Amplification Curve Analysis: Data-Driven Multiplexing Using Real-Time Digital PCR

Amplification Curve Analysis: Data-Driven Multiplexing Using Real-Time Digital PCR

Information about the kinetics of PCR reactions is encoded in the amplification curve. However, in digital PCR (dPCR), this information is typically neglected by collapsing each amplification curve into a binary output (positive/negative). Here, we demonstrate that the large volume of raw data obtai...

Full description

Saved in:
Bibliographic Details
Published in:Analytical chemistry (Washington) Vol. 92; no. 19; pp. 13134 - 13143
Main Authors: Moniri, Ahmad, Miglietta, Luca, Malpartida-Cardenas, Kenny, Pennisi, Ivana, Cacho-Soblechero, Miguel, Moser, Nicolas, Holmes, Alison, Georgiou, Pantelis, Rodriguez-Manzano, Jesus
Format: Journal Article
Language:English
Published: United States American Chemical Society 06-10-2020
Subjects:
Accuracy
Amplification
Analytical chemistry
Antimicrobial resistance
beta-Lactamases - genetics
beta-Lactamases - metabolism
Carbapenems - chemistry
Carbapenems - metabolism
Chemistry
Fluorescence
Kinetics
Learning algorithms
Machine Learning
Melting curve
Multiplexing
Occupancy
Real time
Real-Time Polymerase Chain Reaction
Statistical analysis
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Information about the kinetics of PCR reactions is encoded in the amplification curve. However, in digital PCR (dPCR), this information is typically neglected by collapsing each amplification curve into a binary output (positive/negative). Here, we demonstrate that the large volume of raw data obtained from real-time dPCR instruments can be exploited to perform data-driven multiplexing in a single fluorescent channel using machine learning methods, by virtue of the information in the amplification curve. This new approach, referred to as amplification curve analysis (ACA), was shown using an intercalating dye (EvaGreen), reducing the cost and complexity of the assay and enabling the use of melting curve analysis for validation. As a case study, we multiplexed 3 carbapenem-resistant genes to show the impact of this approach on global challenges such as antimicrobial resistance. In the presence of single targets, we report a classification accuracy of 99.1% (N = 16188), which represents a 19.7% increase compared to multiplexing based on the final fluorescent intensity. Considering all combinations of amplification events (including coamplifications), the accuracy was shown to be 92.9% (N = 10383). To support the analysis, we derived a formula to estimate the occurrence of coamplification in dPCR based on multivariate Poisson statistics and suggest reducing the digital occupancy in the case of multiple targets in the same digital panel. The ACA approach takes a step toward maximizing the capabilities of existing real-time dPCR instruments and chemistries, by extracting more information from data to enable data-driven multiplexing with high accuracy. Furthermore, we expect that combining this method with existing probe-based assays will increase multiplexing capabilities significantly. We envision that once emerging point-of-care technologies can reliably capture real-time data from isothermal chemistries, the ACA method will facilitate the implementation of dPCR outside of the lab.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0003-2700
1520-6882
DOI:10.1021/acs.analchem.0c02253