Synergies between Hyperpolarized NMR and Microfluidics: A Review

TL;DR

This review explores how recent advances in hyperpolarized NMR and microfluidics have synergistically enhanced applications in biomedical research, diagnostics, and chemical analysis by combining high sensitivity with micro-scale integration.

Contribution

It provides a comprehensive overview of the emerging synergy between hyperpolarized NMR and microfluidic technologies, highlighting recent developments and future potential.

Findings

Hyperpolarization can enhance NMR signals by up to 5 orders of magnitude.

Microfluidic integration improves the efficiency of hyperpolarization processes.

Synergistic use of both fields expands applications in biomedical and chemical analysis.

Abstract

Hyperpolarized nuclear magnetic resonance and lab-on-a-chip microfluidics are two dynamic, but until recently quite distinct, fields of research. Recent developments in both areas increased their synergistic overlap. By microfluidic integration, many complex experimental steps can be brought together onto a single platform. Microfluidic devices are therefore increasingly finding applications in medical diagnostics, forensic analysis, and biomedical research. In particular, they provide novel and powerful ways to culture cells, cell aggregates, and even functional models of entire organs. Nuclear magnetic resonance is a non-invasive, high-resolution spectroscopic technique which allows real-time process monitoring with chemical specificity. It is ideally suited for observing metabolic and other biological and chemical processes in microfluidic systems. However, its intrinsically low sensitivity has limited its application. Recent advances in nuclear hyperpolarization techniques may change this: under special circumstances, it is possible to enhance NMR signals by up to 5 orders of magnitude, which dramatically extends the utility of NMR in the context of microfluidic systems. At the same time, hyperpolarization requires complex chemical and/or physical manipulations, which in turn may benefit from microfluidic implementation. In fact, many hyperpolarization methodologies rely on processes that are more efficient at the micro-scale, such as molecular diffusion, penetration electromagnetic radiation into the sample, or restricted molecular mobility on a surface. In this review we examine the confluence between the fields of hyperpolarization-enhanced NMR and microfluidics, and assess how these areas of research have mutually benefited one another, and will continue to do so.