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Query: UMLS:C0028754 (obesity)
 124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The association of obesity with hypertension has been amply demonstrated in cross-sectional, longitudinal, and dietary-intervention studies, but the mechanisms remain enigmatic. Both conditions are independently characterized by similar metabolic alterations, i.e., glucose intolerance, dyslipoproteinemia, elevated serum uric acid, and inadequate Na+ transport. Obesity, hypertension, and these metabolic alterations are associated with hyperinsulinemia/insulin resistance. The degree of these alterations is lowest in lean hypertensives, intermediate in obese normotensives, and greatest in obese hypertensives, but mortality risk is highest in lean hypertensives. This apparent discrepancy may be related to the divergent hemodynamic characteristics, possibly indicating different etiology, of lean and obese hypertensives, i.e., contracted blood volume, increased total vascular peripheral resistance, and normal sympathetic drive in the former, expanded blood volume, normal peripheral resistance, and increased sympathetic drive in the latter. Current knowledge suggests that the interrelationships of obesity and hypertension with the metabolic alterations could be mediated by high carbohydrate and fat consumption and low physical activity, resulting in obesity and separate pathways in hyperinsulinemia and increased sympathetic drive, leading to a double vicious cycle. In one, hyperinsulinemia and the consequent insulin resistance would compound one another. In the second, the increasing hyperinsulinemia would increasingly stimulate the sympathetic nervous system. This double vicious cycle could result in increasing hemodynamic and metabolic derangements causing hypertension, diabetes, and atherosclerotic cardiovascular disease (ASCVD). The association of lean hypertension with ASCVD may be through other mechanisms, e.g., hemodynamic forces on the vascular endothelium.
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PMID:Hyperinsulinemia or increased sympathetic drive as links for obesity and hypertension. 186 20

We investigated the influence of the diabetic state on the contractile response of longitudinal segments of isolated mesenteric vein to prostanoids and leukotriene (LT), and the contribution of the vascular endothelium to modulation of the contractile response was determined. The normal mesenteric vein and de-endothelialized veins of normal (ddY), diabetic KK-CAy and streptozotocin ddY mice (150 mg/kg, i.v., 6 weeks) were used. In the diabetic state, the contractions produced by noradrenaline (60 microM), high K+ solution (143.4 mM), and the thromboxane A2 analogue U-46619 (29 nM-29 mM) were not affected, and LTD4 (0.1 nM-1 microM)-induced contraction was suppressed. Contractions induced by prostaglandin (PG) E2 (0.2 microM-2 mM), PGF2 alpha (0.3 microM-0.3 mM) and the prostacyclin derivatives PGI2-Na (10-100 microM) and TRK-100 (0.2 microM-2 mM) were significantly enhanced in the presence of an intact vascular endothelium, but not in de-endothelialized segments. The increase in PGF2 alpha (0.28 mM) contractions was dependent on age (correlation coefficient r = 0.36, significant difference, P less than 0.05) and blood glucose (r = 0.88, significant difference, P less than 0.01), but was independent of obesity. The contractile response to PGD2 (0.3-0.9 mM) was enhanced in both intact and de-endothelialized segments. These results indicate that the diabetic state affects prostanoid responses in an endothelium-dependent manner, except for the PGD2 response, which is independent of the endothelium.
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PMID:Diabetes-induced enhancement of prostanoid-stimulated contraction in mesenteric veins of mice. 262 93

Focus in this discussion of pulmonary embolism is on the following: risk factors (age, heredity and blood type, obesity, estrogen and oral contraceptive use/pregnancy, cardiovascular disease, cancer, and other risk factors); pathophysiology and presenting symptoms; laboratory procedures and findings (radiography, electrocardiography, lung scanning, and evaluation of lower extremity veins); treatment modalities (heparin therapy, thrombolysis, and surgery); and prevention. Pulmonary embolism may be the primary cause or a major contributory cause in as many as 200,000 deaths per year in the US. Most of these deaths occur in patients in whom the diagnosis is not suspected and, thus, not treated. The mortality rate for untreated pulmonary embolism is approximately 30%. 90% of patients survive the initial embolic event, but the correct diagnosis is made in no more than 2/3 of cases. Risk factors for the development of deep venous thrombosis are based upon the Virchow-Aschoff postulates, which include: trauma or disruption of the vein wall; stasis of blood flow in the veins; and increased coagulability of the blood. More than 85-90% of all pulmonary emboli originate from deep venous thromboses in the popliteal and femoral deep veins. Other important, although less frequent, sites of origin of venous thromboembolism include the pelvic veins, the renal and hepatic veins, the axillary veins in the upper extremities, and the right atrium. Accurate diagnosis and effective prevention and treatment depend on the clinician's awareness of risk factors for development of deep vein thrombosis. Estrogen may accelerate intimal proliferation in arteries and veins, and it may also increase permeability of venous vascular endothelium. The risk of thromboembolism increases as the dose of estrogen increases. Both pregnancy and oral contraceptive use significantly decrease venous tone and the velocity of blood flow in the calf of the leg. Appropriate treatment includes thrombolytic therapy for patients with massive pulmonary embolism, which results in hypotension or shock. Anticoagulant therapy with herapin followed by an oral anticoagulant is the primary treatment for most patients with submassive emboli in which there is less cardiovascular compromise. When thrombolytic therapy is used, it should always be followed by anticoagulant therapy. Prevention of primary or recurrent deep vein thrombosis is directed toward improving venous blood flow and reducing hypercoagulability.
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PMID:Pulmonary embolism: incidence, diagnosis, prevention, and treatment. 398 Feb 63

The prevalence of hypertension in diabetes is significantly higher than in non-diabetics, perhaps twice as common. The excess is related to diabetic nephropathy, mainly in type 1 diabetes, to obesity, mainly in type 2 diabetes, but also to increased sympathetic activity. Furthermore, the increased prevalence of hypertension may relate to insulin resistance and its sequelae. Insulin resistance leads to hyperinsulinemia, relates to increased LDL and reduced HDL levels, causes the development of impaired glucose tolerance and type 2 diabetes and might also be causally related to the onset of hypertension. Syndrome X has relevant therapeutic implications in the management of hypertension. Hypertension is a major risk factor for large vessel disease in diabetics and also a risk factor for microangiopathy, particularly nephropathy. The incidence of atherosclerotic disease is dramatically increased in both type 1 and type 2 diabetics and is the major cause of morbidity and premature death mainly in patients with raised urinary albumin excretion. Thus, diabetics show a two-fold increased risk of coronary heart disease, 2-6 fold increased risk of stroke and a several-fold increased risk of peripheral vessel disease. Some evidence suggests that hypertension may be a risk factor for retinopathy, particularly its progression, but surely hypertension is a significant risk factor for nephropathy, accelerating its progression and perhaps even causing the onset of the glomerulopathy. The mechanisms by which hypertension might contribute to the evolution of both large vessel as well as small vessel disease is still unknown, although increased capillary leakage and vascular endothelium alterations might be important factors.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Hypertension and diabetes]. 856 58

I have presented data to support an interaction of insulin with the vascular endothelium to cause the release of NO and vasodilation. In effect, insulin-mediated vasodilation can be viewed as a novel test of endothelial function. The physiologic significance of insulin-mediated, endothelium-dependent vasodilation is not fully understood, but some insight has been gained. Insulin-mediated vasodilation in skeletal muscle appears to be an important mechanism to amplify insulin's overall action to stimulate skeletal muscle glucose uptake in insulin-sensitive man. Insulin-resistant states of obesity, hypertension, and NIDDM exhibit blunted insulin-mediated vasodilation and impaired endothelium-dependent vasodilation. Together, the data suggest that endothelial dysfunction is an integral aspect of the syndrome of insulin resistance, independent of hyperglycemia, and as such may contribute to worsen insulin resistance, increase vascular reactivity, 32 and predispose to macrovascular disease. Thus, the insulin/EDNO interaction provides a potential mechanism (but certainly not the only one) linking insulin resistance, hypertension, thrombosis, and atherosclerosis-key features of the insulin resistance syndrome (Figure 7). Future research into the signal transduction steps leading to insulin-mediated, endothelium-derived NO production and its dysregulation in insulin-resistant states will be extremely useful to elucidate the mechanisms underlying the increased macrovascular risk in insulin-resistant man.
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PMID:Insulin and the vasculature--old actors, new roles. 895 21

The pulmonary complications remain the prime cause of morbidity and mortality in sickle cell disease. The pathogenetic mechanisms consists both of an alteration of the rheological properties of the blood, the existence of a hypercoagulability state and above all specific interactions between the abnormal sickle cells and the vascular endothelium and a dysregulation of the vascular reactivity in which nitrous oxide intervenes. The acute chest syndrome (ACS) is characterised by chest pain with dyspnoea and recent radiological abnormalities and it is an acute lung complication whose problem is one of aetiology. The infectious pneumonias are rarely documented. On the other hand, alveolar hypoventilation linked to infarcts of the thoracic ribs, thoracoabdominal trauma, subdiaphragmatic pain, the administration of analgesics causing respiratory depression, obesity or sleep disturbance are frequent causes of ACS. Bronchoalveolar lavage has revealed a frequency of fat emboli following infarcts in the long bones. Pulmonary emboli is rarely a cause. Pulmonary thrombosis is a serious complication, the diagnosis is difficult and is seen in a predisposed clinical setting. The treatment of ACS rests on controlled hydration and antibiotic therapy, oxygen therapy and controlled analgesic therapy. The indications for blood transfusion and for exchange transfusion merits a better evaluation. In the long term patients with sickle cell disease present with a failure of normal thoracopulmonary growth with a restrictive ventilatory defect and progressive diminution in the transfer factor of carbon monoxide with age. A history of ACS favours chronic lung disease. Pulmonary arterial hypertension is less frequent.
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PMID:[The sickle cell anemia lung from childhood to adulthood]. 960 86

Twenty-nine obese female Zucker rats (fa/fa) were fed with a laboratory chow supplemented or not with a selenium-rich yeast (Selenion), or Selenion + vitamin E, or vitamin E alone. Twelve lean female Zucker rats (Fa/Fa) of the same littermates fed with the same diet were used as control. After 32 wk of diet, obesity induced a large increase in plasma insulin and lipid levels. A significant decrease in the plasma vitamin E/triglycerides ratio (p<0.005) and an increase in plasma thiobarbituric reactive substances (TBARS) (p<0.005) were also observed. Plasma selenium and vitamin E increased in all supplemented rats. The plasma insulin level was decreased by selenion supplementation and the vitamin E/triglycerides ratio was completely corrected by double supplementation with Selenion + vitamin E. TBARS were also efficiently decreased in two obese groups receiving vitamin E. In plasma, adipose tissue and aorta, obesity induced an increase in palmitic acid (C16:0), a very large increase in monounsaturated fatty acids (palmitoleic acid C16:1, stearic acid C18:1) associated with a decrease in polyunsaturated n-6 fatty acids (linoleic acid C18:2 n-6, arachidonic C20:4 n-6). These alterations in fatty acid distribution were only partly modulated by Se and vitamin E supplements. However, in the aorta, antioxidant treatment in obese rats significantly reduced the increase in C16:0 and C16:1 (p<0.05 and p<0.01, respectively) and the decrease in arachidonic acid (p<0.05). These changes could be beneficial in the reduction of insulin resistance and help to protect the vascular endothelium.
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PMID:Effect of selenium and vitamin E supplementation on lipid abnormalities in plasma, aorta, and adipose tissue of Zucker rats. 989 95

While the prevalence of hypertension is clearly increased among the overweight persons, the pathophysiological mechanisms underlying this frequent association of obesity and hypertension are still poorly understood. The expansion of extracellular volume, inducing hypervolaemia and increased cardiac output, represents the characteristic haemodynamic feature of the obesity-related hypertension. The maintenance of hypervolemia in the face of elevated blood pressure, indicates a resetting of pressor natriuresis toward higher blood pressure. The development of hypertension also indicates an increase in peripheral vascular resistance, thus the lack of physiological adaptation of peripheral resistance to increased cardiac output. The mechanisms underlying these changes in renal function and vascular reactivity can no longer be attributed to hyperinsulinaemia as such, but might be related to insulin resistance responsible for the enhancement in pressor activity of noradrenaline and angiotensin II. This increased reactivity to pressor factors may be due to an inadequate nitric oxide generation by vascular endothelium and to increased sodium and calcium concentration in vascular smooth muscle cells. The role of increased neuropeptide Y (NPY) activity, may also be involved. As to enhancement of tubular sodium reabsorption, it could be related to histological changes within the renal medulla, leading to compression of tubules and vasa recta, hence a more efficient sodium reabsorption. As to the therapeutic approach, the low-energy sodium-restricted diet associated with increased physical activity, represents the cornerstones of treatment for the obesity-related hypertension. If this approach fails, the pharmacological treatment becomes necessary, and the use of the converting enzyme inhibitors seems to be the most appropriate choice of drug therapy for hypertensive obese patients.
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PMID:Obesity and hypertension: from pathophysiology to treatment. 1019 61

Acute studies suggest that leptin has pressor and depressor actions, including stimulation of sympathetic activity as well as increased release of NO from the vascular endothelium. The goal of this study was to examine the role of NO in modulating the chronic blood pressure, heart rate, and renal responses to hyperleptinemia, comparable to that found in obesity-induced hypertension. Male Sprague-Dawley rats were implanted with arterial and venous catheters, and mean arterial pressure and heart rate were monitored continuously 24 h/d. After a 4-day control period, the rats were infused with isotonic saline vehicle (n=6) or N(G)-nitro-L-arginine methyl ester (L-NAME, 10 microgram/kg per minute; n=9) to inhibit NO synthesis for 7 days. After 7 days of vehicle or L-NAME administration, leptin was infused intravenously for 7 days at a rate of 0.5 microgram/kg per minute, followed by a leptin infusion at 1.0 microgram/kg per minute for 7 days, along with vehicle or L-NAME. A 21-day infusion of L-NAME alone (n=6) served as a control for the L-NAME+leptin rats. Although the low dose of leptin alone did not significantly elevate arterial pressure, it raised the heart rate by 18+/-3 bpm. The higher leptin infusion rate raised arterial pressure from 96+/-3 to 104+/-3 mm Hg but did not increase the heart rate further. L-NAME+leptin increased arterial pressure by 40+/-6 mm Hg and heart rate by 79+/-19 bpm compared with pretreatment levels. In control L-NAME rats, mean arterial pressure increased by 31+/-4 mm Hg, whereas the heart rate was not altered significantly compared with pretreatment levels. Neither chronic leptin infusion alone nor L-NAME alone altered the glomerular filtration rate or renal plasma flow significantly, but L-NAME+leptin reduced glomerular filtration rate by 27+/-11% and renal plasma flow by 47+/-9%. These results indicate that impaired NO synthesis mildly enhances the chronic renal hemodynamic and hypertensive effects of leptin but markedly amplifies the tachycardia caused by hyperleptinemia.
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PMID:Inhibition of NO synthesis enhances chronic cardiovascular and renal actions of leptin. 1123 Mar 54

Endothelin-1, released from the vascular endothelium after cleavage from big endothelin-1, is a potent paracrine vasoconstrictor peptide. Small studies suggest that circulating levels of endothelin-1 are elevated in subjects with cardiovascular risk factors. Big endothelin-1 levels may better reflect endothelin-1 generation. We examined relationships between plasma endothelin-1, plasma big endothelin-1, and predisposition to hypertension or other cardiovascular risk factors associated with insulin resistance in a large group of healthy young men. We recruited 96 healthy men aged 24-33 years from a cohort of 864 young men and women in whom predisposition to hypertension had been defined on the basis of their own blood pressure and the blood pressures of their parents. They attended after an overnight fast for measurement of blood pressure, anthropometry, and plasma lipids, insulin, glucose, endothelin-1 and big endothelin-1. Plasma endothelin-1 and big endothelin-1 levels did not correlate with blood pressure (r=0.09, -0.002 respectively) and were not influenced by parental blood pressure. Higher plasma endothelin-1 levels were associated with higher body mass index (r=0.29, p<0.005), and higher plasma insulin (r=0.21, p<0.05). Higher plasma big endothelin-1 levels were associated with insulin resistance, as assessed by the Homeostasis Model of Assessment resistance index (r=0.30, p<0.005). Endothelin-1 levels are not related to blood pressure, but are higher in healthy young men with insulin resistance and obesity.
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PMID:Activation of the endothelin system in insulin resistance. 1139 Oct 30


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