Effects of flowing RBCs on adhesion of a circulating tumor cell in microvessels

Engineering

• Erythrocyte 100%
• Flow Velocity 100%
• Flow Rate 66%
• Fluid Viscosity 66%
• Large Deformation 33%
• Particle Dynamic 33%
• Shear Rate 33%
• Lift Force 33%
• Relative Velocity 33%
• Hydrodynamic Condition 33%
• Potential Function 33%
• Newtonian Fluid 33%

Keyphrases

• Adhesion 100%
• Circulating Tumor Cells 100%
• Microvessels 100%
• Hematocrit 23%
• Vessel Wall 15%
• Red Blood Cell Aggregation 15%
• Function-based 7%
• Large Deformation 7%
• Endothelial Cells 7%
• High-speed Flow 7%
• Blood Flow Velocity 7%
• Cell Surface 7%
• Dissipative Particle Dynamics 7%
• Lift Force 7%
• Tumor Cell Adhesion 7%
• Non-Newtonian Fluid 7%
• Relative Velocity 7%
• Vessel Size 7%
• Blood Flow Resistance 7%
• Elastic Spring 7%
• Hydrodynamic Conditions 7%
• Morse Potential Function 7%
• High Haematocrit 7%
• Blood Viscosity 7%
• Low Shear Rate 7%
• Viscosity Increase 7%

Material Science

• Tumor 100%
• Dissipative Particle Dynamics 7%
• Large Deformation 7%
• Surface (Surface Science) 7%
• Hydrodynamics 7%