Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0020538 (hypertension)
170,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Humans excrete uric acid as the final breakdown product of unwanted purine nucleotides. Urate scavenges potential harmful radicals in our body. However, in conjunction with genetic or environmental (especially dietary) factors, urate may cause gout, nephrolitiasis, hypertension, and vascular disease. Blood levels of urate are maintained by the balance between generation and excretion. Excretion requires specialized transporters located in renal proximal tubule cells, intestinal epithelial cells, and vascular smooth muscle cells. The recently identified human urate transporters URAT1, MRP4, OAT1, and OAT3 are thought to play central roles in homeostasis and may prove interesting targets for future drug development.
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PMID:Molecular physiology of urate transport. 1577 1

Uric acid is the final breakdown product of purine metabolism in man. There is a growing body of evidence that indicates that elevated uric acid levels increase the probability of developing hypertension and cardiovascular disease. The frequency of hyperuricaemia in untreated hypertensive individuals ranges from 25 - 50%. Furthermore, elevated serum uric acid has been reported to increase the probability of developing hypertension by 87% and to increase the mortality rate from ischaemic heart disease. Several studies have reported that changes in serum cholesterol parallel changes in serum uric acid in both order and magnitude. Most recently, hyperuricaemia has been added to the constellation of abnormalities that comprise Syndrome X. The pathophysiology of hyperuricaemia and the link between hyperuricaemia, hypertension and cardiovascular disease are poorly understood. It is entirely possible that hyperuricaemia is part of a pathologic process that underlies fundamental alterations in renal function, as well as other metabolic pathophysiologies that ultimately lead to hypertension and cardiovascular disease.
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PMID:Emerging concepts in cardiovascular disease: should elevated serum uric acid be considered a risk factor? 1599 21

Gestational hypertension is differentiated into higher and lower risk by the presence or absence of proteinuria. We asked if hyperuricemia, a common finding in pregnancy hypertension, might also be an indicator of increased risk. We examined fetal outcome data from 972 pregnancies collected from 1997 to 2002 in a nested case-control study. Participants were nulliparous with no known medical complications. The frequency of preterm birth, the duration of pregnancy, frequency of small-for-gestational-age infants, and birth weight centile were determined for pregnancies assigned to 8 categories by the presence or absence of combinations of hypertension, hyperuricemia, and proteinuria. In women with gestational hypertension, hyperuricemia was associated with shorter gestations and smaller birth weight centiles and increased risk of preterm birth and small-for-gestational-age infants. Hyperuricemia increased the risk of these outcomes in the presence or absence of proteinuria. Risk was also increased in a small group of women with hyperuricemia and proteinuria without hypertension. Women with only hypertension and hyperuricemia have similar or greater risk as women with only hypertension and proteinuria. Those with hypertension, proteinuria, and hyperuricemia have greater risk than those with hypertension and proteinuria alone. The risk of these outcomes increased with increasing uric acid. Hyperuricemia is at least as effective as proteinuria at identifying gestational hypertensive pregnancies at increased risk. Uric acid should be reexamined for clinical and research utility.
Hypertension 2005 Dec
PMID:Uric acid is as important as proteinuria in identifying fetal risk in women with gestational hypertension. 1624 74

Serum uric acid levels are associated with hypertension, cardiovascular disease, and renal disease. Uric acid has been shown to be heritable; however, genome-wide linkage analyses have not been reported. Genome-wide multipoint variance components linkage analyses with 401 markers spaced at approximately 10 centimorgan (cM) were conducted on 1258 subjects of the Framingham Heart Study, using the average of two serum uric acid measurements obtained in examinations 1 and 2 around 1971 and 1979. Covariates in fully adjusted model included sex, age, body mass index (BMI), serum creatinine, alcohol consumption, diabetes, diuretic treatment, and triglycerides. To investigate possible pleiotropic effects between uric acid and covariates that may have a genetic component, bivariate linkage analyses of uric acid with BMI, triglycerides, and glucose were conducted at the uric acid linkage regions. The heritability of uric acid was 0.63. The highest multipoint log-of-the-odds (LOD) score was 3.3 at 50 cM on chromosome 15 for age-sex-adjusted uric acid, but decreased to 1.5 after multivariable adjustment. Additional evidence of linkage was seen on chromosomes 2 (LOD score 1.1 at 4 cM) and 8 (LOD score 1.7 at 6 cM) for multivariable-adjusted uric acid. Pleiotropic effects were only found between uric acid and glucose and BMI at chromosomes 8 and 15 linkage locations, respectively. We have identified several novel loci linked to uric acid. We found possible pleiotropic effects between uric acid and BMI and glucose. Further research is necessary to identify the genes involved in uric acid metabolism and their roles in hypertension, cardiovascular disease, and renal disease.
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PMID:Genome-wide search for genes affecting serum uric acid levels: the Framingham Heart Study. 1625 30

Uric acid might often be regarded as a simple marker of renal disease. Although it is well known that hyperuricemia causes gout which is associated with renal insufficiency and cardiovascular disease, one might think that it could attribute to the intrarenal urate crystal, but not to uric acid per se. In order to clarify the role of uric acid in the kidney, we hypothesized that uric acid causes renal disease. To generate mild hyperuricemia without intrarenal crystal in rats, we used low doses of an uricase inhibitor (2% oxonic acid). Hyperuricemia induced systemic hypertension, glomerular hypertrophy/hypertension, afferent arteriolar sclerosis, and macrophage infiltration in normal rat kidney. In progressive renal disease, such as cyclosporine nephropathy and remnant kidney in rat, uric acid accelerated the progression of renal disease. Thus, we concluded that uric acid is not a simple marker, but a cause of renal disease.
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PMID:Uric acid--a uremic toxin? 1636 44

The connection of gout and hyperuricaemia with gluttony, overindulgence in food and alcohol and obesity dates from ancient times. Studies from different parts of the world suggest that the incidence and severity of hyperuricaemia and gout may be increasing. Uric acid (urate) is the end product of purine degradation. Although most uric acid is derived from the metabolism of endogenous purine, eating foods rich in purines contributes to the total pool of uric acid. Sustained hyperuricaemia is a risk factor for acute gouty arthritis, chronic tophaceous gout, renal stones and possibly cardiovascular events and mortality. Before starting lifelong urate-lowering drug therapy, it is important to identify and treat underlying disorders that may be contributing to hyperuricaemia. It is relevant to recognize the strong association of the insulin resistance syndrome (IRS) (abdominal obesity, dyslipidaemia, hypertension, raised serum insulin levels and glucose intolerance) with hyperuricaemia. Consumption of meat, seafood and alcoholic beverages in moderation and attention to food portion size is important. Moderation in the consumption of not only beer but also other forms of alcohol is essential. In the obese, controlled weight management has the potential to lower serum urate in a quantitatively similar way to relatively unpalatable "low purine" diets. Non-fat milk and low-fat yogurt have a variety of health benefits and dairy products may have clinically meaningful antihyperuricaemic effects. In addition, fruits, such as cherries and high intakes of vegetable protein diet may reduce serum urate levels.
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PMID:Dietary factors and hyperuricaemia. 1637 34

Increased levels of uric acid are associated with cardiovascular disease and the metabolic syndrome. They may predict clinical outcomes and also the onset of hypertension, though it is less clear that hyperuricaemia can be regarded as an independent risk factor given its clustering with other well-recognised factors. Uric acid may increase as a result of pathophysiological processes such as impaired renal sodium handling but may also contribute to renal and vascular damage, particularly endothelial dysfunction. It is notable that the synthesis of uric acid may be associated with the generation of reactive oxygen species if the enzyme xanthine oxidorectase is converted to the oxidase, as may occur in ischaemia. It has been suggested that uric acid may play a role in the pathogenesis of early-onset hypertension but evidence for this is limited. There is also very limited data to suggest that in some circumstances lowering uric acid can lower blood pressure. In the metabolic syndrome, the presence of elevated uric acid concentrations is closely associated with raised triglyceride levels, for reasons that have not been clearly defined. It remains to be seen whether uric acid could or should be considered a specific therapeutic target in cardiovascular disease and especially in hypertension and if so what should be the optimal pharmacological approach to lowering serum urate levels.
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PMID:Uric acid and hypertension. 1637 35

Uric acid is strongly associated with cardiovascular and renal disease, but is usually not considered to have a causal role. However, recent experimental, epidemiological, and clinical studies provocatively suggest that uric acid may contribute to the development of hypertension, metabolic syndrome, and kidney disease in some patients. Clinical studies are urgently needed to examine this important possibility.
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PMID:Unearthing uric acid: an ancient factor with recently found significance in renal and cardiovascular disease. 1659 94

Epidemiologic studies published during the past 3 years support the possible role of uric acid in the onset of essential hypertension. Data from several large, longitudinal cardiovascular disease studies indicate that elevated serum uric acid is a predictor of incident hypertension and blood pressure progression. In a pediatric study, more than 90% of children with essential hypertension have serum uric acid levels above 5.5 mg/dL. During the same period, laboratory studies have provided compelling mechanistic evidence to explain the clinical observations. Uric acid causes hypertension in a rat model through the activation of the renin-angiotensin system, downregulation of nitric oxide, and induction of endothelial dysfunction and vascular smooth muscle proliferation. Ongoing clinical trials will elucidate the role of uric acid in human hypertension and will determine whether control of uric acid may be a new way to prevent or treat essential hypertension.
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PMID:Uric acid and hypertension. 1667 42

We tested the hypothesis that endothelial dysfunction could cause placentation-related defects, persist after the complicated pregnancy, and probably cause cardiovascular disease later in life. Brachial arterial reactivity and factors related to endothelial dysfunction, such as circulating cholesterol, uric acid, nitrites, l-arginine, asymmetrical dimethylarginine, vascular endothelial growth factor, and soluble vascular endothelial growth factor receptor-1, in women with previous healthy pregnancies (n=22), patients with severe preeclampsia (n=25), or patients with recurrent pregnancy loss (n=29), at day 10 of the luteal phase of an ovulatory cycle an average of 11 to 27 months after pregnancy were evaluated. Both groups with placentation defects had a significant decrease in endothelium-dependent dilatation, a higher rate of endothelial dysfunction, lower serum nitrites, and higher cholesterol as compared with control subjects; subjects with previous preeclampsia additionally had higher normal blood pressures and a greater parental prevalence of cardiovascular disease. Patients with recurrent pregnancy loss also demonstrated a significantly lower endothelium-independent vasodilatation. A trend to an inverse correlation was found between serum cholesterol serum and endothelial-mediated vasodilatation in the whole study population. Uric acid, l-arginine, asymmetrical dimethylarginine, vascular endothelial growth factor, and soluble vascular endothelial growth factor receptor-1 were similar in all of the groups. We postulate that endothelial dysfunction may represent a link between preeclampsia and increased cardiovascular disease latter in life and propose that women with unexplained recurrent miscarriages are also at increased cardiovascular risk. The identification and correction of endothelial dysfunction detected during the reproductive stage on obstetric outcome and on cardiovascular diseases needs to be elucidated.
Hypertension 2007 Jan
PMID:Endothelial dysfunction: a link among preeclampsia, recurrent pregnancy loss, and future cardiovascular events? 1711 60


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