Abstract
While many decisions rely on real time quantitative PCR (qPCR) analysis few attempts have hitherto been made to quantify bounds of precision accounting for the various sources of variation involved in the measurement process. Besides influences of more obvious factors such as camera noise and pipetting variation, changing efficiencies within and between reactions affect PCR results to a degree which is not fully recognized. Here, we develop a statistical framework that models measurement error and other sources of variation as they contribute to fluorescence observations during the amplification process and to derived parameter estimates. Evaluation of reproducibility is then based on simulations capable of generating realistic variation patterns. To this end, we start from a relatively simple statistical model for the evolution of efficiency in a single PCR reaction and introduce additional error components, one at a time, to arrive at stochastic data generation capable of simulating the variation patterns witnessed in repeated reactions (technical repeats). Most of the variation in values was adequately captured by the statistical model in terms of foreseen components. To recreate the dispersion of the repeats' plateau levels while keeping the other aspects of the PCR curves within realistic bounds, additional sources of reagent consumption (side reactions) enter into the model. Once an adequate data generating model is available, simulations can serve to evaluate various aspects of PCR under the assumptions of the model and beyond.
Highlights
Since its inception in the mid 1980s, the polymerase chain reaction (PCR) has revolutionized biomedical research
One has recognized that an appreciable degree of uncertainty could accompany stated PCR results
Many publications pertaining to real time PCR results forgo uncertainty measures
Summary
Since its inception in the mid 1980s, the polymerase chain reaction (PCR) has revolutionized biomedical research. As little as a single DNA molecule can be amplified to detectable levels. Fluorescent dyes make it possible to monitor this amplification process in real time, allowing relative quantification of the initial amount of template DNA. Many publications pertaining to real time PCR results forgo uncertainty measures. In theory every reaction’s outcome should be an exact representation of its initial number of target copies, in practice, several mechanisms introduce variation between repeated reactions This variance is not readily explained by measurement error and copy number variation. We aim to recreate between repeat fluorescence variability by adding probable sources of variation to a statistical model of the PCR process
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