Microfluidic systems for cell separation and analysis have attracted increasing research
activity over the past decades. In particular, the prospect of integrating all steps from sample …

Separation of microparticles and cells serves a critical step in many applications such as in
biological analyses, food production, chemical processing, and medical diagnostics. Sorting …

Efficient platforms for cell isolation and analysis play an important role in applied and
fundamental biomedical studies. As cells commonly have a size of around 10 microns …

Rapid progress in the field of microfluidics coupled with increase in demand for cell
separation techniques for biomedical diagnostics has gained significant attention among …

It is an old Chinese saying that “proper tools for proper works.” To crack the mystery inside
cells, special tool is demanded. At this moment, microfluidic chip represents an efficient and …

Microfluidic continuous cell separation based on hydrodynamic interaction in a microfluidic
channel has attracted attention because of its robustness, high throughput and cell viability …

Introduction 3. Principle and strategies for microfluidic cell sorting 3.1. Active multi-channel
switch 3.2. Field flow fractionation 3.3. Local nonuniform field flow fractionation 3.4 …

Manipulating the physical location of cells is useful both to organize cells in vitro and to
separate cells during screening. The quest to manipulate cells on length scales …

Cell mechanics is a highly interdisciplinary research area which has made significant
progress over the last decade, particularly in the study of human diseases. In diseases such …

Microfluidics, which is classified as either active or passive, is capable of separating cells of
interest from a complex and heterogeneous sample. Active methods utilise external fields …