UMLS:C0034065 - FACTA Search

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Query: UMLS:C0034065 (pulmonary embolism)
14,979 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

BRL 26921 (Eminase registered trade mark in Belgium, Germany and The Netherlands) is the p-anisoyl derivative of the primary (human) lys plasminogen-streptokinase activator complex (APSAC). The acyl-enzyme has the theoretical advantage of causing fibrinolysis in situ in the presence of fibrin clotbound plasminogen. It was administered to 34 patients with severe pulmonary embolism (PE) in an open multicentre study. PE was suspected on clinical, blood gas, ECG, and radiographic data. Pulmonary angiograms performed pre- and post-treatment confirmed the diagnosis and were assessed using the Miller Index (MI). Fibrinogen, plasminogen, alpha-2-antiplasmin, fibrinogen degradation products (FDP), activated partial thromboplastin time (APTT), partial thromboplastin time (PTT) were closely monitored before and after each administration of APSAC. Median angiographic improvement was 50% (range 0-94%). The following adverse events were reported: bleeding at puncture sites (n = 12), haematuria (n = 1), epistaxis (n = 3), fever (n = 2). A blood transfusion was given in one patient with an inguinal haematoma. Systemic fibrinogenolysis occurred in 20/28 patients.
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PMID:Thrombolytic treatment of pulmonary embolism with APSAC. 306 87

The Bolus Alteplase Pulmonary Embolism (BAPE) Group and a consortium of French investigators utilized essentially the same investigational protocol to test reduced dose bolus alteplase vs full dose 100 mg/2 h alteplase in the treatment of pulmonary embolism (PE). The principal hypothesis was that reduced dose bolus alteplase (n = 96) would result in fewer bleeding complications than full dose 100 mg of 2 h alteplase (n = 44) administered as a continuous infusion to hemodynamically stable patients with PE. To provide data on bolus alteplase's safety profile in a larger sample size than would have been feasible in either trial alone, we present an overview of the BAPE and French trials. There were no differences between the reduced dose bolus and full dose 2 h rt-PA groups with respect to bleeding complications. Therefore, the principal hypothesis of these two randomized controlled trials could not be confirmed. Efficacy was similar in the two treatment groups. Interpretation of the results will vary because the increased convenience and cost savings from using a reduced dose of bolus alteplase may be offset by a higher mortality rate. However, a trial that compared the mortality rates of the two treatment regimens would have required more than 800 patients.
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PMID:Two trials of reduced bolus alteplase in the treatment of pulmonary embolism. An overview. 808 47

Thrombolysis today has become a routine option not only in the treatment of acute myocardial infarction but also in many other manifestations of thromboembolic disease. Until one decade ago, only two plasminogen activators, streptokinase and urokinase, were available for clinical use. They were characterized by limited thrombolytic potencies and major side effects including systemic fibrinogen breakdown, bleeds and stroke. This has prompted the search for new plasminogen activators with better pharmacological and clinical profiles. The first such new plasminogen activators were Anistreplase, a chemically modified version of the streptokinase-plasminogen-activator-complex and tissue-type plasminogen-activator produced by recombinant technology. Both new substances have fueled the development in modern thrombolytic treatment. While the clinical progress with t-PA was confirmed in large, double-blind, randomized, multicenter trials, no real superiority of anistreplase over the traditional plasminogen activators urokinase and streptokinase has been substantiated. While the clinical use of t-PA today has been established for acute myocardial infarction, pulmonary embolism and deep vein thrombosis, current research is focused on further plasminogen activators with further improved thrombolytic properties. This review summarizes the current knowledge on the biochemical and pharmacological properties of the first, second and future generation of plasminogen activators.
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PMID:Thrombolytic agents--an overview. 885 12

From 1989 to September 1997 1184 patients with deep vein thrombosis were treated. 606 (51.2%) received a specific therapy with loco-regional lysis. The application of two cycles of 20 mg Alteplase within 8 hours prevailed in combination with 1000 IE heparin per hour. In absence or lack of therapeutical effect further cycles of 20 or 40 mg of Alteplase were given. In the time free from lysis the patients received 30,000 IE heparin/24 hours depending on the individual aPTT (1.5-2.5 times prolonged). We developed a special drainage-management using perforans-veins during the loco-regional lysis. Complete lysis resulted in nearly half of the cases and in another third there was a lysis of more than 50%. Complications were observed in 5.8% of the patients, 4% due to heparinization. Importantly no life-threatening bleeding like gastrointestinal or cerebral bleeding or pulmonary embolism occurred. According to our data we conclude that the loco-regional lytic effect tends to be better than using systemical lysis, the risks are minimized and patient monitoring and treatment is much simpler.
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PMID:[Experiences with loco-regional fibrinolytic therapy of deep venous thrombosis with defined drainage management]. 1009 Dec 92

Thrombolytic drugs, streptokinase and urokinase, were initially used in pulmonary embolism. More recently, new drugs like alteplase, reteplase, lanoteplase and saruplase have been a breakthrough in the treatment of acute myocardial infarction. Their efficacy has been demonstrated when treatment is initiated before the 6th hour of infarction onset. A 50% reduction of death rate is expected, if treatment starts within the 1st hour. Alteplase and reteplase are the most efficient thrombolytics despite a higher risk of cerebral bleeding. In pulmonary embolism with clinical signs of severity, thrombolysis is clearly indicated. In deep vein thrombosis of the lower limbs, therapeutic thrombolysis is still controversial. Some acute ischemic strokes (before the 3rd hour) could be treated with alteplase if there is no absolute or relative contraindication for thrombolysis. In prosthetic heart valve thrombosis, thrombolysis may be used if surgical treatment is contraindicated but the risk of bleeding and embolism should be taken into account.
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PMID:[Indications for thrombolytics]. 1058 97

Alteplase (t-PA), a recombinant analogue of human tissue plasminogen activator, became the first genetically engineered thrombolytic approved by the Food and Drug Administration in 1987 for acute myocardial infarction (AMI). In addition to AMI, alteplase is currently approved for the treatment of acute ischemic stroke and pulmonary embolism, and we anticipate approval for catheter clearance in late 2001 in a 2-mg vial configuration. With the withdrawal of human neonatal kidney cell-derived urokinase, alteplase has become an alternative agent in peripheral vascular applications. Because few interventionalists had prior experience with the handling and dosage of alteplase, the Advisory Panel to the Society of Cardiovascular and Interventional Radiology established practice guidelines for use in noncoronary applications. Emerging clinical experience with contemporary dosing regimens shows a safety and efficacy profile similar to urokinase but with significantly reduced drug costs. Tenecteplase (TNK) is a genetically modified version of alteplase. TNK is the only plasminogen activator available that has shown a significantly enhanced safety profile versus alteplase in AMI. Approved for a 5-second, single-bolus injection in AMI, TNK possesses a longer half-life, increased resistance to plasminogen activator inhibitor, and improved fibrin specificity compared with alteplase. Because of its enhanced safety profile, TNK may be a desirable agent for peripheral vascular applications. Initial clinical studies with TNK in acute arterial and venous disease are ongoing. This article outlines the Advisory Panel guidelines for using alteplase and highlights features of tenecteplase.
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PMID:Alteplase and tenecteplase: applications in the peripheral circulation. 1198 95

Our objective was to assess efficacy and tolerance of thrombolysis using 0.6 mg/kg of Alteplase in patients with massive pulmonary embolism defined as the association of a pulmonary embolism with shock. We retrospectively included 21 patients presenting with a massive pulmonary embolism confirmed by either scintigraphy or spiral computed tomography. Patients were treated on the basis of a standard rationale followed by thrombolysis with 0.6 mg/kg Alteplase over a period of 15 minutes. Hospital mortality, vital signs before and 2 hours after thrombolysis, and incidence of hemorrhagic events were recorded. Five patients (23.8%) died, 4 of these deaths occurred during the first 4 hours after hospital admission. Systolic and diastolic blood pressure (Sp02) were significantly improved 2 hours after the beginning of thrombolysis. Five minor hemorrhagic events occurred. This study demonstrates that for patients with pulmonary embolism and shock, a bolus treatment with Alteplase is potentially effective and well tolerated.
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PMID:Efficacy of alteplase thrombolysis for ED treatment of pulmonary embolism with shock. 1452 86

MODALITIES FOR THE DIAGNOSIS OF VENOUS THROMBOEMBOLISM: Currently rely on the confrontation of the initial clinical data and the results of D-dimer measurements, a venous Doppler, although reliable, is not a first-line exploration. REGARDING TREATMENT: Indications for thrombolysis are currently limited to massive pulmonary oedema with shock. Alteplase added to heparin improves the progression of severe embolism; it spares the patients from heavy interventions of resuscitation but the mortality remains the same. Concerning anticoagulant treatments, prolonged antivitamin K at classical doses is more effective than low doses and for limited duration if phlebitis is an idiopathic one. FOR HEART FAILURE WITH PRESERVED EJECTION FRACTION: Treatment of these heart failures, formerly know as 'diastolic' is similar to that of the acute phase of systolic heart failure. However, care should be taken with vasodilatators. CONCERNING HEART FAILURE IN GENERAL: The brain natriuretic peptide (BNP) represents a remarkable progress for the aetiological diagnosis of dyspnoea (inferior to 80 pg/ml in the case of pulmonary origin, superior to 300 pg/ml in the case of cardiac origin or severe pulmonary embolism). Regarding treatment, for acute heart failure, it is still the association of nitrates and diuretics, with oxygen therapy and eventually inotropics. Beta-blockers, which have revolutionized the treatment of chronic heart failure, must be maintained whenever possible in the case of the onset of acute pulmonary oedema. Multisite pacing is increasingly used in refractory chronic heart failure. Implantable defibrillation has become common practice. Non-invasive ventilation (Bi or C-PAP) is interesting in acute cardiogenic pulmonary oedema. THE PREVENTIVE ROLE OF N ACETYL-CYSTEINE: N acetyl cysteine reduces the incidence of nephropathies induced by the radio contrast products in patients with chronic kidney failure. Combined with hydratation, it must be proposed the day before and on the day of the procedure in any patient with diabetes or kidney failure.
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PMID:[Diagnostic and therapeutic progress. Venous thromboembolism, cardiac insufficiency and radio contrast agents]. 1522 98

(1) In the acute phase of ischaemic stroke, antiplatelet or anticoagulant treatments reduce the risk of recurrence and pulmonary embolism, but carry a risk of haemorrhagic transformation. (2) Aspirin has been tested in several placebo-controlled trials and has a positive risk-benefit balance, preventing about 5 deaths per 1000 patients with ischaemic stroke. Aspirin must be given as soon as computed tomography has ruled out intracerebral haemorrhage, unless thrombolytic treatment is planned. (3) Heparin has as many potential benefits as risks: it tends to be beneficial at low doses but harmful at high doses. Low-dose heparin therapy appears to be justified, especially for patients with emboligenic heart disease, tight carotid stenosis, or at risk of pulmonary embolism. Higher-dose heparin is only warranted for the rare patient with a high thrombotic risk. (4) Some thrombolytic drugs can reduce the frequency and severity of complications, but their use carries a high immediate risk of aggravation or death by haemorrhagic transformation. Alteplase has a somewhat positive risk-benefit balance in certain highly specific situations: for example, in some patients with persistent ischaemic stroke who are treated within three hours of onset, and without signs of severe stroke or risk factors for bleeding (high blood pressure, aspirin use). (5) Clinical trials have shown that routine use of "neuroprotective" treatments (calcium channel blockers, haemodilution, parenteral magnesium, oxygen therapy) does not reduce the risk of death or disability. (6) Arterial hypertension frequently occurs in the immediate aftermath of stroke, and then generally subsides. Few clinical trials have evaluated the use of antihypertensive drugs in this setting and there is little evidence of benefit. One trial showed that a sudden drop in blood pressure led to neurological aggravation. Antihypertensive drugs should only be used in stroke patients with severe hypertension or cardiac complications. (7) Cerebral oedema is an important cause of death after stroke: treatments (especially mannitol, mechanical ventilation and neurosurgery) have been poorly evaluated. (8) Other treatments recommended only for patients with persistent complications include oxygen therapy, antibiotics, paracetamol, insulin, and anticonvulsants. (9) A controversial meta-analysis suggested that management by a specialised multidisciplinary team reduced the mid-term risk of death and disability in comparison with management in a non specialised unit.
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PMID:Ischaemic stroke: acute-phase drug therapy. Mostly aspirin and heparin. 1610 99

Recent guidelines recommend bolus-dose alteplase for treating massive pulmonary embolism (PE). However, the safest and most effective treatment is as yet unknown. In the present study, a meta-analysis of published studies of alteplase infusion, bolus-dose alteplase and streptokinase was performed. The outcome measures were as follows: objective assessment of thrombolysis; all-cause mortality; deaths due to initial PE, major bleeding episodes and recurrent PE; and morbidity. In total, 26 studies were identified; however, only two comparative studies of alteplase infusion versus either bolus-dose alteplase or streptokinase were found. Meta-analysis revealed no significant difference between the three regimens, but was compromised by a paucity of data. Crude analysis of summated data on thrombolytic efficacy from all studies revealed that alteplase infusion was more effective than bolus-dose alteplase (relative risk (RR): 1.95; 95% confidence interval (CI): 1.19-3.2), whereas streptokinase was more effective than alteplase infusion (RR: 1.27; 95% CI: 1.09-1.47). Alteplase infusion had a lower mortality due to the initial PE than both bolus-dose alteplase and streptokinase (RR: 0.16; 95% CI: 0.05-0.59 and RR: 0.13; 95% CI: 0.04-0.46, respectively). In conclusion, this evidence suggests that the three thrombolytic agents may vary in efficacy. However, large-scale randomised controlled trials are needed to confirm these results.
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PMID:Efficacy of thrombolytic agents in the treatment of pulmonary embolism. 1626 48

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