Continuous Magnetophoretic Separation of Blood Cells from Plasma at the Microscale

TL;DR

This paper introduces a microfluidic system that uses magnetic forces to continuously separate different blood cells from plasma, enabling efficient blood component separation at the microscale.

Contribution

The study presents a novel microfluidic device with integrated magnetic elements for continuous blood cell separation based on magnetic properties.

Findings

Successfully separates WBC-rich plasma, deoxygenated RBC-rich plasma, and cell-depleted plasma.

Mathematical model accurately predicts blood cell trajectories in the microsystem.

Demonstrates potential for blood analysis and medical diagnostics.

Abstract

We present a method for the direct and continuous separation of red and white blood cells from plasma at the microscale. The method is implemented in a microfluidic system with magnetic functionality. The fluidic structure within the microsystem consists of an inlet and a single microfluidic channel with multiple outlets. The magnetic functionality is provided by an array of integrated soft-magnetic elements that are embedded transverse and adjacent to the microchannel. The elements are magnetized using an external field, and once magnetized they produce a magnetic force on blood cells as they flow through the microchannel. In whole blood, white blood cells (WBCs) behave as diamagnetic microparticles, while red blood cells (RBCs) exhibit diamagnetic or paramagnetic behavior depending on the oxygenation of their hemoglobin. We study the motion of blood cells through the microchannel using a mathematical model that takes into account the magnetic, fluidic and gravitational forces on the cells. We use the model to study blood cell separation, and our analysis indicates that the microsystem is capable of separating WBC-rich plasma, deoxygenated RBC-rich plasma and cell-depleted plasma into respective outlets.