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:C0037315 (sleep apnea)
8,000 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ambulatory blood pressure monitoring can determine the average blood pressure level and the short- and long-term blood pressure variability (circadian rhythm). The circadian blood pressure rhythm appears to be mediated mainly by the circadian rhythm of the sympathetic tone which is linked to changes in physical and mental activity, e.g. the waking-sleeping cycle. A statistically significant circadian blood pressure rhythm was observed in approximately 80% of mild to moderate essential hypertensive patients as well as in normal subjects. However, in patients with Cushing's syndrome, under glucocorticoid treatment, or with hyperthyroidism, central and/or peripheral autonomic dysfunction (Shy-Drager syndrome, spinal cord injury, brainstem lesions, diabetic neuropathy, uremic neuropathy, etc), chronic renal failure, eclampsia, malignant hypertension, sleep apnea syndrome or systemic atherosclerosis, the normal circadian blood pressure rhythm appears to be eliminated or reversed, while in those with primary aldosteronism, renovascular hypertension, pheochromocytoma without paroxysmal hypertension, diabetes insipidus, acromegaly, hyperparathyroidism or hyperprolactinemia, the nocturnal blood pressure fall has been observed as in normal subjects. The alteration in the circadian blood pressure rhythm was observed with different pathophysiological conditions, although no specific pattern was observed for any condition. A disturbance in any part of the hierarchy of factors that regulate the circadian rhythm of sympathetic neural tone seems to disturb the circadian blood pressure rhythm. We conclude that ambulatory blood pressure monitoring is not critically important in the diagnosis of secondary hypertension although it does help in screening for secondary hypertension.
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PMID:Does ambulatory blood pressure monitoring improve the diagnosis of secondary hypertension? 208 1

The daily variation in blood pressure (circadian blood pressure rhythm) is characterized by a nocturnal fall and a diurnal rise. The circadian blood pressure rhythm seems to be mediated mainly by the circadian rhythm of sympathetic tone, linked to changes in physical and mental activities, e.g. the waking-sleeping cycle. Statistically significant circadian blood pressure rhythms have been confirmed in approximately 80% of mild to moderate essential hypertensive patients as well as in normal subjects. However, the normal pattern of circadian blood pressure rhythm is reversed in elderly people and in those with Cushing's syndrome, those undergoing glucocorticoid treatment, and those with hyperthyroidism, central and/or peripheral autonomic dysfunction (Shy-Drager syndrome, tetraplegia, diabetic or uremic neuropathy, etc), chronic renal failure, renal or cardiac transplantation, congestive heart failure, eclampsia, sleep apnea syndrome, malignant hypertension, systemic atherosclerosis and accelerated hypertensive organ damage. However, in those with primary aldosteronism, renovascular hypertension, pheochromocytoma without paroxysmal hypertension, or those with cardiac pacing, a nocturnal blood pressure fall is ordinarily observed. It may be that a fall in cardiac output rather than in peripheral resistance may be mainly responsible for the nocturnal fall in blood pressure. It also seems that a nocturnal heart rate fall is not responsible for it, since the nocturnal blood pressure fall remained unchanged in patients undergoing cardiac pacing and was disturbed in patients with Cushing's syndrome or hyperthyroidism in whom the circadian heart rate rhythm remained unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Circadian blood pressure variations under different pathophysiological conditions. 209 80

A 60-year-old obese woman was admitted for evaluation of excessive daytime sleepiness, loud snoring, cyanosis, systemic edema, hypertension and diabetes mellitus. Laboratory examination showed severe hypoxemia, hypercapnea, metabolic alkalosis, hypokalemia and hyperaldosteronism. CT scan showed a left adrenal tumor. A diagnosis of obstructive sleep apnea syndrome associated with primary aldosteronism was established. Metabolic alkalosis, hypokalemia and sodium retention due to hyperaldosteronism were thought to be factors exacerbating her sleep apnea.
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PMID:[A case report of obstructive sleep apnea syndrome associated with primary aldosteronism]. 818 53

A less-than-normal decline in nocturnal blood pressure (BP) has been associated with excessive hypertensive complications. This is concerning because secondary hypertension is often associated with this so-called nondipper BP profile. A nondipping pattern is more frequently found in the presence of pheochromocytoma, Cushing's syndrome, and sleep apnea syndrome, but the prevalence is unclear in patients with primary hyperaldosteronism. We therefore studied ambulatory BP profiles in 16 hypertensive patients with primary hyperaldosteronism and an equal number of essential hypertensive subjects. The awake-sleep BP difference of the hyperaldosteronism patients was similar to that of essential hypertensives (15/14 +/- 3/2 versus 14/9 +/- 3/2 mm Hg, P=NS). The prevalence of dippers and nondippers (according to two distinct criteria) in the two groups was similar. Repeat ambulatory BP monitoring in 12 subjects with primary hyperaldosteronism after specific intervention (3 after surgical removal of an adrenal adenoma and 9 after commencement and titration of spironolactone therapy) showed highly significant reductions in office BP (22/10 +/- 6/4 mm Hg, P<.05) and awake and sleep BP. However, the extent of nocturnal BP decline was unchanged between the two studies (17/16 +/- 3/3 versus 16/12 +/- 2/2 mm Hg, P=NS). There was no correlation between the awake-sleep difference and serum or urinary aldosterone levels or the aldosterone-to-renin ratio. In this study, we did not detect any differences in the awake-sleep differences between a group of hypertensives with primary hyperaldosteronism and a control group of essential hypertensives.
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PMID:Circadian blood pressure variation in hypertensive patients with primary hyperaldosteronism. 949 70

Resistant hypertension is an increasingly common problem faced by primary care physicians and specialists and will undoubtedly become even more common as the adult population ages and gains weight. In the Antihypertensive and Lipid-Lowering Treatment to Prevent Heart Attack Trial (ALLHAT), at least 8% of subjects were resistant to treatment based on the need for three or more antihypertensive agents. Characteristics of patients with resistant hypertension include being older, black, obese, and diabetic, and having chronic kidney disease as well as untreated sleep apnea. Hyperaldosteronism is common in patients with resistant hypertension, with a prevalence of approximately 20%. This, however, is likely an underestimation of the role aldosterone excess plays in causing drug resistance. In subjects with resistant hypertension, suppressed renin levels are common, exceeding 75% in our studies, suggesting aldosterone excess effects beyond cases of true primary hyperaldosteronism. Recent studies indicate that aldosterone antagonists provide significant blood pressure reduction when added to antihypertensive regimens of patients with resistant hypertension. Interestingly, the blood pressure reduction with use of spironolactone is not limited to patients with hyperaldosteronism, consistent with the concept of aldosterone excess as a continuum from low-renin hypertension with normal aldosterone levels to true primary hyperaldosteronism.
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PMID:The role of aldosterone antagonists in the management of resistant hypertension. 1615 75

Resistant hypertension, defined as uncontrolled hypertension on three medications, is becoming an increasingly common problem. In most cases, blood pressure remains elevated because of persistently high systolic blood pressure levels. Common characteristics of patients with resistant hypertension include older age, obesity, excessive dietary salt ingestion, and presence of sleep apnea. The evaluation of patients with resistant hypertension is focused on identifying contributing and secondary causes of hypertension. Treatment should include both lifestyle changes (weight loss, exercise, dietary salt restriction) and the use of effective multidrug regimens, including a diuretic. Recent data indicate that aldosterone antagonists may be effective when added to existing antihypertensive regimens even in the absence of primary aldosteronism.
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PMID:Resistant or difficult-to-treat hypertension. 1652 95

Resistant hypertension affects approximately 10% of the hypertensive patient population. It should be differentiated from white-coat hypertension and pseudo-resistant hypertension. Non-compliance to anti-hypertensive therapy remains the most common cause of resistant hypertension. Primary hyperaldosteronism is not as uncommon as previously thought, but its prevalence depends on the selected population. Low-renin resistant hypertension responds to aldosterone blockade when other drugs are apparently inadequately effective. Sleep apnea syndrome can also contribute to the development of resistant hypertension by stimulating aldosterone secretion, which leads to vascular damage and may promote scarring through more direct actions. Normal blood levels of potassium in resistant hypertension do not exclude the possible presence of hyperaldosteronism.
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PMID:Resistant hypertension: a methodological approach to diagnosis and treatment. 1767 42

Aldosterone concentrations are inappropriately high in many patients with hypertension, as well as in an increasing number of individuals with metabolic syndrome and sleep apnoea. A growing body of evidence suggests that aldosterone and/or activation of the MR (mineralocorticoid receptor) contributes to cardiovascular remodelling and renal injury in these conditions. In addition to causing sodium retention and increased blood pressure, MR activation induces oxidative stress, endothelial dysfunction, inflammation and subsequent fibrosis. The MR may be activated by aldosterone and cortisol or via transactivation by the AT(1) (angiotenin II type 1) receptor through a mechanism involving the EGFR (epidermal growth factor receptor) and MAPK (mitogen-activated protein kinase) pathway. In addition, aldosterone can generate rapid non-genomic effects in the heart and vasculature. MR antagonism reduces mortality in patients with CHF (congestive heart failure) and following myocardial infarction. MR antagonism improves endothelial function in patients with CHF, reduces circulating biomarkers of cardiac fibrosis in CHF or following myocardial infarction, reduces blood pressure in resistant hypertension and decreases albuminuria in hypertensive and diabetic patients. In contrast, whereas adrenalectomy improves glucose homoeostasis in hyperaldosteronism, MR antagonism may worsen glucose homoeostasis and impairs endothelial function in diabetes, suggesting a possible detrimental effect of aldosterone via non-genomic pathways.
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PMID:Aldosterone and end-organ damage. 1768 82

Management of resistant hypertension (RH), defined as uncontrolled blood pressure on three or more antihypertensive medications including a diuretic, begins initially with identifying and addressing contributors such as medication adherence, lifestyle factors and the use of interfering substances. Evaluation for the "white-coat" phenomenon, or associated conditions and secondary causes such as sleep apnea, primary aldosteronism, chronic kidney disease or renovascular disease may be indicated. Inadequate dosing, lack of using long-acting diuretics, and suboptimal combinations are observed as causes in nearly half of patients with RH. Appropriate pharmacotherapy of RH begins first with insuring the patient is receiving appropriate therapy for compelling indications, as outlined by the JNC-7 guidelines. Specific regimen enhancements to achieve blood pressure control include the addition of aldosterone antagonists, dual renin-angiotensin system blockade, and dual calcium channel blockade. Addition of centrally acting agents, alpha blockers, or vasodilators may also be necessary.
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PMID:Resistant hypertension: identifying causes and optimizing treatment regimens. 1870 62

Resistant hypertension is defined as uncontrolled blood pressure despite the use of three antihypertensive drugs, including a diuretic, in optimal doses. Treatment resistance can be attributed to poor adherence to antihypertensive drugs, excessive salt intake, physician inertia, inappropriate or inadequate medication, and secondary hypertension. Drug-induced hypertension, obstructive sleep apnoea, primary aldosteronism, and chronic kidney disease represent the most common secondary causes of resistant hypertension. Several drugs can induce or exacerbate pre-existing hypertension, with non-steroidal anti-inflammatory drugs being the most common due to their wide use. Obstructive sleep apnoea and primary aldosteronism are frequently encountered in patients with resistant hypertension and require expert management. Hypertension is commonly found in patients with chronic kidney disease and is frequently resistant to treatment, while the management of renovascular hypertension remains controversial. A step-by-step approach of patients with resistant hypertension is proposed at the end of this review paper.
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PMID:Common secondary causes of resistant hypertension and rational for treatment. 2142 78


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