EP2361316A1 - Real time pcr through gigahertz or terahertz spectrometry - Google Patents

Abstract

The invention relates to a method for spectroscopic real-time detection of nucleic acid molecules, in particular polynucleotide sequences, in a PCR amplification (PCR=polymerase chain reaction), wherein the PCR amplification comprises preparing the initial substances required for producing a PCR solution in a buffer and the repeating PCR reaction steps of denaturing, primer hybridization and elongation, and wherein electromagnetic radiation is irradiated into the PCR solution during the PCR amplification at defined time points from a radiation source in the gigahertz or terahertz regime in order to detect at least the presence or absence of a polynucleotide sequence using a detector in a real-time detection.

Description

 Real-time PCR using gigahertz or terahertz spectrometry

description

The invention relates to a method for the spectroscopic real-time detection of nucleic acid molecules, in particular of polynucleotide sequences, in a PCR amplification, and to a corresponding PCR arrangement (PCR = polymerase chain reaction).

Such methods as well as PCR arrangements are typically used for the quantitative analysis of the expression of certain gene sequences. PCR amplifications in general are widely used in the amplification and analysis of DNA or RNA sequences found in many biological systems, but can also be used in principle with artificially engineered polynucleotide sequences.

The method described here relates to a spectroscopic real-time detection in a PCR amplification. This refers both to evidence during the course of all reaction steps of a PCR amplification, as well as to appropriate evidence before and after. Thus, for example, substances used in preliminary steps prior to the execution of the actual PCR reaction steps for the replication of polynucleotide sequences can be examined qualitatively and quantitatively by means of spectroscopic detection. Furthermore, spectroscopic examination steps can also be carried out during the PCR amplification, and even if the PCR amplification itself has already ended.

PCR amplifications are typically used to amplify relatively short and clearly-defined polynucleotide sequences as compared to the human genome. In contrast to living organisms, PCR amplification can only ensure the amplification of polynucleotide sequences of a few thousand base pairs per sequence. To carry out a PCR amplification, it first requires the preparation of a PCR solution which, in addition to a buffer solution as a suitable chemical environment, has a number of further starting substances necessary for the course of a PCR amplification. These starting substances typically include an original polynucleotide sequence to be amplified, primers to define a start and an end portion of the polynucleotide sequence to be amplified, a corresponding polymerase to replicate the portion defined by the primers, and deoxynucleoside triphosphates, which are the building blocks of the replicated polynucleotide sequence. In addition to these starting substances, a PCR solution may also contain a number of other functional components which allow, for example, to increase or optimize the progress of PCR amplification in terms of effectiveness.

A PCR amplification consists of a repetitive sequence of PCR reaction steps, as can be carried out in laboratory thermal cyclers. Each repeat includes the three PCR reaction steps of denaturation, primer hybridization and elongation. Denaturation initially melts double-stranded polynucleotide sequences, heating the PCR solution to a temperature of about 95 ° C to dissolve the hydrogen bonds that hold the two single-stranded polynucleotide sequences together. The temperature level is maintained until it is ensured that only single-stranded polynucleotide sequences are present in the PCR solution. In the PCR reaction step of primer hybridization, the temperature is typically held for a few seconds at a level which allows specific attachment of the primer to the polynucleotide sequence. The designated temperature level is normally a few ⁰ C below the melting point of the resulting by the specific attachment primer sequences, and usually corresponds to a temperature between 55 ° C to 65 ° C. When the annealing of the primers to the predetermined sites of the polynucleotide sequence is complete, filling in the PCR reaction step of elongation by the missing strands or building blocks on free nucleotides under the action of the polymerase. Here, the primer forms the beginning of a new single strand, which is replicated piece by piece. The temperature to be set during this PCR reaction step will depend on the labor optimum of the polymerase used in each case, but is typically at 10 ⁰ C to 15 ° C above the temperature level of primer hybridization. After completion of the PCR reaction step of the elongation, the reaction sequence is repeated, and the desired polynucleotide sequences increase exponentially in the best case, since in each further reaction step, the previously synthesized polynucleotide sequences can serve as templates for further strand synthesis. Real-time quantitative PCR, a refinement of PCR amplification known in the art, performs PCR amplification to replicate polynucleotide sequences while providing a means of quantifying the polynucleotide sequences so obtained. The quantification is based on the execution of fluorescence measurements that are made during the course of the PCR amplification. The detected fluorescence signal increases in proportion to the amount of replicated polynucleotide sequences. Accordingly, in contrast to most conventional quantitative detection methods, which can only be used after the PCR amplification, the real-time quantitative PCR allows a quantitative evaluation of the polynucleotide sequences which are replicated in the PCR amplification still during their amplification.

It should be noted that here and below a quantitative detection in the sense of quantification in connection with a real-time quantitative PCR is to be understood. This can be based on various known quantification models. In a simple case, for example, it is possible to use the fact that between the logarithm of the amount of polynucleotide sequence to be replicated and the CT (Threshold Cycle), ie the cycle to which the detected fluorescence for the first time significantly exceeds the background fluorescence is) there is a linear, inversely proportional relationship. For example, if the amount used is initially known, a standard curve can be generated against the slope of which any unknown amount of polynucleotide sequence can be compared and quantified. On the other hand, if the initial quantity is unknown, it is sometimes possible to deduce the initial quantity by determining the CT. Further calculation methods are known to the person skilled in the art.

The real-time quantitative PCR requires fluorescent dyes or so-called fluorescence markers, which interact chemically or physically with the replicated polynucleotide sequences, and as a result change their own fluorescence behavior. Accordingly, the increase in the intensity of a detected fluorescence signal after the repeating PCR reaction steps correlates with a corresponding increase in replicated polynucleotide sequences. For example, detection of the course of PCR amplification via measured fluorescence signals may rely on the use of simple fluorescent dyes that bind relatively non-specifically to the polynucleotide sequence to be replicated. Such fluorescent dyes are, for example, SybrGreen, which is an asymmetric cyanine dye molecule and, with DNA molecules to be replicated, contains a DNA fluorescent dye molecule. Complex forms, which absorbs blue light at a wavelength of λ _max - 494 nm and emits green light at a wavelength of λ _max = 521 nm. Another commonly used fluorescent dye is ethidium bromide. In addition to these fluorescent dyes, fluorescence markers such as FRET probes, Lightcycler probes, TaqMan probes, molecular beacons, Scorpion primers or Luxprimer® are also used, which indeed permit specific binding to individual sites of the polynucleotide sequence and consequently have narrowly defined fluorescence properties, but are comparatively more expensive. Consequently, such fluorescent markers are not widely used, as is typical for the fluorescent dyes. Furthermore, molecular beacons, for example, are relatively complex structures which additionally require optimized and therefore expensive primers for carrying out the PCR amplification. Furthermore, such complex structures make it difficult to optimize the PCR reaction conditions and thus promote a relatively inefficient amplification of the polynucleotide sequences as well as the preparation of many unwanted by-products.

To avoid these disadvantages of real-time quantitative PCR based on the detection of fluorescence signals, WO 03/102238 A2, which is known from the prior art, proposes a method for detecting the representation of contiguous nucleic acid molecules in a PCR solution, and also an arrangement to carry out the said method. The method comprises the provision of PCR starting materials in a chamber, as well as performing the repetitive PCR reaction steps of denaturation, primer hybridization and elongation. During the execution of these PCR reaction steps, the imaging of contiguous nucleic acid molecules is carried out by the irradiation of UV light into the PCR solution and the subsequent detection of the absorbed light intensity. The PCR solution is in this case taken up by a chamber adapted for carrying out a PCR amplification, into which the light energy of the UV light source is irradiated.

Although the method described in WO 03/102238 A2 makes the use of fluorescent labels unnecessary, this method is very susceptible to interference with respect to individual components of the PCR solution or with respect to remaining residues from reaction steps of previous isolation reactions, eg , As phenols. A further disadvantage of the quantitative determination by means of UV absorption can also be seen in the fact that only single-stranded of double-stranded nucleic acid molecules can be distinguished to a limited extent, and consequently only very unspecific detection capability for polynucleotide sequences is available. WO 2008/109706 A1 describes the use of terahertz spectroscopy in a great variety of types. The detection of double-stranded and single-stranded DNA is also described. A real-time method for the detection of the PCR product is described in this document in any way.

WO 2006/064192 A1 describes a band filter in the terahertz range. A method for the detection of nucleic acid molecules is not described in this document.

US 2006/0216742 describes a method and system for detecting biomolecular binding events using gigahertz or terahertz radiation.

WO 03/100396 A1 discloses a method for detecting the specificity of a ligand to a biological sample.

DE 100 54 476 A1 describes a method for the detection of polynucleotide sequences, in which the refractive index or an equivalent size of the sample in contact with the test medium is determined by interaction with incident electromagnetic radiation.

WO 2004/024949 A2 describes a method for the rapid detection of mutations and nucleotide polymorphisms using spectral data.

A more specific method of detecting the presence of biomolecular bonding between two molecules is proposed by US 2006/0216742 A1, which relates to a detection method and apparatus. According to the disclosure, terahertz radiation will detect the presence of biomolecular bonding of two molecules by emitting terahertz radiation from a source and detecting it by a detector after irradiation of a sample comprising the molecules. However, the disclosed method does not permit the quantification of employed amounts of the molecules, and thus is unsuitable for use in real-time detection in a PCR amplification.

It is therefore the object to propose a marker-free method for real-time detection of polynucleotide sequences in a PCR amplification, which is a specific and quantitative detection of polynucleotide sequences, in particular a distinction between single- and double-stranded Polynucleotidse-, allows, and is largely unaffected by the purity or quality of the solution.

This object is achieved by a method according to claim 1 and 15 and a PCR arrangement according to claim 14.

In particular, the object is achieved by a method for quantitative and spectroscopic real-time detection of nucleic acid molecules, in particular of polynucleotide tidsequenzen in a PCR amplification, the PCR amplification providing the necessary for the preparation of a PCR solution starting materials in a Buffer solution and the repetitive PCR reaction steps of denaturation, the primer hybridization and the elongation comprises, and wherein irradiated during defined PCR amplification at defined times from a radiation source electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime in the PCR solution to detect by means of a detector in a quantitative real-time detection at least the presence or absence of a polynucleotide sequence.

Furthermore, the object is achieved by a method for quantitative and real-time spectroscopic detection of nucleic acid molecules, in particular of polynucleotide sequences, in a PCR amplification, the PCR amplification providing the necessary for the preparation of a PCR solution starting substances in a buffer solution and the repetitive PCR reaction steps of denaturation, primer hybridization and elongation, and wherein during PCR amplification at defined times from a radiation source electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime in the PCR solution is irradiated to detect by means of a detector in a real-time detection at least the presence or absence of a polynucleotide sequence, and wherein the reaction step of the denaturation is effected by Tera-Hertz radiation from the radiation source.

Moreover, the object is achieved by a PCR arrangement for the quantitative spectroscopic real-time detection of polynucleotide sequences in a PCR amplification, wherein a substrate with a receiving area for a PCR solution consisting of the necessary starting substances and a buffer solution, temperature change means, by means of which the PCR solution can be heated to predetermined temperatures and / or cooled to the repeating PCR reaction steps of Denaturation, primer hybridization or elongation, a source of radiation to radiate electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime into the PCR solution, and a detector to quantitatively transmit radiation transmitted through the PCR solution to detect spectroscopically.

A central idea of the present methods and the PCR arrangement according to the invention is the execution of a PCR amplification and a spectroscopic real-time detection in the Giga-Hertz or Tera-Hertz regime of the electromagnetic spectrum. Typically used in this frequency range radiations are between 100 gigahertz and 20 terahertz, in particular between 300 gigahertz and 10 terahertz. These radiation frequencies are suitable for excitation of specific excitation states (typically vibrational vibrational modes) of single-stranded and double-stranded polynucleotide sequences. Excitation states of individual functional groups of these polynucleotide sequences are thus correlated to a predetermined frequency of the electromagnetic radiation and can be detected in absorbance measurements. In the following, extinction measurements generally refer to all spectroscopic detections, including quantitative ones, which relate parts of the light intensity irradiated into the PCR solution to parts of the light intensity emerging from it and detected by a detector in order to draw conclusions about substances and structures to be detected Allow PCR solution. These excitation modes (excitation frequencies) are also characteristic of the chemical bonding states of these functional groups, and may be accompanied by a change in the binding state with a change in the electromagnetic excitation frequency. In particular, excitation modes can be detected whose occurrence is characteristic of the presence of hydrogen bonds between the two single-stranded polynucleotide sequences in a double-stranded polynucleotide sequence. Accordingly, by means of extinction measurements in this designated frequency range, quantitative statements can be made as to whether a mixture of single-stranded or double-stranded polynucleotide sequences is present in a PCR solution.

The detection of predetermined states of excitation of polynucleotide sequences in a PCR solution by means of spectroscopic extinction measurements does not require any fluorescence markers which have to be added to a PCR solution in comparison with the hitherto conventional method of detection by means of fluorescence measurements. On the one hand, this makes the production of a PCR solution less complex and less expensive. On the other hand, can be dispensed with the use of the PCR solution sometimes harmful UV light. Especially through UV light, which is an electronic causes effects in biological macromolecules, the possible sources of error by chemical side reactions, which are sometimes initiated by the irradiation of UV light, very problematic. Electromagnetic radiation in the Giga-Hertz and Tera-Hertz regime, however, are typically able to cause only vibratory excitations and thus hardly interfere with the chemical reaction environment in a PCR solution in practical terms. Moreover, the radiation frequency of Giga-Hertz and Tera-Hertz radiation is suitable for detecting hybridization states of co-pendant nucleic acid molecules or polynucleotide sequences, respectively. Unlike in a real-time quantitative PCR method by means of fluorescence measurement in the UV regime, therefore, detections according to the method according to the invention can detect the presence of individual hybridization states, in particular the presence of single-stranded and double-stranded polynucleotide sequences. This quantitative detection, which is sometimes decisive for carrying out a PCR amplification, allows conclusions to be drawn regarding the progress and the quality of the reaction steps taking place in the PCR solution and thus an increase in the efficiency of the PCR amplification in general.

Another core idea of the method according to the invention is furthermore that the radiation source used for the spectroscopic real-time detection can also be used to bring about the reaction step of denaturation in the PCR amplification by electromagnetic radiation. In fact, the radiated frequency range is quite suitable for melting the hydrogen bonds between the two single strands in a double-stranded polynucleotide sequence, without having to add thermal energy directly to the entire system of the PCR solution. Thus, in the denaturing reaction step, there is no need to raise the temperature of a PCR solution to cause the melting of chemical bonds between individual strands of a polynucleotide sequence. Rather, by irradiating electromagnetic radiation of a predetermined frequency in the Giga-Hertz and Tera-Hertz regime into the PCR solution, the radiation source melts double-stranded polynucleotide sequences without the PCR solution itself having to undergo a strong temperature change. Such a method thus shortens the necessary for the repetitive PCR reaction steps heating and cooling phases of the PCR solution and allows a temporally faster representation of a desired amount of polynucleotide sequences to be amplified.

In a first embodiment of the method according to the invention, it is provided that the starting substances necessary for the preparation of a PCR solution are contained in a buffer. no chemical or physical detection markers, in particular no fluorescence markers. These are markers which are added as unnecessary starting substances for the preparation of a PCR solution described above, in order to be able to detect the preparation of polynucleotide sequences in a measuring method which is known from the prior art. The PCR solution provided for the method according to the invention can consequently be limited to the necessary starting substances, such as are necessary for ordinary PCR amplification without real-time detection. On the one hand, possible interferences of a chemical and physical nature in the process of PCR amplification are thus reduced, and at the same time the controllability of the reaction conditions is increased.

In a further embodiment it can be provided that the intensity of the irradiated electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime is selected such that it penetrates a predetermined layer thickness of the PCR solution. In this case, the layer thickness can relate either to the entire sample cross section, which is penetrated by the irradiated electromagnetic radiation, or else only to a partial region of the sample cross section. The layer thickness is suitable for detecting an extinction signal upon irradiation of a given radiation intensity and the presence of a number of polynucleotide sequences above a certain detection threshold. The extinction signal, which results from attenuation of the electromagnetic radiation intensity, may result from absorption, scattering, diffraction, and reflection, for example. If the irradiated layer thickness is constant and the irradiated electromagnetic radiation is immutable in its intensity, it is possible to deduce the amount of polynucleotide sequences shown, for example, if the extinction cross section of the polynucleotide sequences is known.

In a further embodiment of the method, it is provided that the frequency of the irradiated electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime is between 100 GHz and 20 THz, in particular between 300 GHz and 10 THz. These frequency ranges cover the spectroscopically easily detectable excitation frequencies of most polynucleotide sequences and thus allow the excitation vibrations to be detected spectroscopically, in particular spectroscopically quantitatively.

In a further advantageous embodiment of the invention, it is provided that the buffer solution of the PCR solution with respect to a frequency of the radiated electromag- is selected in the Giga-Hertz or Tera-Hertz regime so that the radiation intensity after transmission of a predetermined layer thickness of the PCR solution with the detector can be detected largely unattenuated. The buffer solution itself is thus selected with respect to the electromagnetic radiation frequencies used so that the irradiated electromagnetic radiation of predetermined frequency ranges undergoes the greatest possible transmission. If these frequency ranges overlap with excitation states of the polynucleotide sequences to be detected, it is ensured that a reduction in the electromagnetic radiation intensity after interaction with the PCR solution is not based on the extinction behavior of the buffer solution itself, but only on the starting substances and with the molecules shown. If an extinction by by-products of the PCR amplification can furthermore be ruled out, the attenuation of the electromagnetic radiation intensity in the regions of the excitation states of the polynucleotide sequences is based largely solely on the interaction of the electromagnetic radiation with the polynucleotide sequences. The ratio of useful signal and unwanted attenuation of the electromagnetic radiation is increased as a result, and the quality of the quantitative spectroscopic real-time detection improved.

In a further embodiment of the method, this is characterized in that the PCR solution is applied to a substrate, in particular in a predetermined receiving area of the substrate, which is largely transparent to the radiated electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime is. Such a receiving area may be formed by a limited volume, or merely as a surface for applying a PCR solution. The substrate itself may be a mineral substrate, for example glass, or else a plastic substrate. If the substrate itself is largely transparent to the incident electromagnetic radiation, it causes only a small proportion of the extinction signal detected in the spectroscopic real-time detection method. The proven extinction is therefore based largely on the interaction of the electromagnetic radiation and the PCR solution, or the substances contained therein, if the buffer solution of the PCR solution itself also causes no or only slight attenuation of the radiation intensity in the frequency range of the irradiated electromagnetic radiation. Furthermore, the substrate, if it is a plastic, can be adapted by the selection of a suitable plastic to the useful frequency range of the irradiated electromagnetic radiation in order to bring about the lowest possible attenuation of the radiation intensity. In a further embodiment of the method, the substrate comprises at least one electromagnetic radiation waveguide in the Giga-Hertz or Tera-Hertz regime. This waveguide can on the one hand serve as a radiation guiding means and at the same time as a substrate with a possible receiving area for the PCR solution. Accordingly, the irradiation of electromagnetic radiation into the PCR solution can be done locally in a well-controlled manner. In addition, the scattered radiation or loss radiation, as occurs in conventional collimation and focusing methods, can be reduced and the spectroscopic real-time detection can be improved. Particularly advantageously, a waveguide can be used if the predetermined receiving area for the PCR solution is located in an area which is penetrated by the evanescent radiation field of the waveguide. Detection of the polynucleotide sequences thus takes place with electromagnetic radiation which is guided on the one hand through the waveguide but on the other hand communicates with regions of the surface outside the waveguide.

In a further embodiment of the method for spectroscopic real-time detection, further temperature-changing means are provided, by means of which the PCR solution can be heated to predetermined temperatures and / or cooled. Such temperature change agents may either directly or indirectly heat or cool the PCR solution. A direct increase in temperature can be based, for example, on direct radiant heating or resistance heating. Cooling can be effected, for example, by suitably arranged Peltier elements or else by a cooling medium, for example air, which is in communication with a heat exchanger. The temperature change means ensure that the fastest possible and exact change of the temperatures necessary for the individual PCR reaction steps is made possible.

In a further embodiment of the method, it is provided that the temperature-changing means heat and / or cool a heat medium which indirectly heats and / or cools the PCR solution via the substrate. It should also be noted that the heat capacity of the substrate itself is low and the thermal conductivity is as large as possible. According to the embodiment, the heat medium can interact in a planar manner, or else penetrate it in guide means provided for this purpose, for example in channels. By means of the heating or cooling of the substrate, the temperature of the PCR solution is correspondingly changed with suitable contact of the PCR solution with the substrate. Consequently, the temperature conditions necessary for the course of the PCR reaction steps can be ensured. In an advantageous embodiment of the method it is provided that electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime from the radiation source into the PCR solution before and / or after a step of denaturation, and / or the primer hybridization and / or the elongation is radiated. Accordingly, the initial conditions and reaction successes can be checked by means of spectroscopic detection after each of the reaction steps taking place in the PCR amplification. Should it prove, for example, that the starting conditions for a subsequent PCR reaction step are unfavorable, appropriate changes in the reaction conditions, for example in the choice of temperature, can be made in order to bring about improved success. In an alternative embodiment, the electromagnetic radiation in the Giga-Hertz or Terahertz regime can be irradiated during the PCR amplification reaction steps of denaturation, primer hybridization or elongation, for example, to draw conclusions on the temporal binding behavior of individual molecular building blocks ,

In a particularly advantageous embodiment of the method, the frequency of the electromagnetic radiation is selected to excite defined vibratory excitation modes of single- and / or double-stranded polynucleotide sequences in order to detect these, in particular the modes characteristic of the presence of hybridization states of double-stranded polynucleotide sequences. Thus, during PCR amplification, the presence of certain molecular structures of the polynucleotide sequences can be detected by which the quality of the PCR amplification process can be verified and detected. Furthermore, termination of the PCR amplification can also be initiated after detection of the polynucleotide sequences. In particular, a conclusion on the structure of the polynucleotide sequences, in particular on their hybridization state, can also be obtained by detecting the shift in the excitation frequency of defined excitation modes.

In a further embodiment of the invention, temporally preceding proofs by means of the electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime are taken into account during the PCR amplification as a background for subsequent detection in the analysis of the evidence. The time-preliminary evidence may be subtracted from subsequent evidence for background subtraction, which is indispensable in absorbance measurements, either directly, averaged, or filtered. This for obtaining quantitative results The necessary step of the subsoil subtraction thus requires no further prior knowledge of the specific extinction behavior of the PCR arrangement, but allows a good background determination in a timely manner.

In a further embodiment of the method for the spectroscopic real-time detection of polynucleotide sequences, electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime is generated from the radiation source prior to performing a PCR amplification in a solution of starting substances to be used in the PCR amplification irradiated to determine chemical or physical properties of individual starting materials, in particular their quality, specificity and their binding behavior, by means of spectroscopic evidence. It should be mentioned here that, prior to performing a real-time quantitative PCR, most users of PCR amplifications typically have the quality or specificity and their binding behavior (quality of the polynucleotide sequences, primer binding, primer specificity, amounts of amplification) for cost reasons in a PCR reaction. Device that does not support the possibility of real-time spectroscopic detection using fluorescence measurements. Accordingly, according to an embodiment of the method according to the invention, this separate verification can be dispensed with, and the physical and chemical properties of individual starting substances can be determined directly by means of a PCR arrangement according to the invention. Furthermore, the primers typically used in PCR amplifications are designed for use in ordinary PCR assemblies without spectroscopic real-time detection, and require use in a PCR array with real-time spectroscopic detection based on the use of Fluoreszenzmarken a new optimization of the reaction conditions for the primer-containing PCR solution with fluorescent markers. This re-optimization is usually necessary because the addition of fluorescent labels affects the melting points of the polynucleotide sequences and thus the primer binding. If the primer binding or primer specificity can be determined beforehand in a PCR arrangement in which the spectroscopic real-time detection of polynucleotide sequences with Giga-Hertz or Tera-Hertz radiation is carried out at a later time, elaborate optimization efforts are therefore no longer necessary.

Furthermore, it should also be noted that the reaction vessels used in fluorescence measurements in the UV regime due to contamination, such as fingerprints, can easily give rise to erroneous measurements and this can sometimes result in incorrect absorption values. Electromagnetic radiation in the Giga-Hertz or Te Because of the longer wavelength, the ra-Hertz regime is much less sensitive to such contamination of the reaction vessels as well as the buffer solution components. In addition, according to the present method eliminates the use of spoiled or inaccurately prepared fluorescent dyes as a possible source of error for spectroscopic detection.

Further embodiments of the invention will become apparent from the dependent claims.

The invention will be described with reference to embodiments, which are explained in more detail with reference to the figures.

Hereby show:

1 is a flowchart for illustrating the time sequence of individual

Steps in a method for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification according to a first embodiment of the invention;

2 shows a schematic representation of the extinction behavior of a PCR solution in the course of a PCR amplification at radiation frequencies which coincide with excitation states of predetermined polynucleotide sequences in a PCR solution;

3 shows a partial view of a schematic representation of a second embodiment of the PCR arrangement according to the invention;

4 shows a partial view of a third embodiment of a PCR arrangement according to the invention;

5 shows a partial view of a fourth embodiment of a PCR arrangement according to the invention;

6 shows a partial view of a fifth embodiment of a PCR arrangement according to the invention;

7 shows a sixth embodiment of a PCR arrangement according to the invention, which is based on the partial view of the fourth embodiment shown in FIG. 5; 8 shows a schematic representation of the extinction behavior of a buffer solution used for producing a PCR solution and of a polynucleotide sequence in the frequency regime of the Giga-Hertz and / or Tera-Hertz regime.

1 shows a schematic flow diagram of the typical sequence of an embodiment of the method according to the invention for the spectroscopic real-time detection of polynucleotide sequences 10 in a PCR amplification. In such a method, it first requires the provision of a buffer solution 13 in which the starting substances necessary for the preparation of a PCR solution are taken up or dissolved. Necessary starting materials 12 are the polynucleotide sequence 10 to be replicated, suitable primers, a polymerase, and deoxynucleoside triphosphates for synthesizing polynucleotide sequences. Already before the preparation of the PCR solution 11, the quality, specificity and the formation behavior of individual starting substances 12 can be determined in a spectroscopic real-time detection. This proof takes place at a time shown in FIG. 1 at 1 time. After preparation of the PCR solution 11, further spectroscopic real-time detection of the PCR solution 11 can be carried out again (time 2). Only then takes place by the repetition of the PCR reaction steps of denaturation, primer hybridization, and elongation replication of the polynucleotide sequences to be replicated, wherein after each completed PCR reaction step spectroscopic real-time evidence can be performed (times 3, 4 and 5) , Here, excitation states of the single-stranded polynucleotide sequences are preferably measured after the PCR reaction step of denaturation (time point 3), whereby excitation states of double-stranded polynucleotide sequences are suitably measured after the PCR reaction step of elongation (time point 5). Spectroscopic real-time proofs can thus be carried out during the entire sequence of the PCR amplification by means of the method according to the invention, and the time course of the polynucleotide sequences occurring in the PCR amplification can also be quantitatively characterized. Furthermore, it is of course also possible to carry out spectroscopic detection measurement after the end of the PCR amplification.

If according to an aspect of the present method, the PCR reaction step of the denaturation by irradiation of electromagnetic radiation in the Tera-Hertz regime are effected, this method would be a radiation of appropriate electromagnetic radiation at the time of denaturation. Fig. 2 shows a schematic representation of the Extinktionsverlaufes in a PCR solution, which can be determined spectroscopically according to an embodiment of the present invention with electromagnetic radiation in the Giga-Hertz or Tera-Hertz regime. The frequency of the irradiated electromagnetic radiation is chosen so that it coincides with the frequency of predetermined excitation states of individual polynucleotide sequences and is attenuated by appropriate irradiation in the PCR solution of these. Since, in a PCR amplification, the number of polynucleotide sequences to be replicated is typically increasing exponentially in time, the measurement points of spectroscopic real-time extinction evidence lie on an exponential curve. In the present case, the individual proofs of the extinction of the PCR solution are illustrated by crosses. The time course is determined according to physical as well as chemical parameters, which can influence the efficiency or speed of the PCR amplification. From the extinction measurements, the amount of specific polynucleotide sequences can subsequently be determined by computational method.

In the practical implementation of spectroscopic real-time detection of polynucleotide sequences during the PCR amplification, it is found that only those detections above a predetermined detection threshold D ₁ provide clear detection results, which can also be used for further evaluation. Detection values below this detection threshold D ₁ are only of a theoretical nature since the signal-to-noise ratios do not permit any definite extinction determinations. The earliest time T ₁ for a clear spectroscopic real-time detection thus occurs when the measured absorbance is above the detection threshold D ₁ . By a suitable frequency selection of the irradiated electromagnetic radiation, it can be achieved that a detection threshold D _{2 is} as low as possible and below which the detection threshold D _{1 is} for electromagnetic radiation of other frequencies. Consequently, fewer PCR reaction steps must be performed than in conventional real-time quantitative PCR methods. Furthermore, the earliest time T _{2 is} as low as possible, in particular shorter than T ₁ for electromagnetic radiation of the other frequencies.

3 shows a partial view of a schematic representation of an embodiment of a PCR arrangement according to the invention for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification. According to this embodiment, a radiation source 20 emits electromagnetic radiation in the gigahertz and / or Tera-Hertz regime in a PCR solution 11. The PCR solution 11 is located in the receiving region 23 of a substrate 24, which defines by its formation the layer thickness S of the PCR solution through which the electromagnetic radiation 21 passes. Such a receiving region 23 is presently formed by an at least partially limited volume, such as a container. The frequency of the radiation is set such that it coincides with the frequency of predetermined excitation states in the PCR solution 11 located polynucleotide sequences 10. After transmission of the irradiated electromagnetic radiation 21 through the cross section of the receiving region 23, the correspondingly weakened intensity of the electromagnetic radiation 21 is detected by a detector 22.

In the present case, it has been omitted to specify the optical elements typical of the optical structure, such as focusing elements, collimation elements, beam guiding elements and filters. The additional provision of such conventional beam conditioning optical elements will be apparent to those skilled in the art.

4 shows a further partial view of an embodiment of a PCR arrangement for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification. In contrast to the receiving region 23 of the first embodiment according to FIG. 3, the second embodiment according to FIG. 4 does not provide a double-walled receiving region 23, but only a single-walled one, to which the PCR solution 11 is accommodated. This may be, for example, a film application of a PCR solution to the receiving region 23 of the substrate. Furthermore, the arrangement of the PCR solution 11 on the receiving region 23 of the substrate 24 in the field of gravity can be oriented so that a constant layer thickness S can be ensured during the spectroscopic real-time detection. In addition, the receiving region 23 of the substrate 24 may still contain constructive arrangements which increase the adhesion between the PCR solution 11 and the receiving region 23 of the substrate 24. Such arrangements are, for example, fine surface structures which assist in adhering the PCR solution 11 to the substrate 24.

5 shows a partial view of a fourth embodiment of the PCR arrangement according to the invention for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification. In this case, the direction of the electromagnetic radiation 21 emitted from the radiation source 20 and the direction of the radiation detected by the detector 22 are not arranged in extension to one another. Rather, the electromagnetic radiation 21 from the PCR solution 11 and / or the substrate of the Receiving area 23 deflected such that no straight line of rays takes place. Such a beam path is advantageous, for example, in the case of scatter measurements. Such a relative arrangement of radiation source 20 and detector 22 may also contribute to an improved spatial arrangement of various components, which contributes to reducing the overall size of the PCR assembly of the invention.

In comparison with the embodiments of the free beam path of the electromagnetic radiation 21 in the illustrations according to FIGS. 3 to 5, in the partial view of the embodiment according to FIG. 6 the electromagnetic radiation 21 is guided in a waveguide W suitable for the frequency range of the radiation. Here, the electromagnetic radiation 21 can be coupled directly to the radiation source 20 in the waveguide W or only after suitable conditioning. Accordingly, the waveguide W can be directly connected to the detector 22 or the radiation can only be conditioned for detection by means of the detector 22. The waveguide W is designed to emit in the receiving region 23 electromagnetic radiation 21 as an evanescent radiation field, which consequently can cause an extinction of the electromagnetic radiation 21 through the interaction with a waveguide W externally applied PCR solution. The embodiments of the waveguide W may comprise insulated waveguide structures, or else waveguide sections integrated into further recording devices. In a preferred embodiment, the waveguide W is integrated in a chip construction.

FIG. 7 shows an embodiment of a PCR arrangement based on the partial view of the fourth embodiment in FIG. 5 for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification, which as a further element represents the temperature change means 25 associated with the Substrate 24 of the receiving area

23 interacts. The temperature changing means 25 are adapted to the substrate

24 to heat on the side and / or to cool, which is opposite to the side of the receiving area 23 for receiving the PCR solution 11. By changing the temperature of the substrate 24 is carried out by appropriate heat conduction, a temperature change of the PCR solution 11. The thermal resistance of the substrate 24 is low, and the heat and / or cooling capacity of the temperature change means 25 compared to the heat capacity of the applied PCR solution 11 large , A relatively rapid change in temperature of the PCR solution 11, and a rapid sequence of repetitive PCR reaction steps can be ensured. For improved heat conduction means may be provided between the temperature changing means 25 and the substrate 24, which support a heat conduction. In one embodiment of the invention, According to the PCR arrangement according to the invention, the temperature changing means 25 can heat and / or cool an air flow which is conducted directly to the substrate 24 and, after appropriate heat conduction through the substrate 24, changes the temperature of the PCR solution 11 accordingly.

FIG. 8 shows the extinction behavior 13 'of the buffer solution 13 necessary for producing the PCR solution 11 and the extinction behavior 10' of predetermined excitation states of the polynucleotide sequence 10 to be detected in a frequency range of the Giga-Hertz or Tera-Hertz regime. Due to its refractive behavior, the extinction of the buffer solution 13 varies detectably over a predetermined frequency range. Many standard laboratory buffer solutions 13 have such an extinction behavior. For the lowest possible possible detection of an excitation state of a polynucleotide sequence 10, it may be necessary to select a buffer solution 13 which has a minimum of its extinction behavior in the frequency range of the designated excitation state of the polynucleotide sequence 10. Accordingly, the absorbance of the electromagnetic radiation 21 irradiated into the PCR solution 11 by the buffer solution 13 is small as compared with the absorbance by the polynucleotide sequences 10 in the PCR solution 11, and the detection of the extinction of the excited state of the polynucleotide sequence 10 is performed with little interference by the Buffer solution 13. By appropriate choice or adjustment of the buffer solution 13 to the polynucleotide sequence 10 to be detected and its excitation frequency, a favorable signal to noise ratio can be achieved.

It should be noted at this point that all the above-described parts taken alone and in any combination, in particular the details shown in drawings are claimed as essential to the invention. Changes are familiar to the person skilled in the art.

Reference numerals:

10 polynucleotide sequence

10 'Extinction of the excited state of a polynucleotide sequence

11 PCR solution

12 starting substance

13 buffer solution

13 'Extinction of the buffer solution 14 markers

20 radiation source

21 Electromagnetic radiation

22 detector

23 recording area

24 substrate

25 temperature change means

26 heat medium

S layer thickness

W waveguide

D ₁ detection threshold

D ₂ detection threshold

T earliest time for detection

Claims

25Ansprüche

1. A method for the spectroscopic real-time detection of nucleic acid molecules, in a PCR amplification, wherein the PCR amplification, the provision of the necessary for the preparation of a PCR solution (11) starting materials (12) in a buffer solution (13) and the repetitive PCR reaction steps of denaturation, primer hybridization and elongation, and wherein during PCR amplification at defined times from a radiation source (20) electromagnetic radiation (21) in the Giga-Hertz or Terahertz regime in the PCR solution (11) is irradiated in order to detect by means of a detector (22) in a real-time detection at least the presence or absence of a polynucleotide sequence (10).

2. A method according to claim 1, characterized in that the nucleic acid molecules are polynucleotide sequences.

3. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to claim 1 or 2, characterized in that that for the preparation of the PCR solution (11) necessary starting substances (12) in a buffer solution (13) no chemical or physical detection markers (14), in particular no fluorescence markers.

4. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the intensity of the irradiated electromagnetic radiation (21) in the Gigahertz or Tera-Hertz regime is selected in that it penetrates a predetermined layer thickness (S) of the PCR solution (11). 26

5. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the frequency of the irradiated electromagnetic radiation (21) in the Gigahertz or Tera-Hertz regime between 100 GHz and 20 THz, in particular between 300 GHz and 10 THz.

6. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the buffer solution (13) of the PCR solution (11) with respect to a frequency of the irradiated electromagnetic radiation (21) is selected in the Giga-Hertz or Tera-Hertz regime so that the radiation intensity after transmission of a predetermined layer thickness (S) of the PCR solution with the detector (22) can be detected largely unattenuated.

7. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the PCR solution (11) on a substrate (24), in particular in a predetermined receiving area (23 ) of the substrate (24) is applied, which is largely transparent to the irradiated electromagnetic radiation (21) in the Giga-Hertz or Tera-Hertz regime.

8. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to claim 7, characterized in that the substrate (24) at least one waveguide (W) for electromagnetic

Radiation in the Giga-Hertz or Tera-Hertz regime.

9. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to any one of the preceding claims, characterized in that further temperature change means (24) are provided, by means of which the PCR solution (11) heated to predetermined temperatures and / or can be cooled. 27

10. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to claim 9, characterized in that the temperature changing means (24) heat and / or cool a heat medium (26), which via the substrate the PCR Solution (11) directly or indirectly heats and / or cools.

11. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the electromagnetic radiation (21) in the Giga-Hertz or Tera-Hertz regime from the radiation source (20 ) is irradiated into the PCR solution (11) before and / or after a step of denaturation, and / or primer hybridization and / or elongation.

12. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the frequency of the electromagnetic radiation is selected to defined vibrational excitation modes of single and / or double-stranded polynucleotide sequences (10 ) to detect these, in particular the modes characteristic of the presence of hybridization states of double-stranded polynucleotide sequences (10).

13. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that during the PCR amplification in advance of time by means of the electromagnetic radiation (21) in the Giga-Hertz or Tera-Hertz regime as background for subsequent proofs in an analysis of the evidence to be considered.

14. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification according to one of the preceding claims, characterized in that the electromagnetic radiation (21) in the Giga-Hertz or Tera-Hertz regime from the radiation source (20 ) before performing a PCR amplification in a solution 28

of starting substances to be used in the PCR amplification (12) is irradiated in order to determine chemical or physical properties of individual starting substances (12), in particular their quality, specificity and their binding behavior, by means of spectroscopic detection.

15. A PCR arrangement for the spectroscopic real-time detection of polynucleotide sequences in a PCR amplification, these

- A substrate (24) having a receiving area (23) for a PCR solution (11), consisting of the necessary starting substances (12) and a buffer solution (13),

Temperature change means (24) by means of which the PCR solution (11) can be heated and / or cooled to predetermined temperatures in order to enable the repetitive PCR reaction steps of denaturation, primer hybridization or elongation,

a radiation source (20) for irradiating electromagnetic radiation (13) in the Giga-Hertz or Tera-Hertz regime into the PCR solution (11),

- And a detector (22) to detect by the PCR solution (11) transmitted radiation spectroscopy includes.

16. A method for the spectroscopic real-time detection of nucleic acid molecules in a PCR amplification, the PCR amplification providing the necessary for the preparation of a PCR solution (11) starting materials (12) in a buffer solution (13) and which comprises repeating PCR reaction steps of denaturation, primer hybridization and elongation, and wherein during the PCR amplification at defined times from a radiation source (20) electromagnetic radiation (21) in the Giga-Hertz or Terahertz regime in the PCR solution (11) is irradiated to detect by means of a detector (22) in a spectroscopic real-time detection at least the presence or absence of a polynucleotide sequence (10), and wherein the reaction step of denaturation by Tera-Hertz radiation from the radiation source (20) is effected.

The method of claim 16, wherein the nucleic acid molecules are polynucleotide sequences.