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Query: UMLS:C0020500 (
hyperoxaluria
)
912
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In normal adults the urinary excretion of oxalate rarely exceeds 0.5 mmol/24 hours-1 despite dietary and seasonal fluctuations of intake and absorption.
Hyperoxaluria
may be encountered in a number of disease states because of increased absorption of dietary oxalate or derangements of metabolism (Table 1). More unusually,
hyperoxaluria
may arise from one of three inborn errors of metabolism, i.e., the primary hyperoxalurias. The most common, primary hyperoxaluria type I (PHI), is recessively inherited; it will be discussed in detail in this paper. Primary hyperoxaluria type II, caused by a deficiency of
D-glycerate dehydrogenase
(EC 1.1.1.29), has a similar clinical pattern of disease, but has been described in only a very few families. More recently, another idiopathic form of
hyperoxaluria
has been defined (type III). It is likely that this form results from a primary defect in oxalate absorption in the absence of any morphologically or functionally definable intestinal disease; a satisfactory response to dietary restriction of oxalate, along with the use of thiazide diuretics, has been described.
...
PMID:Perspectives in the assessment and management of patients with primary hyperoxaluria type I. 249 26
Primary hyperoxalurias are inborn errors of metabolism with recessive autosomal transmission. Type 1 is due to the deficiency of the hepatic-specific peroxisomal enzyme alanine: glyoxylate aminotransferase, and type 2 to that of the glyoxylate reductase/
D-glycerate dehydrogenase
, present in the cytosol of hepatocytes and leucocytes. Type 3 is due to increased intestinal absorption of oxalate of unknown pathophysiology. In the 3 types, increased oxalate load may lead to systemic oxalosis when glomerular filtration rate decreases below 30 ml/min/1.73 m2, calcium oxalate saturation occurring in plasma when oxalate level approximates 50 mumol/l. High fluid intake and long-term co-administration of pyridoxine and orthophosphate could perhaps efficiently prevent renal failure in a majority of patients. However, combined liver-kidney transplantation presently constitutes the most adequate therapy of end-stage renal failure in type 1 and perhaps in type 2
hyperoxaluria
.
...
PMID:[Primary hyperoxaluria]. 852 46
Most cases of primary hyperoxaluria are due to deficiency of hepatic peroxisomal alanine:glyoxylate aminotransferase [i.e. primary hyperoxaluria type 1 (PH1), McKusick 259900] and several hundred examples have been described since the original report in 1925. By contrast, primary hyperoxaluria type 2 (PH2, McKusick 260000) is very rare indeed with only 22 patients recorded since the original description in 1968. PH2 is characterized by
hyperoxaluria
and L-glyceric aciduria and is caused by deficiency of
D-glycerate dehydrogenase
/glyoxylate reductase. In comparison with PH1 much less is known about PH2 and considerable uncertainties remain about its frequency, clinical course and optimum management.
...
PMID:Primary hyperoxaluria type 2. 859 29
Urolithiasis is uncommon in adolescence and rare in early childhood. In pediatric populations, congenital urinary tract anomalies associated with stasis and infection, idiopathic urolithiasis (adolescents), and nephrocalcinosis (premature infants) account for the majority of urolithiasis patients. Inborn errors of metabolism, such as the primary hyperoxalurias, are rare causes of urolithiasis in childhood. We report six children (mean age at symptom onset 1.3 years; range 0.32-4.1 years) with moderate
hyperoxaluria
(mean 1.10 +/- 0.58 mmoL/1.73m2 per day; range 0.69-2.19 mmoL/1.73m2 per day). Urolithiasis was present in four. Stones from two children were comprised of calcium oxalate dihydrate. Calcium oxalate crystalluria was seen in two of the patients. Findings included a mean urine calcium concentration of 6.61 +/- 2.28 mg/kg per day, urine citrate of 925.5 +/- 291.29 mg/g of creatinine per day, and mean renal clearance of 99.83 +/- 23.27 mL/min. All children were born full term, none was receiving diuretics, and none had recurrent urinary tract infections. Secondary causes of
hyperoxaluria
, including dietary oxalate excess, pyridoxine deficiency, and malabsorption, were excluded. Urine glycolate and glycerate were normal in all patients. In one hyperoxaluric member of each sibship, hepatic alanine-glyoxylate aminotransferase and
D-glycerate dehydrogenase
/glyoxylate reductase activity were normal. The clinical and biochemical features of these children are unlike those in previously recognized hyperoxaluric states. Thus, our description of a separate hyperoxaluric entity, referred to as unclassified
hyperoxaluria
.
...
PMID:Hyperoxaluria and urolithiasis in young children: an atypical presentation. 1060 14
In the present paper we report the oral findings of a patient who was diagnosed with
hyperoxaluria
. Hyperoxalurias can basically be classified as primary and secondary, with the first being inborn errors of metabolism and the second a result of excessive oxalate intake. Primary hyperoxalurias form a rare group of metabolic diseases that are inherited in the autosomal recessive fashion. The affected genes code for specific hepatic enzymes that are involved in glyoxylate metabolism and their deficiency results in overproduction of oxalate. Two different types are described: Primary hyperoxaluria type I results from a deficiency of peroxisomal enzyme alanine-glyoxylate aminotransferase and the more rare type II from a deficiency of cytosolic enzyme
D-glycerate dehydrogenase
. Since oxalate is primarily excreted through the kidneys, abnormally high concentration of oxalate in the urine occurs. This can in turn result in recurrent kidney stones and parenchymal renal damage and end-stage renal disease (ESRD). Inability to further excrete oxalate through the kidneys leads to its deposition in various organs (oxalosis). Several oral findings have been described in patients with oxalosis, most important of whose are bone resorption in the jaws, external root resorption and rapidly progressive dental mobility, as well as dental pain associated with deposition of oxalate in the dentine and the pulp.
...
PMID:Oral findings associated with primary hyperoxaluria type I. 2241 69
A 6-month-old boy presented with acute renal failure, thrombocytopenia, and severe non-immune hemolytic anemia. Infection by Shiga-like toxin-producing Escherichia coli and other causes of microangiopathic hemolysis were ruled out, leading to a diagnosis of atypical hemolytic uremic syndrome (aHUS). Neither pathogenic variants in HUS-associated genes nor anti-factor H antibodies were identified. Copy number variation analysis uncovered 4 copies of complement factor H related genes, CFHR1-CFHR4, conceivably leading to higher than normal levels of the corresponding proteins. However, this abnormality was also found in the healthy relatives, neither explaining the disease nor the excessive complement deposition on endothelial cells detected by an ex-vivo test. Whole-exome sequencing revealed a pathogenic homozygous variant in GRHPR encoding the glyoxylate and
hydroxypyruvate reductase
. Recessive GRHPR mutations cause primary hyperoxaluria type 2 (PH2). The presence of renal calculi in the patient and elevated oxalate levels in the urine were consistent with the genetic diagnosis of PH2. We hypothesize that, in this patient,
hyperoxaluria
caused by the GRHPR genetic defect triggered endothelial perturbation and complement activation, which was amplified by impaired factor H regulatory activity due to the increased -CFHR1-CFHR4 copy numbers, resulting in aHUS.
...
PMID:Hemolytic Uremic Syndrome in an Infant with Primary Hyperoxaluria Type II: An Unreported Clinical Association. 3088 67
