UMLS:C0020538 - FACTA Search

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

Erythropoietin is a hypoxia-induced hormone that is essential for normal erythropoiesis. The production of recombinant human erythropoietin (rHuEpo) has revolutionized the treatment of anemia associated with chronic renal failure and chemotherapy, and has been used as prophylaxis to prevent anemia after surgery. The erythropoietin receptor is widely distributed in the cardiovascular system, including endothelial cells, smooth muscle cells and cardiomyocytes. Epo has potentially beneficial effects on the endothelium including anti-apoptotic, mitogenic and angiogenic activities. On the other hand, some reports suggest that rHuEpo may have pro-thrombotic or platelet-activating effects. Hypertension develops in 20-30% of renal patients treated with rHuEpo. Many patients with heart failure have anemia. Despite some potential adverse effects, early studies in heart failure patients with anemia suggest that rHuEpo therapy is safe and effective in reducing left ventricular hypertrophy, enhancing exercise performance and increasing ejection fraction. Further studies are warranted to define the role of rHuEpo in chronic heart failure and other cardiovascular settings.
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PMID:The cardiovascular effects of erythropoietin. 1449 55

Evaluation of anemia: Before beginning epoetin treatment, it is essential to evaluate the level of anemia (Hb < 11-12g/dL) by the following measurements: -Hb concentration -Red blood cell indices (MCV, MCH, MCHC) -Reticulocyte count -Iron stores and availability -C-reactive protein (CRP) Target for anemia treatment: The minimum target Hb concentration to be attained is 11 g/dL. The upper limit is established individually on a clinical basis. Pending further data, it is advisable to maintain and not exceed 12 g/dL for patients with cardiovascular disease, diabetes, and graft access. Use of iron: At the start of epoetin treatment, 150 mg of iron are needed for every expected increase of 1 g/dL of Hb. It is important to achieve and maintain levels of TSAT > 20%, serum ferritin 100 mcg/L and hypochromic red cells > 6% both before initiating epoetin treatment and during its administration. TSAT levels should not persistently exceed > 50% and serum ferritin > 500 mcg/L. When administering oral iron the dose should be at least 200 mg/die elemental iron; on the other hand, when the intravenous route is used, the dose should be 30-60 mg/IV dose in the form of low molecular weight salts (iron sodium gluconate) while the higher doses should be reserved for patients with transferring levels > 170 mg/dL. Administration of epoetin: The dosage of epoetin is individual with more than tenfold variability among individuals and all aiming at the same target Hb concentration. There are no clinical parameters entirely capable of predicting the necessary dosage. Therapeutic range is very wide, without any toxic effects for clinical use up to 100.000 IU/week. The target Hb concentration is reached in most patients with mild anaemia after 2 months' treatment with 4.000-10.000 epoetin (20-50 mcg darbepoetin alpha) per week. The HB concentration, along with the reticulocyte count, must be checked weekly following initiation and monthly during maintenance. Patients with a stable dose-response during conservative therapy may require less frequent monitoring (every 2-3 months). Inadequate response to epoetin treatment If any resistance is encountered, after excluding all the acute and chronic conditions of inadequate response, the reticulocyte count (severe reduction in the presence of anti erythropoietin antibodies) and the erythropoietin dosage should be measured. The target Hb concentration 11-12 g/dL is maintained in 90-95% of the patients by administering 1.000-30.000 IU of epoetin (5-150 mcg darbepoetin alpha) per week in the presence of adequate reserves of iron. Higher dosages define a state of resistance. Diagnosis of pure red cell (PRCA) from anti-erythropoietin antibodies is confirmed by bone marrow examination (almost total loss of erythroblasts). If antierythropoietin antibodies are present or there is a well founded suspicion of PRCA, the administration of epoetin and other similar treatment should be avoided. Side effects of epoetin treatment: The treatment of anaemia with epoetin does not hasten the progression of CRF. Blood pressure is to be checked regularly during initiation of epoetin and the treatment should be discontinued in cases of refractory hypertension or hypertensive encephalopathy. There should be increased surveillance of graft access, especially in those patients who risk vascular depletion. In general, heparin requirements do not increase but it may be advisable to evaluate a dose increase. PRCA from anti-erythropoietin antibodies has been detected with an incidence ranging from 0.12 to 1.1 cases/every 10 thousand patients treated.
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PMID:[Guidelines for the treatment of anemia in chronic renal failure]. 1466 4

Erythropoietin (Epo) was once thought to act exclusively in the formation of red blood cells. As recently reviewed by Smith et al. [Cardiovasc. Res. 59 (2003) 538-548], Epo can also act within the cardiovascular system with effects in thrombosis and hypertension as well as actions on platelets, vascular endothelium and smooth muscle, and myocytes of the heart. Here, the actions of Epo to protect neuronal cells of the brain are first evaluated and parallel actions of Epo in cardioprotection are then drawn. Thus, with recent reports of Epo receptor (EpoR) expression by cardiac myocytes, it could be predicted that Epo initiates direct protective signalling events. This is supported by five independent studies published in 2003 showing Epo protects cardiac myocytes following ischemia/reperfusion. Importantly, these protective actions have been observed in vitro and in vivo. The former suggests the direct actions of Epo to prevent myocyte death independently of its effects on red blood cell number or cells other than cardiac myocytes. The latter demonstrates the potential for Epo in the treatment of the heart post-infarction, decreasing the numbers of apoptotic myocytes, limiting infarct expansion and attenuating the post-infarct deterioration in haemodynamic function. These beneficial effects of Epo should stimulate further research into the actions of Epo.
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PMID:An update on the cardiac effects of erythropoietin cardioprotection by erythropoietin and the lessons learnt from studies in neuroprotection. 1524 78

Recombinant human erythropoietin therapy frequently causes hypertension in humans and animals with chronic renal failure. Asymmetric dimethylarginine (ADMA) is an endogenous inhibitor of nitric oxide (NO) synthase, and its accumulation has been associated with reducing NO bioavailability and increasing superoxide generation. Whether epoetin beta (EPO) or darbepoetin alpha (NESP) can modify the levels of ADMA in endothelial cells was investigated. Endothelial cells from the third passage were incubated for 24 h in the presence of various concentrations of EPO or NESP (0, 0.1, 1, 10, 50, 100, and 200 U/ml). The levels of ADMA, allantoin, nitrate, and nitrite in conditioned media and the activity of dimethylarginine dimethylaminohydrolase (DDAH), the content of thiols and reactive oxygen species in endothelial cells, were determined. When endothelial cells were exposed to EPO or NESP, ADMA concentration in the cell culture medium increased significantly in a dose-dependent manner versus control. This effect was associated with a reduced activity of DDAH, the enzyme that degrades ADMA. Furthermore, EPO- or NESP-induced accumulation of ADMA was accompanied by a significant reduction of NO synthesis and an increase in oxidative stress. Both allantoin, a marker of oxygen free radical generation, and reactive oxygen species increased significantly after EPO or NESP treatment compared with control. The antioxidant pyrrolidine dithiocarbamate preserved DDAH activity and reduced ADMA accumulation in the same way as the co-incubation with anti-EPO neutralizing antibody. EPO and NESP posttranslationally impair DDAH activity via increased oxidative stress, causing ADMA as an important cardiovascular risk factor to accumulate and inhibit NO synthesis.
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PMID:Erythropoietin increases asymmetric dimethylarginine in endothelial cells: role of dimethylarginine dimethylaminohydrolase. 1572 83

Epoetin treatment of renal anemia has been practiced in Slovenia since 1988. More than 90% of hemodialysis patients and 83% of peritoneal dialysis patients have been treated with epoetin. Epoetin has also been available for patients with renal anemia in the pre-dialysis period and for those with a failing kidney allograft. Although epoetin treatment did not accelerate the worsening of native kidney function or allograft function, intensified antihypertensive treatment was required in kidney graft recipients. In patients on peritoneal dialysis, hypervolemia had a greater effect on hypertension than did epoetin treatment. Epoetin resistance was connected with C-reactive peptide cryptorchidism, intact parathyroid hormone, and treatment with angiotensin-converting enzyme inhibitors. In hemodialysis patients, lower doses of epoetin were required for patients receiving low molecular heparin and those with lower iPTH. Epoetin alpha, epoetin beta and epoetin omega seemed to be effective and safe in the treatment of renal anemia. In the past 2 years, epoetins were administered to hemodialysis patients only intravenously.
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PMID:Our experience with epoetins in treating renal anemia. 1596 88

Erythropoietin is a hypoxia-induced hormone that is a major regulator of normal erythropoiesis. Over the last decade, the production of recombinant human erythropoietin has revolutionized the treatment of anemia associated with chronic renal failure, and has led to a greater understanding of anemia pathophysiology and to the elucidation of the interactions of erythropoietin, iron, and erythropoiesis. Anemia has been shown to be independently associated with increased mortality and disease progression. Potential survival benefits associated with correction of anemia have expanded considerably the indications of erythropoietin use in various patient populations and are leading to consideration of earlier, more aggressive treatment of mild to moderate anemia. The results of such treatment are promising in a variety of new clinical settings, including anemia associated with congestive heart failure. Furthermore, the erythropoietin receptor is widely distributed in the cardiovascular system, including endothelial cells, smooth muscle cells and cardiomyocytes and preclinical studies have established erythropoietin to be a pleiotropic cytokine with anti-apoptotic activity and tissue-protective actions in the cardiovascular system, beyond correction of hemoglobin levels. Despite some potential adverse effects, such as hypertension, and the occurrence of erythropoietin resistance, early studies in heart failure patients with anemia suggest that erythropoietin therapy is safe and effective in reducing left ventricular hypertrophy, enhancing exercise performance and increasing ejection fraction. Anemia is found in about one-third of all cases of congestive heart failure (CHF). The most likely common cause is chronic renal insufficiency, which is present in about half of all CHF cases. However, anemia can occur in CHF without renal insufficiency and is likely to be due to excessive cytokine production. The anemia itself can worsen cardiac function, both because it causes cardiac stress through tachycardia and increased stroke volume, and because it can cause a reduced renal blood flow and fluid retention, adding further stress to the heart. Long-standing anemia of any cause can cause left ventricular hypertrophy, which can lead to cardiac cell death through apoptosis and worsen CHF. Therefore, a vicious circle, cardio-renal anemia syndrome, is set up wherein CHF causes anemia, and the anemia causes more CHF and both damage the kidneys worsening the anemia and the CHF further and increasing mortality. There is now evidence that early correction of the CHF anemia with subcutaneous erythropoietin and intravenous iron improves shortness of breath and fatigue, cardiac function, renal function and exercise capacity, reducing the need for hospitalization and improving quality of life. In the present review we discuss the data on current clinical use of erythropoietin in cardiovascular disease, with the main focus on the treatment of congestive heart failure, and summarize the advances and progress made in the understanding of the hematopoietic and pleiotropic effects of erythropoietin in the cardiovascular system.
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PMID:Erythropoietin in heart failure and other cardiovascular diseases: hematopoietic and pleiotropic effects. 1624 29

(1) Current treatments for anaemia in patients receiving cancer chemotherapy include blood transfusion and epoetin alfa and beta. These epoetins correct anaemia in 40% to 65% of patients and reduce the number of patients who require transfusions during the second and third months of treatment by 12-35% in absolute terms. (2) Darbepoetin alfa is slightly more glycosylated than epoetin alfa and beta. It is no more effective than these two drugs in chronic renal failure. Darbepoetin alfa is now approved for the treatment of anaemia in patients who are receiving chemotherapy for non myeloid malignancies. (3) Two placebo-controlled dose-finding studies and two placebo-controlled trials involving nearly 1000 patients in total have shown that darbepoetin alfa decreases the number of transfused patients by 17-25% in absolute terms, and that it probably reduces fatigue. However, one-quarter of patients receiving darbepoetin were nonetheless transfused. (4) In the absence of reliable comparisons, there is no firm evidence that darbepoetin alfa is more effective than other epoetins. (5) According to relatively imprecise company reports, darbepoetin alfa increased the risk of thromboembolic events during clinical trials (6% versus 3%), including pulmonary embolism (1.3% versus 0%); the company also states that darbepoetin alfa does not increase the risk of arterial hypertension, a classical effect of epoetin that is mentioned in the summary of product characteristics (SPC). Placebo-controlled trials and dose-finding studies show no impact on the outcome of cancer, but follow-up is limited and a negative effect cannot be ruled out. The company states that no cases of erythroblastopenia have occurred among more than 70 000 treated patients. (6) According to the SPC, darbepoetin alfa can be given once a week. However, the optimal epoetin dosing schedule is unknown. Epoetin therapy takes several weeks to correct anaemia, whereas transfusion is immediately effective. (7) In practice, darbepoetin alfa seems a little easier to administer than epoetin alfa or beta, but the advantages and disadvantages of these drugs as compared with blood transfusion are not entirely clear.
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PMID:Darbepoetin alfa: new indication/new dosage. No proven advantage in chemotherapy-induced anaemia. 1628 72

At the age of 69 years, a woman with recurrent gastrointestinal bleeding underwent investigation by gastroscopy and colonoscopy. Extensive telangiectatic changes were observed in the canalis and antrum of the ventricle and in the colon. In parallel, the woman suffered from nephrotic syndrome, hypertension, and progressive renal failure attributable to chronic glomerular changes with extensive interstitialfibrosis. The progressive renal failure and recurrent gastrointestinal bleeds made frequent transfusions and erythropoietin injections necessary. Because of those complications, and because CAPD avoids the intermittent overhydration of a therapy such as hemodialysis and the risk of using anticoagulants, it was decided to perform continuous ambulatory peritoneal dialysis (CAPD) when dialysis became necessary. After CAPD was started, the woman's bleeding episodes decreased within 1 week. After 70 months of CAPD, the woman is well, without gastrointestinal bleeding. No transfusions have been necessary since the start of CAPD. For the now 77-year-old woman, data are as follows: epoetin beta dose, 12,000 U/week; body weight, 67 kg; hemoglobin, 130 g/L. The woman has experienced 1 episode of peritonitis since starting dialysis (6 months before the time of writing), because of a malfunction of the peritoneal dialysis device. No intestinal perforations have occurred. It seems worthwhile to try CAPD for dialysis in patients with morbus Osler
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PMID:Peritoneal dialysis as a plausible option in morbus Osler: case report. 1668 2

Forty five (24 male & 21 female) moderate to severe degree of predialysis CRF patients were prospectively studied over a period of 6 months (July- December, 2004) to see the effect of Recombinant Human Erythropoietin (rHuEpo/EPO) therapy on renal anaemia, progression of renal excretory function & quality of life at 3 and 6 months intervals from the starting of EPO therapy. Mean +/- SD age of the patients was 56 +/- 12 (30-77 yrs) and causes of CRF were Diabetic Nephropathy (DN)=15 (33%), Chronic Glomerulonephritis (CGN) =14(31%), Hypertension (HTN)=11(21%), Chronic Pyelonephritis (CPN)=03 (6.5%) and Obstructive Uropathy (OU)=02 (4.5%). Doses of rHuEpo was 80-100 IU/k week subcutaneously (SC) until the target Hb 11gm% & Hct 30% were achieved; there after the dose was titrated as appropriate. Serum Iron & Ferritin levels were also kept within normal reference level by iron therapy during the study period. Mean +/- SD base line (before starting EPO therapy) level of haemoblobin were 8.4 +/- 0.81(gm%), Hct 27.86 +/- 1.6 (%), blood urea 21.72 +/- 10.5 (mmol/L), S. creatinine 431.93 +/- 228.79 (mmol/L) & Ccr. 21.25 +/- 10 mum respectively. The results showed that significant improvement of haemoglobin level occurred (gm%) from 8.4 +/- 0.81 (gm%) to 9.51 +/- 1.02 (p<0.001) at 3 months and 8.4 +/- 0.81 to 11.10 +/- 1.4, (p<0.001) at 6 months interval. Haematocrit (Hct%) value also significantly increased from 27.86 +/- 1.5 to 30.57 +/- 3.62, (p<0.001) at 3 months and 27.86 +/- 1.5 to 32.81 +/- 3.92 (p<0.001) at 6 months of EPO therapy. Mean blood urea and S. creatinine levels decreased from base line level during the study period but did not show any statistical significance. There was no significant side-effects like uncontrolled hypertension, seizure or hyperviscosity syndrome in any of the study population. The quality of life in terms of improvement of physical ability and sense of well being were also improved in all the study patients. In conclusion, this study showed that the effect of rHuEpo therapy is beneficial for the correction of renal anaemia, can delay the progression of renal failure and improvement of overall quality of life in predialysis CRF patients.
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PMID:Effect rHuEpo on predialysis CRF patients: study of 45 cases. 1696 14

Chronic kidney disease (CKD) is associated with increased cardiovascular (CV) risk. Left ventricular (LV) hypertrophy (LVH), together with coronary artery disease, has been considered the main target of intervention. LVH is highly prevalent in CKD even in early stages, as compared to general non-selected population. This is mainly due to the multifactorial pathogenesis of LVH in renal patients where both haemodynamic and non-haemodynamic stimuli synergically act inducing either an increase in left ventricular mass or an LV dilation. Anaemia and arterial hypertension seem to be the most important factors. Interventional studies have shown that partial correction of anaemia through epoetin, together with an arterial hypertension successful therapy through renin-angiotensin system acting drugs, such as ACE-inhibitors, were able to induce a LVH regression in CKD. Indeed, the unfavourable outcome in patients with both CKD and LVH, whose survival is reduced and incidence of fatal and non-fatal CV events increased, can be reversed if LVH is regressed by therapy. The most promising strategy in CKD seems to be LVH early diagnosis through echocardiography, the correct screening of risk factors, a LVM longitudinal monitoring through echo, as well as starting treatment in the early stages of CKD, with the aim of improving general and CV prognosis for these patients.
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PMID:[Left ventricular hypertrophy in chronic kidney disease]. 1717 62

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