The present application claims the benefit of priority under 35 U.S.C. §119 of EP14182415.1, filed Aug. 27, 2014, the content of which is incorporated by reference herein in its entirety.
The present disclosure relates to the field of analytics, and more particularly to an analysis method for a Real-time Nucleic acid amplification Reaction (RNR) such as a polymerase chain reaction PCR and a system for analyzing a nucleic acid amplification reaction of an analyte, such as for detecting a presence and/or measuring a quantity of an analyte in a sample by a nucleic acid amplification reaction
In vitro nucleic acid amplification techniques include a variety of methods based on different approaches. One approach includes methods by which a DNA or RNA sequence is multiplied, thus making it more readily detectable for various procedures or tests. For example, in vitro amplification of the nucleic acid can be done using one of the following methods: Polymerase chain reaction (PCR), Ligase chain reaction (LCR), or isothermal transcription mediated amplification (TMA) method. In all of the above mentioned approaches the nucleic acid is subjected to repetitive amplification cycles.
A technique that is frequently used for various medical, biological or industrial applications is the PCR technique. This technique relies on thermal cycling, including cycles of repeated heating and cooling for enzymatic replication of the nucleic acid in order to amplify a specific region of the nucleic acid strand. As PCR progresses, the DNA generated is itself used as a template for replication, setting in motion a chain reaction in which the DNA template is exponentially amplified doubling (at least theoretically) with each reaction cycle.
Nucleic acid amplification techniques include many variations. One of these variations is called real-time nucleic acid RNR and is based on amplifying and simultaneously detecting the presence of nucleic acid in the sample and additionally to quantify its concentration in the sample.
There are several known methods for the detection of products in quantitative nucleic acid amplification. According to one of these methods, in order to indirectly measure the amount of nucleic acid during RNR, the intensity of a fluorescence emission of the analyte is acquired and a growth curve is created indicative of the intensity of the fluorescence emission over the RNR cycle range. The increase of the growth curve signal above the initially stationary baseline is used to determine a quantification cycle Cq in each reaction.
The determination of the quantification cycle Cq based on the growth curve using various CT methods is the subject of multiple patent applications:
EP 2719770 A1 discloses a method of detecting a presence and/or measuring a quantity of an analyte in a sample by PCR as well as a respective analyzer. In particular, signal normalization of the growth curve taking into account a maximum growth value of the signal is disclosed.
U.S. Pat. No. 7,788,039 B2 discloses a method for determining an amount of target nucleic acid in a sample. An initial amount of the target is calculated according to a calibration equation using an initial amount of the standard, the target and standard growth curve values, where the calibration equation is a non-linear equation.
EP1798652B1 discloses a mathematical algorithm for creating a growth signal from measurement data.
EP1798542A1 shows a method for determining the presence of a nucleic acid in a sample wherein a digital value is selected on the growth signal and the presence of the nucleic acid is determined from a comparison of the selected digital value with calibrated digital values.
“Analyzing real-time PCR data by the comparative CT method”, Thomas D Schmittgen et al., Nature Protocols 3, -1101-108 (2008) provides an overview of the comparative CT method for quantitative gene expression studies.
Nucleic acid amplification systems are commercially available from various vendors based on various nucleic acid amplification methods and employed for medical applications such as the detection of infectious diseases. Therefore, reliability and precision of nucleic acid amplification methods is of utmost importance.
Embodiments of the disclosed subject matter therefore aim to provide an improved analysis method using nucleic acid amplification and a respective system that enable improved robustness, precision, accuracy, linearity and qualitative discrimination of a nucleic acid amplification analysis.
In accordance with embodiments of the disclosed subject matter, an analysis method for a real-time polymerase chain reaction is provided for detecting a presence and/or measuring a quantity of an analyte in a sample. Further, a system for analyzing a nucleic acid amplification reaction of an analyte is provided. Further embodiments are also provided.
Embodiments of the disclosed subject matter relate to an analysis method for a real-time nucleic acid amplification RNR using a combined threshold function CTF over the RNR cycle range, the CTF including at least two different threshold levels. The CTF is obtained by calculation on the basis of the at least two different threshold levels.
The calculation may be performed before or after the acquisition of the intensity of the fluorescence emission and the creation of the growth curve. For example, the calculation is performed once and the resultant CTF is stored in an electronic memory for reading out the CTF when it is needed for determining the quantification cycle number Cq of the RNR. Alternatively the CTF is calculated after the acquisition of the intensity of the fluorescent emission and/or after the creation of the growth curve before the determination of the quantification cycle number.
Embodiments of the disclosed subject matter are particularly advantageous as combining at least two different threshold levels into the CTF enables improvement of the precision of the RNR over a wide range of analyte concentrations and/or limit the effect of the presence of interfering substances.
Moreover, embodiments of the disclosed subject matter are particularly advantageous as the occurrence of false negatives for weak analyte concentrations and erroneous Cq values for high analyte concentrations are prevented thus increasing the reliable working range of the RNR analysis.
In accordance with embodiments of be disclosed subject matter at least one of the CT threshold levels is a constant value over the RNR cycle range. The constant value may be given by a relative intercept increase (RII-method), a partial growth threshold (PGT-method), a multiple of standard deviation of the growth curve above the baseline, a manually set threshold or a constant function.
In accordance with embodiments of the disclosed subject matter the CTF is obtained from the at least two different threshold levels by combining the threshold levels over the RNR cycle range, such as by superposition, linear or non-linear combination. Alternatively or in addition the CTF is obtained by dividing the RNR cycle range into RNR cycle intervals and calculating a separate CTF per interval using at least two different threshold levels per interval wherein the at least two different threshold levels can vary from interval to interval.
In accordance with an embodiment of the disclosed subject matter the CTF is a combination, such as a linear combination, of two threshold levels over the entire RNR cycle range. One of the threshold levels delivers a dominant contribution to the CTF at early reaction cycles of the RNR, such as for cycle numbers below 10, 15 or 20, whereas one of the threshold levels delivers a dominant contribution to the CTF at late reaction cycles of the RNR, such as for cycle numbers greater than 30, 40 or 50. In accordance with embodiments of the disclosed subject matter the CTF transitions from an initial threshold level to a final threshold level over the RNR cycle range. In other words, the contribution of the initial threshold level to the CTF may be dominant for early reaction cycles of the RNR such as for cycle number 0 or 1 and the contribution of the final threshold level to the CTF may be substantially below the contribution of the initial threshold level such as 0 at early reaction cycles of the RNR, such as for cycle number 0 or 1. Analogously, the contribution of the final threshold level at late reaction cycles of the RNR to the CTF may be substantially above the contribution of the initial threshold level. The transition of the CTF from the initial threshold level to the final threshold level over the RNR cycle range may be a step or multi-step transition, a linear transition, as polynomial transition, an exponential transition or a combination thereof.
In accordance with embodiments of the disclosed subject matter the initial threshold level itself comprises a first combination A of at least two different threshold levels. Alternatively or in addition, the final threshold level itself includes to second combination B of at least two different threshold levels where the threshold levels that are combined into the initial threshold level may be the same or different threshold levels than the threshold levels that are combined into the final threshold level.
In accordance with an embodiment of the disclosed subject matter one of the initial and final threshold levels is not a combination of threshold levels but a single threshold level.
In accordance with embodiments of the disclosed subject matter the initial threshold level comprises at least one threshold level that is adapted for precise determination of the quantification cycle number for a strong growth curve, i.e., a growth curve obtained for a high analyte concentration and/or low concentration of an interference substance.
On the other hand, the final threshold level includes at least one threshold level that is adapted for precise determination of the quantification cycle number for late increases, i.e., a low analyte concentration and/or high concentration of an interference substance. Due to the transition of the CTF from the initial threshold level to the final threshold level over the RNR cycle range a precise determination of the quantification cycle number is enabled both for early and late signal increases.
In accordance with embodiments of the disclosed subject matter the initial threshold level has a starting point with a y-coordinate below a y-coordinate of an end point of the final threshold level resulting in an increasing combined threshold function with a positive slope or the initial threshold level has a starting point with a y-coordinate above a y-coordinate of an end point of the final threshold level resulting in a decreasing combined threshold function, i.e. in a combined threshold function that has a negative slope over the RNR cycle range.
In accordance with embodiments of the disclosed subject matter the y-coordinate of the starting point and the y-coordinate of the end point are used to calculate the combined threshold function by a linear, polynomial, exponential, logarithmic or other transition between the two y-coordinates. For example, the two y-coordinates are stored in an electronic memory and read from the electronic memory for calculating the combined threshold function by means of linear interpolation between the two y-coordinates.
In accordance with embodiments of the disclosed subject matter the CTF is a constant over the RNR cycle range. For example each of the threshold levels provides a constant and the combined threshold function is calculated as a linear combination of the two constants such as an average or a weighted average of the two constants. For example, one of the threshold levels is adapted for precise determination of the quantification cycle number for an early signal increase whereas the other of the two threshold levels may be adapted for precise determination of the quantification cycle number for a late signal increase hence for CT determination at late reaction cycles of the RNR.
In accordance with another aspect of the disclosed subject matter a system for analyzing a nucleic acid amplification reaction of an analyte is provided, the system comprising: a detection system configured to acquire the intensity of fluorescence emission of the analyte for each amplification reaction cycle of the RNR and a processing will configured to: create a growth curve indicative of the intensity of the fluorescent emission over a range of reaction cycles of the RNR, provide a combined threshold function CTF comprising at least two different threshold levels; and determine a quantification cycle number Cq of the RNR, the quantification cycle number Cq being indicative of a quantitative and/or qualitative analysis result of the growth curve as the cycle number corresponding to an intersection of the growth curve with the combined threshold function.
In accordance with embodiments of the disclosed subject matter the processing unit provides the combined threshold function by reading data from an electronic memory of the system that is descriptive of the combined threshold function and calculating the combined threshold function using this data and/or the growth curve. For example, the data stored in the electronic memory indicates the y-coordinate of the starting point of the initial threshold level and the end point of the final threshold level and the calculation of the combined threshold function by the processor is performed by means of an interpolation between the y-coordinates over the RNR cycle range.
Embodiments of the disclosed subject matter may be particularly advantageous as the accuracy and precision of the analysis may be increased over a wide concentration range of the analyte and/or robustness against interferences.
Other and further objects, features and advantages of the embodiments will appear more fully from the following description. The accompanying drawings, together with the general description given above and the detailed description given below, serve to explain the principles of the embodiments.
By way of illustration, specific exemplary embodiments in which the disclosed subject matter may be practiced now are described.
Certain terms will be used in this patent application, the formulation of which should not be interpreted to be limited by the specific term chosen, but as to relate to the general concept behind the specific term.
The term ‘baseline’ refers to the initial portion of the growth curve which shows no signal increase.
The term ‘intercept’ or ‘intercept value’ as understood herein is the signal offset value of the growth curve at an early cycle number, i.e., 0 that is obtained by extrapolation.
The term ‘saturation line’ refers to the portion of the growth curve in the plateau region after the exponential growth phase which is also referred to as exponential amplification phase and after the leveling off stage.
The term ‘threshold level’ as used herein encompasses a threshold level for the growth curve.
A ‘combined threshold function’ or ‘CTF’ as understood herein encompasses a mathematical function over the cycle range that is composed of at least two different threshold levels. According to one embodiment, a CTF may be a linear or logarithmic combination of two different threshold levels.
In one embodiment, the Y-value, i.e. the threshold level, returned by the CTF for a given X-value, i.e., cycle number, may transition from one of the two different threshold levels to the other one.
According to one embodiment, a CTF may transition from a first combination (e.g. linear or logarithmic) of at least two different threshold levels to a second combination (e.g. linear or logarithmic) of at least two different threshold levels.
The term ‘real-time nucleic acid amplification RNR cycle range’ as understood herein refers to the range of cycle numbers that is executed for acquiring the intensity values for the creation of the growth curve. For example, the RNR cycle range may be a predefined fixed number, such as 30, 40 or 50. Setting the RNR cycle range is as tradeoff between throughput of the analysis system for analyzing the nucleic acid amplification reaction and the sensitivity of the analysis system for the determination of a quantification cycle number for weak signals.
In accordance with an embodiment of the disclosed subject matter a threshold method is implemented as a relative intercept increase RII. For example, the RII is a parallel above the baseline.
In accordance with embodiments of the disclosed subject matter the RII may have the following format:
y(x)=B+r·I (1)
B: baseline function, typically linear
I: intercept extrapolation to cycle number 0
r: positive percentage parameter, e.g. 50%
In accordance with embodiments of the disclosed subject matter a threshold method may be implemented as a partial growth threshold PGT that depends on the signal difference of the growth curve between the saturation line and the baseline, i.e. the growth from the baseline to the saturation line. The PGT may return a constant Y-value over the entire range of cycle numbers.
In accordance with embodiments of the disclosed subject matter the PGT may have the following form:
y(x)=B+p·G=B+p·(S−B) (2)
B: baseline function
S: Saturation line
G: growth from baseline to saturation line
p: parameter preferably between 0% and 100%, e.g. 5%
In accordance with an embodiment of the disclosed subject matter a threshold method is given by the standard deviation of the growth curve above the baseline and may have the following form:
y(x)=B+f·D (3)
B: baseline function
f: Multiplying factor parameter, e.g. 10
D: Standard deviation of growth curve
In accordance with embodiments of the disclosed subject matter as threshold method is given by a threshold value that is pre-set or manually entered by a user.
In accordance with an embodiment of the disclosed subject matter the threshold method is a constant value that is constant over the RNR cycle range, for example:
y(x)=C (4)
C: a predefined constant based on empirical data.
In accordance with embodiments of the disclosed subject matter the transition from one of the at least two different threshold levels, i.e. the initial threshold level, to the other one of the at least two different threshold levels, i.e. the final threshold level, is such by a step or multi-step, linear, polynomial and/or exponential transition as illustrated on
For example, a CTF with a linear transition from the initial threshold level y1 to the final threshold level y2 may have the following form:
where:
x1: early reaction cycle number, such as 0 or 1;
x2: late reaction cycle number, such as 30, 40 or 50;
y1: initial threshold level;
y2: final threshold level.
In accordance with an embodiment of the disclosed subject matter the CTF may have the following format for implementation of a polynomial transition:
where:
p: Fixed polynomial order, such as 2 for a quadratic polynomial function.
In accordance with an embodiment of the disclosed subject matter the CTF may have the following format for implementation of an exponential transition:
The analyte is conjugated to a fluorescent dye and the sample is loaded into the thermal cycler block 120. A thermal cycler block 120 can be a conventional design sample block, which comprise 96 wells and is able to hold up to 96 samples. The sample is illuminated with the fluorescence excitation source 110, and the raw fluorescence data is measured by the RNR detector system 130 for each RNR cycle number. The RNR detector 130 is suitable to collect the RNR fluorescence signal emitted by one or more fluorescent dyes. The measured data is collected in data processing system memory unit 150, and can be displayed on the display unit 170 as an un-normalized RNR growth curve, or alternatively as a normalized RNR growth curve.
The baseline 240 is the RNR signal during the initial cycles of the RNR reaction, typically measured between cycles 1 and 15, where there is no detectable increase in fluorescence due to RNR reaction products. The baseline 240 is the baseline function B (cf. equations 1 to 3). The pre-defined threshold 220 is used to determine a cycle number at which the RNR signal exceeds the baseline 240 of the RNR reaction, i.e. the cycle in which there is the first detectable significant increase in fluorescence, which is about cq=22 here. The threshold 220 is given by CTF (cf. equations 5 to 7).
The maximum growth value 250 is a difference between as maximum intensity of the RNR signal at a plateau region 230 and the RNR signal at the baseline 240. The plateau stage 230 is the RNR signal during final cycles of the RNR reaction.
The intensity of the RNR signal at a plateau region 230 is S and the maximum growth value 250 is the growth G in the above equation 2.
The diagram shows a first threshold level y1 and a second threshold level y2.
The threshold y1 may be defined by entering a starting point T1 (x1, y1); likewise the threshold level y2 may be defined by entering an end point T2 (x2, y2).
In the embodiment considered here the y-coordinate of the starting point T1 that determines the threshold level y1 is greater than the respective coordinate of y2 of the end point T2 such that y1 is above the other threshold level y2 as illustrated in
The growth curve 200.1 originates from a sample concentration at the upper end of the dynamic range of the RNR whereas the sample concentration for the growth curve 200.2 is at the lower end of the dynamic range. As a consequence, the exponential phase of the growth curve 200.1 occurs in a much lower cycle number range that is the case for the growth curve 200.2 as illustrated in
Application of the threshold level y1 alone for the determination of cq of growth curves 200.1 and 200.2 would result in the detection of cq only for growth curve 200.1 but would fail to detect a cq value (or lead to very late detection) for growth curve 200.2 as the latter is too weak to reach the intensity y1 in its exponential phase and/or plateau region within the RNR cycle range.
On the other hand, usage of threshold level y2 alone would lead to the detection of a cq value for growth curve 200.2 but would be unreliable as regards detection for a cq value for growth curve 200.1 as y2 is close to the baseline such that variations could lead to an imprecise Cq detection for the growth curve 200.1.
This situation is remedied by combining threshold levels y1 and y2 which provides a combined threshold function CTF(x). In the example considered here, the CTF is in accordance with above equation 5 such that CTF has a linear transition from y1 to y2 over the x-coordinate range x1 to x2 as illustrated in
Hence, the combined threshold function CTF(x) is calculated by combining the threshold levels y1 and y2. In the embodiment considered here this is a linear combination providing a linear transition from T1 to T2 along the x-axis. The RNR cycle range an be set to be equal to the x-coordinate range x1 to x2 in the embodiment considered here as additional RNR cycles above cycle x2 would not provide a significant contribution to the quantification cycle number determination but merely reduce system throughput.
The calculation of the CTF can be performed by the RNR system 100 (cf.
In the example illustrated in
Alternatively CTF(x) can be in accordance with above equation 6 or 7 or it can be another monotonous or step-function.
In accordance with embodiments of the disclosed subject matter the threshold level y1 is in accordance with equation 2 thus taking into account the signal level S of the saturation line in the plateau phase whereas the threshold level y2 is in accordance with equation 1 taking into account the intercept value I rather than S.
The resultant CTF is illustrated in
As it can be observed in
The equidistant Cq values that are obtained in the above case iii, reflect the constant relative concentration of the respective analytes corresponding to consequent growth curves 200.1 to 200.7 (i.e. one order of magnitude for consecutive curves) which is due to the fact that the point of intersection of the CTF with the respective growth curves is always within the exponential growth phase irrespective of the degree of dilution of the analyte over an extremely broad concentration range. This in turn implies that the precision of the Cq determination is substantially increased in comparison to above cases i. and ii. due to the fact that the growth curve has the lowest amount of noise within the exponential growth phase and thus yields most accurate results.
As apparent from
While the foregoing embodiments have been described in some detail for purposes of clarity and understanding, it will be clear to one skilled in the art from a reading of this disclosure that various changes in form and detail can be made without departing from the true scope of the subject matter. For example, all the techniques and apparatus described above can be used in various combinations. All publications, patents, patent applications, and/or other documents cited in this application are incorporated by reference in their entirety for all purposes to the same extent as if each individual publication, patent, patent application, and/or other document were individually indicated to be incorporated by reference for all purposes.
Number | Date | Country | Kind |
---|---|---|---|
14182415.1 | Aug 2014 | EP | regional |