Stroke Genetics Network (SiGN) study: design and rationale for a genome-wide association study of ischemic stroke subtypes.

BACKGROUND AND PURPOSE: Meta-analyses of extant genome-wide data illustrate the need to focus on subtypes of ischemic stroke for gene discovery. The National Institute of Neurological Disorders and Stroke SiGN (Stroke Genetics Network) contributes substantially to meta-analyses that focus on specific subtypes of stroke. METHODS: The National Institute of Neurological Disorders and Stroke SiGN includes ischemic stroke cases from 24 genetic research centers: 13 from the United States and 11 from Europe. Investigators harmonize ischemic stroke phenotyping using the Web-based causative classification of stroke system, with data entered by trained and certified adjudicators at participating genetic research centers. Through the Center for Inherited Diseases Research, the Network plans to genotype 10,296 carefully phenotyped stroke cases using genome-wide single nucleotide polymorphism arrays and adds to these another 4253 previously genotyped cases, for a total of 14,549 cases. To maximize power for subtype analyses, the study allocates genotyping resources almost exclusively to cases. Publicly available studies provide most of the control genotypes. Center for Inherited Diseases Research-generated genotypes and corresponding phenotypes will be shared with the scientific community through the US National Center for Biotechnology Information database of Genotypes and Phenotypes, and brain MRI studies will be centrally archived. CONCLUSIONS: The Stroke Genetics Network, with its emphasis on careful and standardized phenotyping of ischemic stroke and stroke subtypes, provides an unprecedented opportunity to uncover genetic determinants of ischemic stroke.

Thrombolytics in acute ischaemic stroke: historical perspective and future opportunities.

The discovery of thrombolytic agents goes back to the 1930s, when it was shown that substances derived from bacteria (streptokinase, staphylokinase), tissue (fibrinokinase), urine (urokinase) or bat saliva could activate the fibrinolytic system. The potential to treat arterial thrombosis with plasmin was recognized, but it was not until 1958 that its first use in acute ischaemic stroke (AIS) was described. However, since computer tomography (CT) was not available until the mid 1970s, optimal selection of patients was not possible. Early studies with streptokinase in AIS showed an increased risk of intracranial haemorrhage and lack of efficacy, which was associated with low fibrin specificity. The search for new agents with a better risk-benefit profile continued until 1979 when tissue plasminogen activator (t-PA) was discovered. In 1983 it became possible to produce recombinant t-PA (rt-PA) by expression of a cloned gene which enabled clinical trials to be started, mainly for coronary thrombolysis. In 1995, the National Institute of Neurological Disorders and Stroke study showed that rt-PA was an effective treatment for AIS, nowadays for use up to 4.5 h after onset. However, rt-PA still often fails in achieving rapid reperfusion, has relatively low recanalization rates and is associated with an increased bleeding risk. Several attempts have been made to develop thrombolytics with a better risk-benefit profile than rt-PA, but no real impact on clinical practice was observed. In 1994, it was shown that tenecteplase (rt-PA-TNK) had a higher fibrin specificity than rt-PA, but its clinical use in AIS was described only in 2005. The recently reported results of a small phase 2B trial showed significantly better reperfusion and clinical outcome with rt-PA-TNK compared to rt-PA; patients were selected by CT perfusion and angiography, and treated within 6 h after stroke onset. Currently, a phase 3 trial of rt-PA-TNK versus rt-PA is being planned in patients at an onset up to 4.5 h. The most fibrin-specific recombinant plasminogen activator desmoteplase originates from 1991, and its clinical development in AIS started in 2005. Desmoteplase is in phase 3 development for the treatment of AIS between 3 and 9 h after onset in AIS patients presenting with occlusion or high-grade stenosis.

Randomized, placebo-controlled, dose-ranging clinical trial of intravenous microplasmin in patients with acute ischemic stroke.

BACKGROUND AND PURPOSE: Microplasmin is a recombinant truncated form of human plasmin. It has demonstrated efficacy in experimental animal models of stroke and tolerability in healthy volunteers. We tested the tolerability of microplasmin in patients with acute ischemic stroke. METHODS: In a multicenter, double-blind, randomized, placebo-controlled Phase II trial, 40 patients with ischemic stroke were treated with either placebo or active drug between 3 and 12 hours after symptom onset in a dose-finding design. Ten patients received placebo, 6 patients received a total dose of 2 mg/kg, 12 patients received a total dose of 3 mg/kg, and 12 patients received a total dose of 4 mg/kg. We studied the pharmacodynamics of microplasmin and its effect on the clinical and hemodynamic parameters of the patients. MRI was used as a surrogate marker and matrix metalloproteinases serum concentrations were used as markers of neurovascular integrity. The study was underpowered to detect clinical efficacy. RESULTS: Microplasmin induced reversible effects on markers of systemic thrombolysis and neutralized alpha(2)-antiplasmin by up to 80%. It was well tolerated with one of 30 treated patients developing a fatal symptomatic intracerebral hemorrhage. No significant effect on reperfusion rate or on clinical outcome was observed. Matrix metalloproteinase-2 levels were reduced in microplasmin-treated patients. CONCLUSIONS: Microplasmin was well tolerated and achieved neutralization of alpha(2)-antiplasmin. Further studies are warranted to determine whether microplasmin is an effective therapeutic agent for ischemic stroke.