Microfluidic Isotachophoresis: Theory and Applications

TL;DR

This paper provides a comprehensive, rigorous review of isotachophoresis (ITP) theory and its applications in microfluidic systems, emphasizing steady and unsteady transport, and aims to facilitate broader adoption in microfluidics.

Contribution

It offers a detailed theoretical framework for ITP, combining physicochemical principles with practical applications in microfluidic biochemical analyses, which was lacking in existing literature.

Findings

Review of ITP transport dynamics and principles

Analysis of ITP focusing in microfluidic systems

Discussion of simulation and detection tools

Abstract

Isotachophoresis (ITP) is a versatile electrophoretic technique which can be used for sample preconcentration, separation, purification, mixing, and control and acceleration of chemical reactions. Although the basic technique is nearly a century old and widely used, there has been a persistent need for an easily approachable, succinct, and rigorous review of ITP theory and analysis. This is important as interest and adoption of the technique has grown over the last two decades, especially because of its implementation into microfluidics and integration with on-chip chemical and biochemical assays. We here provide a review of ITP theory with a strong emphasis on steady and unsteady transport starting from physicochemical first principles including conservation of species, conservation of current, the approximation of charge neutrality, pH equilibrium of weak electrolytes, and so-called regulating functions governing transport dynamics. We combine these generally applicable (to all types of ITP) theoretical discussions with applications of ITP in the field of microfluidic systems, particularly on-chip biochemical analyses. Our discussion includes principles governing ITP focusing of weak and strong electrolytes, ITP dynamics in peak and plateau modes, review of simulation tools, experimental tools and detection methods, applications of ITP for on-chip separations and trace analyte manipulation, and design considerations and challenges for microfluidic ITP systems. We conclude with remarks on possible future research directions. The intent of this review is to help make ITP analysis and design principles more accessible to the scientific and engineering communities, and to provide a rigorous basis for increased adoption of ITP into microfluidics.