4.8 Article

Multiplexed miRNA Quantitation Using Injectionless Microfluidic Thermal Gel Electrophoresis

Journal

ANALYTICAL CHEMISTRY
Volume 94, Issue 14, Pages 5674-5681

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acs.analchem.2c00356

Keywords

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Funding

  1. National Institute of General Medical Sciences of the National Institutes of Health [R21GM137278]
  2. National Science Foundation [2046487]
  3. Wayne State University
  4. Initiative for Maximizing Student Diversity fellowship [NIH R25GM058905-22]
  5. Division Of Chemistry
  6. Direct For Mathematical & Physical Scien [2046487] Funding Source: National Science Foundation

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This report presents a simple and rapid method for directly quantifying multiple miRNAs using microfluidic thermal gel electrophoresis (TGE). The method utilizes fluorescent probes and an innovative microfluidic device to achieve accurate miRNA measurement, and it has been validated with cell extracts. This technique has the potential for automation and can be valuable for clinical and pharmaceutical analyses.
MicroRNAs (miRNAs) are a class of biomolecules that have high clinical and pharmaceutical significance because of their ability to regulate protein expression. Better methods are needed to quantify target miRNAs, but their similar sequence lengths and low concentrations in biomedical samples impede analysis. This report aimed to develop a simple, rapid method to directly quantify multiple miRNAs using microfluidic thermal gel electrophoresis (TGE). Fluorescent probes were designed complementarily in sequence to four target miRNAs that also contained variable DNA overhangs to alter their electrophoretic mobilities. Samples and probes were directly added into thermal gel and loaded throughout a microchannel. Applying voltage resulted in an inline preconcentration and separation of the miRNAs that did not require a sample injection nor user intervention to switch between modes. Baseline resolution was achieved between four double-stranded miRNA-probe hybrids and four excess single-stranded probes. Analytical performance was then improved by designing an innovative microfluidic device with a tapered channel geometry. This device exhibited superior detection limits and separation resolution compared to standard channel devices without increasing the complexity of microfabrication or device operation. A proof-of-concept demonstration was then performed, showing that target miRNAs could be detected from cell extracts. These results demonstrate that TGE provides a simple, inexpensive means of conducting multiplexed miRNA measurements, with the potential for automation to facilitate future clinical and pharmaceutical analyses.

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