From Fibrinolysis to the Plasminogen–Plasmin System and Beyond: A Remarkable Growth of Knowledge, with Personal Observations on the History of Fibrinolysis

Kwaan, Hau C.

doi:10.1055/s-0034-1383545

Cited by 19 publications

(25 citation statements)

References 97 publications

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“…P194Serum uric acid is independent predictor of decreased number of circulating proangiogenic progenitor cells in asymptomatic coronary artery disease patients [ 191 ], while P733regulatory B cells from patients with coronary artery disease display numerical and functional alterations, a novel immune defect in atherosclerosis [ 192 ]. Similarly, phospholipase A2 enzymes can predict ischemic events after acute coronary syndromes [ 193 ], while plasminogen-plasmin level is considered as an important biomarker of fibrinolysis [ 194 ]. Similarly, atrial fibrosis is a risk stratifier for atrial fibrillation [ 195 ], while mitogen-activated protein kinases [ 196 ] and intercellular adhesion molecule1 gene polymorphism are good markers of coronary heart diseases [ 197 ] mainly for atherosclerosis [ 196 ].…”

Section: Biomarkers Of Coronary Artery Diseasementioning

confidence: 99%

Emerging Risk Biomarkers in Cardiovascular Diseases and Disorders

2015

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Present review article highlights various cardiovascular risk prediction biomarkers by incorporating both traditional risk factors to be used as diagnostic markers and recent technologically generated diagnostic and therapeutic markers. This paper explains traditional biomarkers such as lipid profile, glucose, and hormone level and physiological biomarkers based on measurement of levels of important biomolecules such as serum ferritin, triglyceride to HDLp (high density lipoproteins) ratio, lipophorin-cholesterol ratio, lipid-lipophorin ratio, LDL cholesterol level, HDLp and apolipoprotein levels, lipophorins and LTPs ratio, sphingolipids, Omega-3 Index, and ST2 level. In addition, immunohistochemical, oxidative stress, inflammatory, anatomical, imaging, genetic, and therapeutic biomarkers have been explained in detail with their investigational specifications. Many of these biomarkers, alone or in combination, can play important role in prediction of risks, its types, and status of morbidity. As emerging risks are found to be affiliated with minor and microlevel factors and its diagnosis at an earlier stage could find CVD, hence, there is an urgent need of new more authentic, appropriate, and reliable diagnostic and therapeutic markers to confirm disease well in time to start the clinical aid to the patients. Present review aims to discuss new emerging biomarkers that could facilitate more authentic and fast diagnosis of CVDs, HF (heart failures), and various lipid abnormalities and disorders in the future.

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Section: Biomarkers Of Coronary Artery Diseasementioning

confidence: 99%

Emerging Risk Biomarkers in Cardiovascular Diseases and Disorders

2015

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“…The plasminogen activation (PA) system is an enzymatic cascade with key regulatory functions in fibrinolysis and degradation of extracellular matrix proteins (Syrovets and Simmet, 2004 ; Castellino and Ploplis, 2005 ; Kwaan, 2014 ). Plasminogen circulates in the blood as an inactive zymogen that is converted into active plasmin by tissue-type plasminogen activator (tPA) or urokinase-type plasminogen activator (uPA).…”

Section: Fibrin Formation and Degradation In The Cnsmentioning

confidence: 99%

Breaking boundaries—coagulation and fibrinolysis at the neurovascular interface

Bardehle

Rafalski

Akassoglou

2015

Front. Cell. Neurosci.

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Blood proteins at the neurovascular unit (NVU) are emerging as important molecular determinants of communication between the brain and the immune system. Over the past two decades, roles for the plasminogen activation (PA)/plasmin system in fibrinolysis have been extended from peripheral dissolution of blood clots to the regulation of central nervous system (CNS) functions in physiology and disease. In this review, we discuss how fibrin and its proteolytic degradation affect neuroinflammatory, degenerative and repair processes. In particular, we focus on novel functions of fibrin—the final product of the coagulation cascade and the main substrate of plasmin—in the activation of immune responses and trafficking of immune cells into the brain. We also comment on the suitability of the coagulation and fibrinolytic systems as potential biomarkers and drug targets in diseases, such as multiple sclerosis (MS), Alzheimer’s disease (AD) and stroke. Studying coagulation and fibrinolysis as major molecular pathways that regulate cellular functions at the NVU has the potential to lead to the development of novel strategies for the detection and treatment of neurologic diseases.

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“…Historically, fibrinolysis was discovered through many observations including the fact that blood collected by wet-cupping (several milliliters) might be clotted and then spontaneously dissolved in 12-24 hours. 36 Whole blood certainly possesses potency of lysing clot per se , and this potency originates from the natural blood thrombolytic agents. Thus, it is not of surprise that the control samples with zero concentration of active tPA exhibit clot lysis to some extents in all methods developed for thrombolytic activity measurement, including the developed SATA assay and the digested clot method.…”

Section: Discussionmentioning

confidence: 99%

Spectrophotometric analysis of thrombolytic activity: SATA assay

Zamanlu¹,

Eskandani²,

Mohammadian³

et al. 2017

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Introduction: Measurement of thrombolytic activity is crucial for research and development of novel thrombolytics. It is a key factor in the assessment of the effectiveness of conventionally used thrombolytic therapies in the clinic. Previous methods used for the assessment of thrombolytic activity are often associated with some drawbacks such as being costly, time-consuming, complex with low accuracy. Here, we introduce a simple, economic, relatively accurate and fast method of spectrophotometric analysis of thrombolytic activity (SATA) assay, standardized by tissue plasminogen activator (tPA), which can quantitatively measure in vitro thrombolytic activity. Methods: Blood clots were formed, uniformly, by mixing citrated whole blood with partial thromboplastin time (PTT) reagent, together with calcium chloride. Then, designated concentrations of tPA were added to the samples, and the released red blood cells from each clot were quantified using spectrophotometry (λmax=405nm) as an indicator of thrombolytic activity. The accuracy of the method was tested by assessment of dose-responsibility against R2 value obtained by linear equation and measurement of the limit of detection (LOD) and limit of quantification (LOQ). The SATA assay was validated in comparison with some currently used techniques. Results: A linear relationship was obtained between different concentrations of tPA versus the spectrophotometric absorbance of the related dilutions of lysed clots, at λmax=405nm. Calculated R2 values were greater than 0.9; with LOD of 0.90 µg/mL of tPA (436.50IU) and LOQ of 2.99 µg/mL of tPA (1450.15IU). Conclusion: Conclusively, the SATA assay is a very simple quantitative method with repeatable and reproducible results for estimating the potency of an unknown thrombolytic agent, and calculating the activity as delicate as 1 µg/mL of tPA (485 IU/mL of thrombolytic dose).

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From Fibrinolysis to the Plasminogen–Plasmin System and Beyond: A Remarkable Growth of Knowledge, with Personal Observations on the History of Fibrinolysis

Cited by 19 publications

References 97 publications

Emerging Risk Biomarkers in Cardiovascular Diseases and Disorders

Emerging Risk Biomarkers in Cardiovascular Diseases and Disorders

Breaking boundaries—coagulation and fibrinolysis at the neurovascular interface

Spectrophotometric analysis of thrombolytic activity: SATA assay

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