EC:3.4.21.73 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.73 (urokinase-type plasminogen activator)
10,685 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

With technological advances in equipment and increased experience of operators, the success rates of percutaneous transluminal coronary angioplasty (PTCA) now exceed 90%. However, acute periprocural occlusion continues to complicate approximately 6% of all procedures, and many of these occlusions are due to intracoronary (IC) thrombus. Patients at highest risk for this complication include those with acute ischemic syndromes or with angiographically apparent thrombus. These individuals may be candidates for the use of prolonged heparin infusions prior to dilatation, intracoronary thrombolytic therapy, or monoclonal antibody directed against the platelet glycoprotein IIb/IIIa receptor. All patients undergoing PTCA should receive adequate antiplatelet therapy, including aspirin, and heparin with dosing monitored by activated clotting times (ACT). In addition, some recommend the use of ionic contrast material. When IC thrombus accumulates following intervention, initial therapy should include IC nitroglycerin followed by a combination of redilatation and IC urokinase infusion. Prolonged balloon inflations may be useful, particularly with the use of autoperfusion catheters. Platelet glycoprotein IIb/IIIa receptor antagonists may prove to be beneficial in this situation as well. If the patient's clinical status deteriorates in spite of these measures, emergency coronary artery bypass graft surgery may be required.
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PMID:Management of intracoronary thrombosis complicating percutaneous transluminal coronary angioplasty. 881 33

Megakaryocytopoiesis is governed in the bone marrow microenvironment by cellular interactions that include various adhesion receptor systems and pericellular proteolysis for proper regulation of cell motility and differentiation. In order to define the role of cell surface molecules required for these processes, we searched for protease receptors on these cells. In an in vitro system utilizing different cell lines of the megakaryoblastic lineage (MEG-01, Dami), low level surface expression of the urokinase (uPA) receptor was noted. Following stimulation with phorbolester (PMA), a 3-6 fold higher expression of uPA receptor over a period of up to 5 days could be observed by fluorescent activated cell-sorting as well as by direct ligand-binding of amino-terminal fragment of uPA or vitronectin. Together with elevated expression of alpha IIb beta 3-integrin (glycoprotein IIb/IIIa complex), double immuno-fluorescence staining of stimulated cells confirmed the increased cell surface localization of uPA receptor. Semi-quantitative RT-PCR, ligand blot analysis and measurement of cell-bound proteolytic activity revealed a differentiation-dependent upregulation of the uPA receptor expression in megakaryoblastic cell lines as in monocytic cells. Due to its glycolipid anchorage, incubation with phosphatidylinositol-specific phospholipase C reduced uPA receptor-mediated ligand binding by about 60%, uPA receptor mRNA was expressed in cultured megakaryocytes derived from bone marrow, whereas no uPA receptor mRNA was detectable in platelets. These results indicate a differentiation-dependent increase in the expression of uPA receptor in megakaryoblastic cells. The characteristics of surface expression and functionality of the receptor on megakaryocytic cells may influence their maturation by regulating cellular communication in the bone marrow micro-environment.
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PMID:The urokinase-receptor (CD87) is expressed in cells of the megakaryoblastic lineage. 906 8

Pharmacological therapy for acute nonhaemorrhagic stroke has become a reality over the last 5 years. Mechanistically, both thrombolytic (tissue plasminogen activator and urokinase) and antiplatelet (aspirin) monotherapy have demonstrated efficacy. However, unintended actions limit the extent of clinical improvement in each circumstance. For example, in addition to excess bleeding, tissue plasminogen activator therapy has been associated with complement activation, neuronal toxicity and laminin degradation, while aspirin may reduce nitric oxide synthase activity and cerebral blood flow. Attention is now directed toward improving the therapeutic index for each class of agents. Generally, while thrombolytic therapy is focused on developing agents with greater fibrin specificity and safety (that is, a reduction in intracranial haemorrhage rate), the development of antiplatelet agents is primarily focused on achieving greater potency. The latter is being investigated by combining agents with different mechanisms (aspirin and dipyridamole, aspirin and clopidogrel) as well as agents designed to block the glycoprotein IIb/IIIa receptor, the final common pathway for platelet aggregation. Thus, combination therapy using both thrombolytic and antiplatelet agents will further attempt to improve the therapeutic index by increasing potency and improving the safety profile. Anecdotal case studies support the merits of this approach and are consistent with the data reported for myocardial ischaemia and interventional strategies. It is anticipated that drug therapy directed at both thrombolytic and antiplatelet targets will ultimately result in a widened therapeutic window that will allow acute stroke therapy to be administrated to a much greater number of patients than is currently possible.
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PMID:Combining antiplatelet and thrombolytic therapies for stroke. 1193 43

Methylene 3, 4 dioxymethamphetamine (MDMA) has been gaining popularity as a recreational drug over the past few decades around the globe. Although once thought to be safer than its mother compound, amphetamine, several life-threatening adverse reactions have been reported. Among the cardiovascular toxicities documented, MDMA commonly causes various forms of arrhythmia and heart failure. However, MDMA-induced acute myocardial infarction is rarely reported. We report a case of acute myocardial infarction in a young man shortly after taking MDMA. Massive thrombosis over the right coronary artery was demonstrated by means of emergency angiography. After treatment with intravenous glycoprotein IIb/IIIa inhibitor and intracoronary urokinase infusion, the coronary artery was shown to be patent without any apparent stenotic lesions. The mechanism of MDMA-induced acute myocardial infarction was discussed.
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PMID:Methylene 3, 4 dioxymethamphetamine-induced acute myocardial infarction. 1552 53

Acute limb ischemia is still the most frequent cause of major limb loss. Timely and fast revascularization is the key for limb salvage and patient survival. Large randomized trials showed equivalency of surgical and endovascular revascularization by means of local lysis with urokinase (TOPAS, STILE). New lytic agents and their modified application such as via a pulse spray catheter or combined with an ultrasound catheter and the combination with glycoprotein IIb/IIIa receptor antagonists have increased the efficacy and speed of thrombolysis. Recently, mechanical thrombectomy devices have become more widespread because intervention time and bleeding complications can be reduced. This review article summarizes the clinical presentation of and the treatment options for acute arterial occlusive disease caused either by embolism or local thrombosis.
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PMID:Treatment of acute limb ischemia with focus on endovascular techniques. 1958

With thrombolysis, intravenous alteplase (0.9 mg/kg body weight, maximum 90 mg), with 10% of the dose given as a bolus followed by a 60-minute infusion, is recommended within 4.5 hours of onset of ischemic stroke. When indicated, intravenous thrombolysis must be initiated as soon as possible. It is possible to use intravenous alteplase in patients with seizures at stroke onset, if the neurological deficit is related to acute cerebral ischemia. Intravenous alteplase can be discussed for use on a case-by-case basis, according to risk of bleeding, in selected patients under 18 years and over 80 years of age, although for the current European recommendations this would be an off-label use. In hospitals with a stroke unit, intravenous thrombolysis is prescribed by a neurologist (current French labelling) or a physician having the French certification for neurovascular diseases (outside the current French labelling). The patient must be monitored in the stroke unit or in case of multiple organ failure in an intensive and critical care unit. In hospitals without a stroke unit, thrombolysis must be decided by the neurologist from the corresponding stroke unit via telemedicine. It is recommended to perform brain imaging 24 hours after thromboysis. Intra-arterial thrombolysis can be contemplated on a case-by-case basis after multidisciplinary discussion within a 6-hour time window for patients with acute middle cerebral artery or carotid occlusions, and within a larger time window for patients with basilar artery occlusion, because of their very poor spontaneous prognosis. Mechanical thrombectomy can also be contemplated in the same situations. With antiplatelet agents, it is recommended that patients receive aspirin (160 mg-325 mg) within 48 hours of ischemic stroke onset. When thrombolysis is performed or contemplated, it is recommended to delay the initiation of aspirin or other antithrombotic drugs for 24 hours. The use of antiplatelet agents that inhibit the glycoprotein IIb/IIIa receptor is not recommended. Urgent anticoagulation using heparin, low-molecular-weight heparins or danaparoid with the goal to treat ischemic stroke patients is not recommended. Secondary prevention by anticoagulation can be used, immediately or within the first days, after minor ischemic stroke or TIA in patients with a high risk for cardioembolism, if uncontrolled hypertension is absent. In patients with large infarcts and a high risk for cardioembolism, the timing for initiating anticoagulation must be decided on a case-by-case basis. In patients with anticoagulation who had an ischemic stroke, the decision to temporarily stop or maintain anticoagulation must be made on a case-by-case basis, depending on thromboembolic risk, level of anticoagulation at stroke onset and estimated risk of hemorrhagic transformation. It is not recommended to use neuroprotective agents in ischemic stroke patients. Patients with cerebral venous thrombosis must be treated with therapeutic doses of heparin, even in case of concomitant intracranial hemorrhage related to cerebral venous thrombosis. If the patient's status worsens despite adequate anticoagulation, thrombolysis may be used in selected cases. The optimal administration route (local or intravenous), thrombolytic agent (urokinase or alteplase) and dose are unknown. There is currently no recommendation with regard to local thrombolytic therapy in patients with dural sinus thrombosis. Urgent blood transfusions are recommended to reduce hemoglobin S to <30% in patients with sickle cell disease and acute ischemic stroke.
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PMID:[Treatment of arterial and venous brain ischemia. Experts' recommendations: stroke management in the intensive care unit]. 2264 7

Background and Purpose: Endovascular treatment (EVT) for acute vertebrobasilar intracranial atherosclerosis-related large vessel occlusion (ICAS-LVO) and its outcomes are not well known. We aimed to evaluate endovascular and clinical outcomes of vertebrobasilar ICAS-LVO patients who underwent EVT. Methods: Consecutive acute stroke patients who underwent EVT for vertebrobasilar LVO were retrospectively reviewed. Patients were assigned to the ICAS (+) or the ICAS (-) group based on angiographical findings. Procedural details and clinical outcomes were compared between the ICAS (+) and ICAS (-) groups. Results: This study included 77 patients with acute vertebrobasilar LVO who underwent EVT. Among the study subjects, 24 (31.2%) had an ICAS-LVO. Recanalization was achieved in 19 patients in the ICAS (+) group (79.2%), which was comparable with the ICAS (-) group (84.9%; p = 0.529). However, recanalization using conventional endovascular modalities (stent retriever thrombectomy, contact aspiration thrombectomy, or intra-arterial urokinase infusion) was less successful in the ICAS (+) group (36.8%) than the ICAS (-) group (100.0%; p < 0.001). All the remaining patients in the ICAS (+) group required specific rescue treatments appropriate for ICAS, including balloon angioplasty, stenting, or intra-arterial glycoprotein IIb/IIIa inhibitor infusion to obtain a successful recanalization. Procedural time was not significantly longer in the ICAS (+) group. The rates of favorable outcomes (37.5% vs. 41.5%; p = 0.740), death, and symptomatic intracerebral hemorrhage were not significantly different between the groups. Conclusion: ICAS-LVO was common in patients who underwent EVT for acute vertebrobasilar LVO. Although conventional modalities were often ineffective for vertebrobasilar ICAS-LVO, a comparable recanalization rate could be obtained with ICAS-specific modalities. Recanalization rate and procedural time were comparable, and clinical outcomes did not differ between patients with or without ICAS-LVO.
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PMID:Endovascular and Clinical Outcomes of Vertebrobasilar Intracranial Atherosclerosis-Related Large Vessel Occlusion. 3094 Oct 84