This paper analyzes the applicability of Eringen’s Generalized Continuum Theories as a model for human blood in the microcirculation. The applied theory considers a fluid with a fully deformable substructure, namely a micromorphic fluid. This analysis is motivated by the fact that blood itself can be considered a suspension of deformable particles, i.e., red blood cells (RBCs), suspended in a Newtonian fluid, i.e., blood plasma. As a consequence, non-Newtonian phenomena such as shear-thinning are observed in blood. To test the micromorphic fluid as a model for blood, the solution for the velocity and the motion of substructure is determined for a cylindrical pipe flow and compared to experimental results of blood flow through narrow glass c...
Over the years, various experimental methods have been applied in an effort to understand the blood...
In this paper, we study the blood flow through blood vessels of various radii (including the case of...
Program year: 1975/1976Digitized from print original stored in HDRSince blood is the transport mediu...
This paper was presented at the 2nd Micro and Nano Flows Conference (MNF2009), which was held at Bru...
In spite of the development of cardio-vascular prosthetic devices, prosthetic heart valves, pulsatil...
Surface tension driven microfluidic flows offer low-cost solutions for blood diagnostics due to the ...
The non-Newtonian nature of blood arises from the presence of suspended formed elements which are th...
This paper was presented at the 3rd Micro and Nano Flows Conference (MNF2011), which was held at the...
Abstract. The viscoelastic properties of blood are dominated by microstructures formed by red cells....
AbstractHistorically, predicting macroscopic blood flow characteristics such as viscosity has been a...
The earlier constitutive model of Fang & Owens (Biorheology, vol. 43, 2006, p. 637) and Owens (J. No...
We introduce a new framework to study the non-Newtonian behaviour of fluids at the microscale based ...
Author manuscript; available in PMC 2012 March 1.We investigate the biophysical characteristics of h...
The flow of blood is a non-Newtonian phenomenon, best described by Bingham fluids. We have given the...
The main function of the microvasculature is transport of materials. Water and solutes are carried b...
Over the years, various experimental methods have been applied in an effort to understand the blood...
In this paper, we study the blood flow through blood vessels of various radii (including the case of...
Program year: 1975/1976Digitized from print original stored in HDRSince blood is the transport mediu...
This paper was presented at the 2nd Micro and Nano Flows Conference (MNF2009), which was held at Bru...
In spite of the development of cardio-vascular prosthetic devices, prosthetic heart valves, pulsatil...
Surface tension driven microfluidic flows offer low-cost solutions for blood diagnostics due to the ...
The non-Newtonian nature of blood arises from the presence of suspended formed elements which are th...
This paper was presented at the 3rd Micro and Nano Flows Conference (MNF2011), which was held at the...
Abstract. The viscoelastic properties of blood are dominated by microstructures formed by red cells....
AbstractHistorically, predicting macroscopic blood flow characteristics such as viscosity has been a...
The earlier constitutive model of Fang & Owens (Biorheology, vol. 43, 2006, p. 637) and Owens (J. No...
We introduce a new framework to study the non-Newtonian behaviour of fluids at the microscale based ...
Author manuscript; available in PMC 2012 March 1.We investigate the biophysical characteristics of h...
The flow of blood is a non-Newtonian phenomenon, best described by Bingham fluids. We have given the...
The main function of the microvasculature is transport of materials. Water and solutes are carried b...
Over the years, various experimental methods have been applied in an effort to understand the blood...
In this paper, we study the blood flow through blood vessels of various radii (including the case of...
Program year: 1975/1976Digitized from print original stored in HDRSince blood is the transport mediu...