Issue 20, 2023

Real-time continuous monitoring of dynamic concentration profiles studied with biosensing by particle motion

Abstract

Real-time monitoring-and-control of biological systems requires lab-on-a-chip sensors that are able to accurately measure concentration–time profiles with a well-defined time delay and accuracy using only small amounts of sampled fluid. Here, we study real-time continuous monitoring of dynamic concentration profiles in a microfluidic measurement chamber. Step functions and sinusoidal oscillations of concentrations were generated using two pumps and a herringbone mixer. Concentrations in the bulk of the measurement chamber were quantified using a solution with a dye and light absorbance measurements. Concentrations near the surface were measured using a reversible cortisol sensor based on particle motion. The experiments show how the total time delay of the real-time sensor has contributions from advection, diffusion, reaction kinetics at the surface and signal processing. The total time delay of the studied real-time cortisol sensor was ∼90 seconds for measuring 63% of the concentration change. Monitoring of sinusoidal cortisol concentration–time profiles showed that the sensor has a low-pass frequency response with a cutoff frequency of ∼4 mHz and a lag time of ∼60 seconds. The described experimental methodology paves the way for the development of monitoring-and-control in lab-on-a-chip systems and for further engineering of the analytical characteristics of real-time continuous biosensors.

Graphical abstract: Real-time continuous monitoring of dynamic concentration profiles studied with biosensing by particle motion

Supplementary files

Article information

Article type
Paper
Submitted
10 May 2023
Accepted
10 Sep 2023
First published
29 Sep 2023
This article is Open Access
Creative Commons BY license

Lab Chip, 2023,23, 4600-4609

Real-time continuous monitoring of dynamic concentration profiles studied with biosensing by particle motion

M. H. Bergkamp, S. Cajigas, L. J. van IJzendoorn and M. W. J. Prins, Lab Chip, 2023, 23, 4600 DOI: 10.1039/D3LC00410D

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