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An Integrated Platform for the Assessment of Fluorescent Signals in Hydrogel Beads Produced by Droplet Microfluidics | IEEE Conference Publication | IEEE Xplore
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An Integrated Platform for the Assessment of Fluorescent Signals in Hydrogel Beads Produced by Droplet Microfluidics

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Kathrine Nygaard Borg; Guangyao Cheng; Ayush Shetty; Tianle Wang; Cinzia Tesauro; Birgitta Ruth Knudsen
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Abstract:

Biomedical applications using hydrogel beads as incubators are continuously developing. Herein, we present a platform streamlining the production of hydrogel beads, detec...Show More

Metadata

Abstract:

Biomedical applications using hydrogel beads as incubators are continuously developing. Herein, we present a platform streamlining the production of hydrogel beads, detection of fluorescent signals, and post-analysis, using polyacrylamide (PAA) beads produced by droplet microfluidics as a model. A customized optical detection module is integrated with the data acquisition and analysis modules developed by LabVIEW and Python, respectively. The platform is evaluated by a series of characterizations. We expect to promote this platform for the quantitative assessment of biochemical reactions occurring in the PAA- based incubators.
Published in: 2023 IEEE 23rd International Conference on Nanotechnology (NANO)
Date of Conference: 02-05 July 2023
Date Added to IEEE Xplore: 01 September 2023
ISBN Information:

ISSN Information:

DOI: 10.1109/NANO58406.2023.10231287
Conference Location: Jeju City, Korea, Republic of

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References is not available for this document.
Contents

I. Introduction

Hydrogel beads are widely employed for biomedical applications including diagnostics [1], drug delivery [2] and tissue engineering [3], owing to the features of hydrophilicity, biocompatibility, and tailorable properties. Compared to their counterparts of solid and non-permeable particles, hydrogels are highly porous and permeable, providing an extended surface area for chemical functionalization for such as detection probes or targeting ligands required in biochemical reactions [4]. Moreover, the high liquid contents presented in hydrogels also provide the benefits of transparency and biocompatibility for the ease of optical detection [5] and aqueous-based biological reactions [6], [7]. Recent developments on microfluidics [8] have enabled the production of hydrogel beads in a high- throughput (> 1,000 drops per second) and controllable (uniform droplet size) manner. Furthermore, the porosity of hydrogel network may also be regulated by the concentration of crosslinkers and polymerization catalysts, for an array of purposes including entrapment of cells or biomolecules [9], DNA barcoding [6], display of proteins [10] and as nanoreactors for enzymatic reactions [11].

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