The aim of this research is to present a new method to identify and separate target DNA of the same size, in base pairs (bp), into different sizes based on the targeted sequences. This sequence-specific analysis can then be used to evaluate the presence of multiple targeted analytes in a sample without the need for fluorescence detection. This work displays the feasibility of this method using multiple different 150 bp target sequences separated via microfluidic electrophoresis into 230 bp to 330 bp peaks. Using a combination of denaturation, hybridization, ligation, purification, and universal amplification, this represents a simple, robust method for targeted analysis of short DNA sequences. This work shows a limit of detection of 3 pg (∼1.825 x 10 copies) of input DNA using 20 PCR cycles and the ability for the method to be used for short DNA sequences extracted from a plasma sample, most importantly cell-free DNA. Overall, this method has the potential to be used for mutation detection and multiplexed analysis without the need for multiple fluorophores or significant optimization due to varying melting temperatures between PCR primers and can qualitatively evaluate the presence of specific target sequences in a variety of molecular diagnostic applications.
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| http://dx.doi.org/10.1016/j.ab.2022.114691 | DOI Listing |
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