Add to ORKGInitiation of blood coagulation by tissue factor (TF) is a robust, highly regulated process. Both the spatial distribution of TF and the geometry of the vasculature may play important roles in regulating coagulation. As this review describes, microfluidic systems provide a unique opportunity for investigating the spatiotemporal dynamics of blood coagulation in vitro. Microfluidic systems with surfaces of phospholipid bilayers patterned with TF have been used to demonstrate experimentally the threshold responses of initiation of coagulation to the size and shape of surfaces presenting TF. These systems have also been used to demonstrate experimentally that propagation of coagulation is regulated by the shear rate of blood flow in microcapill...
Biological and physical factors interact to modulate blood response in a wounded vessel, resulting i...
Microarraying allows the spatial and compositional control of surfaces, typically for the purpose of...
The formation of blood clots involves complex interactions between endothelial cells, their underlyi...
Initiation of blood coagulation by tissue factor (TF) is a robust, highly regulated process. Both th...
To date, microfluidic techniques provide the most physiologically relevant environment for the study...
Upon vessel injury, a series of events are orchestrated to promote an optimal hemostatic response th...
Upon vessel injury, a series of events are orchestrated to promote an optimal hemostatic response th...
Objective—Blood flow is considered one of the important parameters that contribute to venous thrombo...
This paper provides an overview of the various types of microfluidic devices that are employed to st...
Current in vitro or ex vivo models of hemostasis and thrombosis fail to recapitulate the hemodynamic...
Current in vitro or ex vivo models of hemostasis and thrombosis fail to recapitulate the hemodynamic...
This paper describes microfluidic experiments with human blood plasma and numerical simulations to d...
Microfluidic devices provide a powerful platform for the study of blood biology due to their control...
Microfluidic devices provide a powerful platform for the study of blood biology due to their control...
AbstractBlood coagulation in vivo is a spatially nonuniform, multistage process: coagulation factors...
Biological and physical factors interact to modulate blood response in a wounded vessel, resulting i...
Microarraying allows the spatial and compositional control of surfaces, typically for the purpose of...
The formation of blood clots involves complex interactions between endothelial cells, their underlyi...
Initiation of blood coagulation by tissue factor (TF) is a robust, highly regulated process. Both th...
To date, microfluidic techniques provide the most physiologically relevant environment for the study...
Upon vessel injury, a series of events are orchestrated to promote an optimal hemostatic response th...
Upon vessel injury, a series of events are orchestrated to promote an optimal hemostatic response th...
Objective—Blood flow is considered one of the important parameters that contribute to venous thrombo...
This paper provides an overview of the various types of microfluidic devices that are employed to st...
Current in vitro or ex vivo models of hemostasis and thrombosis fail to recapitulate the hemodynamic...
Current in vitro or ex vivo models of hemostasis and thrombosis fail to recapitulate the hemodynamic...
This paper describes microfluidic experiments with human blood plasma and numerical simulations to d...
Microfluidic devices provide a powerful platform for the study of blood biology due to their control...
Microfluidic devices provide a powerful platform for the study of blood biology due to their control...
AbstractBlood coagulation in vivo is a spatially nonuniform, multistage process: coagulation factors...
Biological and physical factors interact to modulate blood response in a wounded vessel, resulting i...
Microarraying allows the spatial and compositional control of surfaces, typically for the purpose of...
The formation of blood clots involves complex interactions between endothelial cells, their underlyi...