119 research outputs found
COVIDâ19 pandemic perspectives: A scientific silver lining?
Accounts of the numerous negative effects caused by COVID-19 are pervasive, but few perspectives have identified any positive impacts of this massive societal shift. This forum examines potentially positive changes that have occurred within the scientific community amid the chaotic pandemic. Among these positives are the formation of virtual supergroups and an interdisciplinary brain trust. In forcing scientists away from their lab benches, COVID-19 has created time and space for more conversations about science and experimental design. Being away from the lab in this time of social unrest has also given scientists time to directly address institutional racism and its suppression of diversity in science. Although COVID-19 has been an unforeseen disaster of epic proportions, some of the resulting changes in our scientific community should remain in place after the pandemic is over. By leveraging these small wins, we will undoubtedly return to our laboratories stronger, smarter, and more efficient
New findings on venous thrombogenesis
Venous thrombosis (VT) is the third most common cause of cardiovascular death worldwide. Complications from VT and pulmonary embolism are the leading cause of lost disability-adjusted life years. Risks include genetic (e.g., non-O blood group, activated protein C resistance, hyperprothrombinemia) and acquired (e.g., age, surgery, cancer, pregnancy, immobilisation, female hormone use) factors. Pathophysiologic mechanisms that promote VT are incompletely understood, but involve abnormalities in blood coagulability, vessel function, and flow (so-called Virchowâs Triad). Epidemiologic studies of humans, animal models, and biochemical and biophysical investigations have revealed contributions from extrinsic, intrinsic, and common pathways of coagulation, endothelial cells, leukocytes, red blood cells, platelets, cell-derived microvesicles, stasis-induced changes in vascular cells, and blood rheology. Knowledge of these mechanisms may yield new therapeutic targets. Characterisation of mechanisms that mediate VT formation and stability, particularly in aging, are needed to advance understanding of VT
Newly-Recognized Roles of Factor XIII in Thrombosis
Arterial and venous thrombosis are major contributors to coagulation-associated morbidity and mortality. Greater understanding of mechanisms leading to thrombus formation and stability is expected to lead to improved treatment strategies. Factor XIII (FXIII) is a transglutaminase found in plasma and platelets. During thrombosis, activated FXIII crosslinks fibrin and promotes thrombus stability. Recent studies have provided new information about FXIII activity during coagulation and its effects on clot composition and function. These findings reveal newly-recognized roles for FXIII in thrombosis. Herein, we review published literature on FXIII biology and effects on fibrin structure and stability, epidemiologic data associating FXIII with thrombosis, and evidence from animal models indicating FXIII has an essential role in determining thrombus stability, composition, and size
Influence of Cellular and Plasma Procoagulant Activity on the Fibrin Network
At the nexus of cellular and plasma procoagulant activities lies fibrin, which is necessary to provide a clot's structural support. Abnormalities in fibrin network formation or function can result in either bleeding or thrombotic complications. Understanding relationships between procoagulant activity and normal fibrin formation, as well as pathophysiologic mechanisms leading to abnormal fibrin deposition, is essential for the continued development of hemostatic and antithrombotic therapies
A portable blood plasma clot micro-elastometry device based on resonant acoustic spectroscopy
Abnormal blood clot stiffness is an important indicator of coagulation disorders arising from a variety of cardiovascular diseases and drug treatments. Here, we present a portable instrument for elastometry of microliter volume blood samples based upon the principle of resonant acoustic spectroscopy, where a sample of well-defined dimensions exhibits a fundamental longitudinal resonance mode proportional to the square root of the Youngâs modulus. In contrast to commercial thromboelastography, the resonant acoustic method offers improved repeatability and accuracy due to the high signal-to-noise ratio of the resonant vibration. We review the measurement principles and the design of a magnetically actuated microbead force transducer applying between 23 pN and 6.7 nN, providing a wide dynamic range of elastic moduli (3 Paâ27 kPa) appropriate for measurement of clot elastic modulus (CEM). An automated and portable device, the CEMport, is introduced and implemented using a 2 nm resolution displacement sensor with demonstrated accuracy and precision of 3% and 2%, respectively, of CEM in biogels. Importantly, the small strains (<0.13%) and low strain rates (<1/s) employed by the CEMport maintain a linear stress-to-strain relationship which provides a perturbative measurement of the Youngâs modulus. Measurements of blood plasma CEM versus heparin concentration show that CEMport is sensitive to heparin levels below 0.050 U/ml, which suggests future applications in sensing heparin levels of post-surgical cardiopulmonary bypass patients. The portability, high accuracy, and high precision of this device enable new clinical and animal studies for associating CEM with blood coagulation disorders, potentially leading to improved diagnostics and therapeutic monitoring
Thrombin generation, fibrin clot formation and hemostasis
Hemostatic clot formation entails thrombin-mediated cleavage of fibrinogen to fibrin. Previous in vitro studies have shown that the thrombin concentration present during clot formation dictates the ultimate fibrin structure. In most prior studies of fibrin structure, clotting was initiated by adding thrombin to a solution of fibrinogen; however, clot formation in vivo occurs in an environment in which the concentration of free thrombin changes over the reaction course. These changes depend on local cellular properties and available concentrations of pro- and anti-coagulants. Recent studies suggest that abnormal thrombin generation patterns produce abnormally structured clots associated with an increased risk of bleeding or thrombosis. Further studies of fibrin formation during in situ thrombin generation are needed to understand fibrin clot formation in vivo
Tissue factor and factor VIIa â Hemostasis and beyond
Initiation of the coagulation cascade via exposure of active tissue factor (TF) to blood and formation of the factor VIIa/TF complex is essential for hemostasis and is an initial procoagulant signal in thrombosis. As of early 2012, over 20,000 articles listed on PubMed describe advances in the understanding of TF biology in the settings of hemostasis and thrombosis, as well as in signaling events in cancer, sickle cell anemia, hyperlipidemia, and a broad spectrum of inflammatory disorders. It is both inspiring and humbling, then, to consider not only what has been learned about TF regulation, but also the number of questions still remaining about its role in physiology. This supplement reviews both well-accepted and currently-controversial topics in coagulation and factor VIIa/TF biology, with particular foci on non-hemostatic roles of TF, innovative approaches for the treatment of hemophilia, and novel in vivo models of bleeding and thrombosis
Kinetic model facilitates analysis of fibrin generation and its modulation by clotting factors: implications for hemostasis-enhancing therapies
We developed a computational model that accounts for essential kinetic features of thrombin generation, fibrin formation, and fibrinolysis in diverse in vitro systems. We applied it to characterize strategies to improve hemostasis
Human Factor IX Binds to Specific Sites on the Collagenous Domain of Collagen IV
The primary region of factor IX that mediates binding to bovine aortic endothelial cells resides in residues 3-11 of the N-terminal region known as the Gla domain. Recently, it was proposed that the observed binding to endothelial cells is actually a measure of the interaction between factor IX and collagen IV (Cheung, W. F., van den Born, J., Kuhn, K., Kjellen, L., Hudson, B. G., and Stafford, D. W. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 11068-11073). To confirm that factor IX binds to collagen IV and to examine the specificity of this interaction, we used scanning force microscopy to examine factor IX binding to collagen IV. We imaged collagen IV in the presence and the absence of factor IX and observed specific interactions between factor IX and collagen IV. Our results demonstrate that factor IX binds to collagen IV at specific sites in the collagenous domain approximately 98 and approximately 50 nm from the C-terminal pepsin-cleaved end
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