Improving Quantitative Power in Digital PCR through Digital High-Resolution Melting
Autor: | Shelley M. Lawrence, Yunshu Geng, Stephanie I. Fraley, Mridu Sinha, Daniel Ortiz Velez, Yixu Yuan, April Aralar, Kevin Chen |
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Rok vydání: | 2020 |
Předmět: |
0301 basic medicine
Microbiology (medical) Diagnostic Tests Routine Computer science business.industry 030106 microbiology False positives and false negatives Bacteriology Pattern recognition Microbial profiling DNA Amplicon Real-Time Polymerase Chain Reaction High Resolution Melt 03 medical and health sciences 030104 developmental biology Robustness (computer science) False positive paradox Humans Digital polymerase chain reaction Artificial intelligence business Control methods |
Zdroj: | J Clin Microbiol |
ISSN: | 1098-660X 0095-1137 |
Popis: | Applying digital PCR (dPCR) technology to challenging clinical and industrial detection tasks has become more prevalent because of its capability for absolute quantification and rare target detection. However, practices learned from quantitative PCR (qPCR) that promote assay robustness and wide-ranging utility are not readily applied in dPCR. These include internal amplification controls to account for false-negative reactions and amplicon high-resolution melt (HRM) analysis to distinguish true positives from false positives. Incorporation of internal amplification controls in dPCR is challenging because of the limited fluorescence channels available on most machines, and the application of HRM analysis is hindered by the separation of heating and imaging functions on most dPCR systems. We use a custom digital HRM platform to assess the utility of HRM-based approaches for mitigation of false positives and false negatives in dPCR. We show that detection of an exogenous internal control using dHRM analysis reduces the inclusion of false-negative partitions, changing the calculated DNA concentration up to 52%. The integration of dHRM analysis enables classification of partitions that would otherwise be considered ambiguous “rain,” which accounts for up to ∼3% and ∼10% of partitions in intercalating dye and hydrolysis probe dPCR, respectively. We focused on developing an internal control method that would be compatible with broad-based microbial detection in dPCR-dHRM. Our approach can be applied to a number of DNA detection methods including microbial profiling and may advance the utility of dPCR in clinical applications where accurate quantification is imperative. |
Databáze: | OpenAIRE |
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