hr preceding and 3 hr after glucose ingestion in patients with renal
hypercalciuria
(with presumed "renal leak" of
calcium
) than in normal subjects. The increment in the
calcium
excretion rate was also higher in patients with renal hyperacalciuria, particularly during the 2nd hour of glucose ingestion. The results provide a further support for the concept of different etiologies of renal and absorptive hypercalciurias.
...
PMID:An exaggerated augmentation of renal calcium excretion after oral glucose ingestion in patients with renal hypercalciuria. 34 35
Three types of
hypercalciuria
are described; their existence and frequent association with
calcium
urolithiasis in humans are accepted. Various dietary factors such as minerals, electrolytes, fluids, vitamin D, carbohydrates, proteins are discussed with regard to their ability to alter the nature and the degree of
calcium
excretion following their ingestion. It is emphasised that at present we have only limited knowledge on the chain of events linking calorie intake and the response of the kidney.
...
PMID:A survey of calcium urolithiasis in normocalcemic hypercalciuria: possible role of nutrients and diet-mediated factors. 38 96
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