Droplet Digital PCR (ddPCR) is a method for performing digital PCR that is based on water-oil emulsion droplet technology. A sample is fractionated into 20,000 droplets, and PCR amplification of the template molecules occurs in each individual droplet. ddPCR technology uses reagents and workflows similar to those used for most standard TaqMan probe-based assays. The massive sample partitioning is a key aspect of the ddPCR technique.
This section provides an overview of droplet digital PCR technology, how ddPCR works, and what the advantages and benefits of ddPCR are.
Related topics: Planning Droplet Digital PCR Experiments, Absolute Quantification of PCR Targets with the QX100™ ddPCR™ System
Our PrimePCR™ Assays for Droplet Digital™ PCR are designed and validated for copy number variation, rare mutation detection, NGS library quantification, and high-sensitivity gene expression studies.
Droplet Digital PCR technology is a digital PCR method utilizing a water-oil emulsion droplet system. Droplets are formed in a water-oil emulsion to form the partitions that separate the template DNA molecules. The droplets serve essentially the same function as individual test tubes or wells in a plate in which the PCR reaction takes place, albeit in a much smaller format. The massive sample partitioning is a key aspect of the ddPCR technique.
The QX100™ Droplet Digital PCR system partitions nucleic acid samples into thousands of nanoliter-sized droplets, and PCR amplification is carried out within each droplet. This technique has a smaller sample requirement than other commercially available digital PCR systems, reducing cost and preserving precious samples.
Sample partitioning is the key to droplet digital PCR. In traditional PCR, a single sample offers only a single measurement, but in Droplet Digital PCR, the sample is partitioned into 20,000 nanoliter-sized droplets. This partitioning enables the measurement of thousands of independent amplification events within a single sample.
ddPCR technology uses a combination of microfluidics and proprietary surfactant chemistries to divide PCR samples into water-in-oil droplets (Hindson et al. 2011). The droplets support PCR amplification of the template molecules they contain and use reagents and workflows similar to those used for most standard TaqMan probe-based assays. Following PCR, each droplet is analyzed or read in a flow cytometer to determine the fraction of PCR-positive droplets in the original sample. These data are then analyzed using Poisson statistics to determine the target DNA template concentration in the original sample.
Droplet Digital PCR surpasses the performance of earlier digital PCR techniques by resolving the previous lack of scalable and practical technologies for digital PCR implementation. Serial dilution is laborious and introduces the possiblity of pipetting error; competing chip-based systems rely on complex fluidics schemes for partitioning. Droplet Digital PCR addresses these shortcomings by massively partitioning the sample in the fluid phase in one step. The creation of tens of thousands of droplets means that a single sample can generate tens of thousands of data points rather than a single result, bringing the power of statistical analysis inherent in digital PCR into practical application. The QX100 Droplet Digital PCR system automates the ddPCR workflow of droplet generation, thermal cycling, droplet reading, and data analysis, making this technology accessible to the working research laboratory.
ddPCR technology enables high-throughput digital PCR in a manner that uses lower sample and reagent volumes and reduces overall cost compared with other methods while maintaining the sensitivity and precision that are the hallmarks of digital PCR.
The benefits of ddPCR technology include:
Bio-Rad’s QX100 Droplet Digital PCR (ddPCR) system consists of two instruments, the QX100 droplet generator and the QX100 droplet reader, plus their associated software and consumables. The QX100 droplet generator partitions samples (20 µl into 20,000 nanoliter-sized droplets) for PCR amplification. Following amplification using a thermal cycler, droplets from each sample are analyzed individually on the QX100 droplet reader, where PCR-positive and PCR-negative droplets are counted to provide absolute quantification of target DNA in digital form.
The ddPCR system can be used to:
QX100 Droplet Digital PCR system. QX100 droplet reader (left) and the QX100 droplet generator (right).
This 3-D animated video describes the principles and process of ddPCR using the QX100 Droplet Digital PCR system.
The workflow is quite simple. First, the QX100 droplet generator partitions samples into thousands of nanoliter-sized droplets. After PCR on a thermal cycler, droplets from each sample are streamed in single file on the QX100 droplet reader to count positive and negative reactions. The PCR-positive and PCR-negative droplets are counted to provide absolute quantification in digital form. The steps are described in more detail below.
Step 0: Prepare PCR-Ready Samples prior to Starting ddPCR
Step 1: Droplet Generation Prior to droplet generation, nucleic acid samples (DNA or RNA) are prepared as they are for any real-time assay: using primers, fluorescent probes (TaqMan probes with FAM and HEX or VIC), and a proprietary supermix developed specifically for droplet generation. Samples are then placed into the QX100 droplet generator, which utilizes proprietary reagents and microfluidics to partition the samples into 20,000 nanoliter-sized droplets. The droplets created by the QX100 droplet generator are uniform in size and volume.
Step 2: PCR Amplification of Droplets
Droplets are transferred to a 96-well plate for PCR amplification in any compatible thermal cycler.
Step 3: Droplet Reading
Following PCR amplification of the nucleic acid target in the droplets, the samples are placed in the QX100 droplet reader, which analyzes each droplet individually using a two-color detection system (set to detect FAM and either HEX or VIC), enabling multiplexed analysis for different targets in the same sample. The droplet reader and its bundled QuantaSoft™ software count the PCR-positive and PCR-negative droplets.
Digital droplet reading. Fluorescence measurements for each droplet in two optical channels are used to count the numbers of positive and negative droplets per sample.
Step 4: Analyze Results
Positive droplets, containing at least one copy of the target, exhibit increased fluorescence over negative droplets. In ddPCR, the QuantaSoft software measures the numbers of droplets that are positive and negative for each fluorophore (for example, FAM and HEX) in a sample. The fraction of positive droplets is then fitted to a Poisson distribution to determine the absolute initial copy number of the target DNA molecule in the input reaction mixture in units of copies/µl.
Sample results from a ddPCR experiment. Each droplet in a sample is plotted on a graph of fluorescence intensity versus droplet number. All positive droplets (those above the threshold intensity indicated by the red line) are scored as positive, and each is assigned a value of 1. All negative droplets (those below the threshold) are scored as negative, and each is assigned a value of 0 (zero). This counting technique provides a digital signal from which to calculate the starting target DNA concentration by a statistical analysis of the numbers of positive and negative droplets in a given sample.
Droplet Digital PCR data from a multiplex experiment in which two targets are PCR amplified can also be viewed as a 2-D plot in which FAM fluorescence is plotted versus HEX fluorescence for each droplet. Because the DNA distribution into the droplets follows a random pattern, the droplets are clustered into four groups:
2-D plot of droplet fluorescence.
The QuantaSoft software fits the fraction of positive droplets to a Poisson distribution to determine the absolute starting copy number in units of copies/µl input sample and then reports the target DNA concentration in the form of copies per µl in the sample.
Concentration results. Sample concentrations are plotted as copies per µl.
Step 5: Visualize Data
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