EP4363607A1 - Method for placing a partition cohort of a microfluidic, in particular biological sample - Google Patents

Abstract

The invention relates to a method (500) for placing a partition cohort of a microfluidic, in particular biological sample in partitions (110, 120) on a partition surface (101), in particular to determine a concentration of an analyte in the sample. The invention further relates to an analysis method (600) for detection of an analyte in a microfluidic sample and to a method (700) for preparing a partition cohort of a microfluidic sample.

Description

description

title

Method for designing a partitioning of a microfluidic, in particular a biological sample

State of the art

Microfluidic analysis systems (so-called lab-on-chips, LoCs for short) allow automated, reliable, fast, compact and cost-effective processing of patient samples for medical diagnostics. By combining a multitude of operations for the controlled manipulation of fluids, complex molecular diagnostic test sequences can be carried out on a lab-on-chip cartridge.

In the case of the implementation of a partition-based quantitative test method, in particular with a so-called digital polymerase chain reaction (digital PCR for short) in such a LoC, one of these operations consists in aliquoting the sample into a large number of partitions.

These can be implemented as chambers or drops, for example. Within each of these partitions, an end point amplification of the specific DNA target takes place independently of one another, which results in an increase in fluorescence if at least one target was located in the respective partition at the beginning of the amplification reaction. Starting from the proportion of partitions that show an increase in fluorescence, the target concentration in the analyzed sample can be deduced by using Poisson statistics.

During the aliquoting process, various sources of error affect the accuracy of the quantitative detection. The fluctuations in the concentration of the examined sub-volume dominate (so-called subsampling error) and the statistical inaccuracy caused by the aliquoting process itself (so-called partitioning error). Both of these mechanisms have already been described in the literature (Dube et al., PLoS ONE 3 (8), e2876 (2008), 10.1371/journal.pone.0002876; Jacobs et al., BMC Bioinformatics 15, 283 (2014), https ://doi.org/10.1186/1471-2105-15-283;

Bizouarn F (2014) Introduction to Digital PCR. In: Biassoni R., Raso A. (eds) Quantitative Real-Time PCR. Methods in Molecular Biology (Methods and Protocols), vol 1160. Humana Press, New York, NY. https://doi.org/10.1007/978-l-4939-0733-5_4; Basu, Amar S. (2017): Digital Assays Part I: Partitioning Statistics and Digital PCR. in SLAS technology 22 (4), pp. 369-386. DOI:

10.1177/2472630317705680). The general recommendation is to reduce the partitioning error by using the largest possible number of partitions in order to increase the dynamic measuring range of the analysis system. The subsampling error is generally negligible and, according to the literature, only plays a significant role if the proportion of the volume analyzed is below 30% or 50%, depending on the application (Jacobs et al., BMC Bioinformatics 15, 283 (2014), https https://doi.org/10.1186/1471-2105-15-283). In addition, the advantage of the highest possible number of partitions is emphasized.

Disclosure of the Invention Advantages of the Invention

Against this background, the invention relates to a method for designing a partitioning of a microfluidic sample into partitions on a partition surface. In particular, the invention also relates to a method for partitioning, dividing or aliquoting such a sample into partitions or subsets of the sample. The method can be used in particular for determining a concentration of an analyte in the sample, in particular in combination with a digital PCR in the case of nucleic acid sections as analytes.

A partitioning of a sample can thus be understood as a division or aliquoting of a sample into sample parts, in a preferred embodiment an actual placement of the sample in the form of sample parts on the partition area. The sample can in particular be a biological sample, for example comprising a body fluid such as blood, urine, sputum or a smear. In addition to the body fluid, the sample can also contain other substances, for example in the form of a mixture of the body fluid with a transport medium such as eNAT™ or UTM™. The analyte, also called target, can be a molecule in the sample, in particular a nucleic acid segment, for example part of a DNA or RNA of a pathogen or a specific body cell, in particular a tumor cell. In a particular embodiment, the analyte can also be cells, in particular protozoa or animal or human body cells, for example one or more of what are known as circulating tumor cells (CTC for short). As already mentioned, the method according to the invention can thus be part of or a prerequisite for a partition-based quantitative detection method for analytes in the sample, for example with the aid of a digital PCR, with such a detection method being used in the case of microfluidic samples preferably with a microfluidic device, in particular a lab-on-chip system, can be carried out. By the With the method according to the invention, a partitioning of the sample can advantageously be implemented for a statistical estimation of a concentration of the analyte in the sample with a low relative error.

In a preferred embodiment, the method for designing a partitioning comprises a partitioning of the sample on the partition area according to the invention. The partition surface can generally be part of a microfluidic device, preferably part of a microfluidic cartridge. For example, the partition surface can be a surface on a substrate in a chamber of the microfluidic device.

According to a first step of the method, a geometric shape of the partitions, a shape of the partition area and a total volume of the sample are defined. The partition area can, for example, have a square or rectangular shape and optionally be surrounded by a delimiting wall. The partitions can preferably be in the form of droplets or chambers. In the case of the droplets, these are present in particular as an emulsion, for example as water-based droplets in an oil emulsion, it being possible for the droplets to be stabilized preferably by adding surface-active substances, so-called surfactants. In the case of chambers, the chambers can have a round or angular base, preferably a hexagonal base. The chambers are separated from one another by walls, the walls preferably being made as thin as possible in order to block as little surface as possible. The walls are preferably taken into account in the geometric shape of the chambers.

In a further step of the method, a minimum partition measure of the partitions is determined. A minimum partition size is a size, that is to say a representative and preferably unique value, for the size of the partition, in particular for the volume of the partition. In particular, the partition dimension can be the diameter of the partition in the case of a spherical or teardrop-shaped partition or the width of the chamber in the case of partitioning into chambers with an angular, for example square or hexagonal, base area. For example, the partition dimension is the distance between two opposite corners, preferably the minimum center distance of the partitions. A maximum number of partitions with a minimum partition size that can be arranged on the partition area results implicitly from the minimum partition size. This maximum number is also referred to below as the first number of partitions and is a measure of a minimum value of the partitioning error because the statistical inaccuracy of the concentration determination of the entire partitioned volume of the sample decreases with an increasing number of partitions. A partitioning design with as many partitions as possible and a correspondingly small partition size is referred to below as a minimal variant.

According to a further step of the method, a second partition measure of the partitions and thus a second number of partitions is determined under the condition that a maximum possible proportion of the total volume can be partitioned on the partition area and under this condition the maximum possible proportion on as many partitions as possible on the Partition area is divided. This has the advantage that the more of the total volume that can be partitioned, the lower the subsampling error. However, the number of partitions should be kept as large as possible in order to achieve the lowest possible partitioning error. This second partition size is also referred to below as the maximum partition size d _max and, however, represents the smallest possible partition size given the maximum partitioned total volume. The number of partitions at the maximum partition size is also referred to below as the second designated. A design of a partitioning, in which the complete total volume of the sample is partitioned as far as possible and a correspondingly larger partition size is selected, is referred to as the maximum variant in the following as a distinction from the minimum variant. In particular, this step can also be carried out before the previous step.

In a next step of the method, a first uncertainty of a measurable concentration of the analyte is determined when using a partition measure from a first range around the minimum partition measure and a second uncertainty of the measurable concentration is determined Using a partition measure from a second range around the second partition measure. The first and second uncertainties can preferably be relative uncertainties. These determinations advantageously determine whether a design according to the minimum or maximum variant is better with regard to the smallest possible measurement error of the concentration. The first range is preferably defined such that the first range includes the minimum partition metric, preferably as the lower end of the first range, and does not include the second partition metric. The second range is preferably defined such that the second range includes the second partition measure, preferably as the upper end of the second range, and does not include the minimum partition measure. In a particular embodiment, the first area and the second area can be two mutually non-overlapping areas, ie in particular disjunctive areas.

According to a special development of this step of the method, the first uncertainty of a measurable concentration of the analyte is determined when using the first partition number of partitions with the minimum partition measure and the second uncertainty of the measurable concentration is determined when using the second partition number of partitions with the second partition measure. Preferably, the first uncertainty and/or the second uncertainty are determined at a value from the maximum theoretical range for a measurement of the concentration of the analyte. This maximum theoretical range is from -log(11 /A _max )/V _par to -log(1-( A _max -1)/A _max )/V par, where A _max is the first partition number, V _par is the capacity/volume of a single partition and log denotes the natural logarithm. In order to preferably generate two measuring ranges of the same size, the center point of this range on a logarithmic scale is selected as the value, which is at (log(ll/A _max ) * log(l-( A _max -l)/A _max )) ^A 0.5 /V _Par lies.

According to a particular embodiment of the method, the partitions are designed with a partition measure from the first range, preferably with the minimum partition measure, if a measurement of a concentration of the analyte at a predetermined concentration value is carried out when the Partitions with a partition size from the second range, in particular with the second partition size, is not possible. The predetermined concentration value can preferably be a value from the maximum theoretical range described above, preferably around the midpoint of this range on a logarithmic scale, described above.

In a next step of the method, the partitions are designed from the first area or from the second area depending on a comparison of the first uncertainty with the second uncertainty. This has the advantage that uncertainties for a subsequent concentration measurement can be taken into account for the selection of the partition measure and thus for the specific form of the design of the partitions.

In particular, the minimum variant or maximum variant can be selected on the basis of these ascertained uncertainties.

In a particular embodiment of the method, the partitions are designed with a partition measure not equal to the maximum partition measure if the first uncertainty is less than the second uncertainty, and the partitions are designed not equal to the minimum partition measure if the first uncertainty is greater than or equal to the second uncertainty is big. In this embodiment, the first area thus includes all feasible partition dimensions with the exception of the second/maximum partition dimension and the second area thus includes all feasible partition dimensions with the exception of the minimum partition dimension.

In a further special embodiment of the method, the partitions are designed with a partition measure from the first range if the first uncertainty is smaller than the second uncertainty, and the partitions are designed with a partition measure from the second range if the first uncertainty is greater than the second uncertainty or equal. A range (optionally modified compared to the previous step of the method) can preferably be selected as the first range in such a way that the range only includes partition dimensions whose associated, preferably relative, uncertainty of the measurable concentration is smaller than the preferably relative uncertainty of the measurable concentration Choice of second/maximum partition measure. Analogously, a range (optionally modified compared to the previous step) can preferably be selected as the second range in such a way that the range only includes partition dimensions whose associated, preferably relative, uncertainty of the measurable concentration is smaller than the preferably relative uncertainty of the measurable concentration when selecting the minimum partition size. This has the advantage that a partition measure of the minimum variant is selected, with which the relative uncertainty is always smaller than when the maximum variant is selected, and vice versa.

In a further special embodiment of the method, the partitions are designed as a first partition number of partitions with the minimum partition measure if the first uncertainty is smaller than the second uncertainty, or as a second partition number of partitions with the second/maximum partition measure if the first uncertainty is greater than or equal to the second uncertainty.

As stated above, the method can be part of an analysis method for detecting an analyte in a microfluidic sample. The subject matter of the invention is therefore also such an analysis method, in which the sample is divided into partitions according to the invention and in which at least one partition is examined for the presence of the analyte. The analysis method preferably includes carrying out a digital PCR with at least some of the partitions.

The subject matter of the invention is also a method for producing a partitioning of a microfluidic sample. A partition area is provided and the sample is partitioned according to the design method according to the invention. The manufacturing method may preferably include manufacturing compartments for partitioning on the partition surface.

Brief description of the drawings

Embodiments of the invention are shown schematically in the drawings and explained in more detail in the following description. For those in the Elements that are shown in different figures and have a similar effect are given the same reference symbols, with a repeated description of the elements being dispensed with.

Show it

FIG. 1 shows a flowchart of an exemplary embodiment of the method according to the invention for designing a partitioning,

FIGS. 2a, 2b show a schematic representation of a partitioning of a sample onto a partition surface in the form of droplets or in the form of chambers filled with sample parts,

Figure 3 Diagrams with exemplary calculations of relative

Uncertainties of different concentrations of an analyte in the sample depending on a selected partition measure for the partitions,

FIG. 4 shows a flowchart of an exemplary embodiment of the analysis method according to the invention for detecting an analyte in a microfluidic sample and

FIG. 5 shows a flow chart of an exemplary embodiment of the manufacturing method according to the invention for a partitioning of a microfluidic sample.

Embodiments of the invention

FIG. 1 shows a flowchart 500 of an exemplary embodiment of the method 500 according to the invention for designing a partitioning of a microfluidic sample. As described above, the partitioning can in particular be part or a prerequisite of a partition-based quantitative detection method for analytes in the sample, with such a detection method for microfluidic samples preferably having a microfluidic device, in particular a lab-on-chip system, can be performed. For example, the method described below is part of a quantitative detection of nucleic acid segments of pathogens or tumor cells in a biological sample comprising a body fluid (e.g. blood, sputum or a smear), the quantitative detection using a digital PCR with the partitioning of the sample designed according to the invention he follows.

In a first step 510 of the method 500, the volume of the sample and an area available for the partitioning, partition area for short, are determined. For example, the volume that can be divided could be \Z _sys = 25 microliters (m/_) and the partition area could be square with an edge length of L = 10 millimeters (mm).

In the second step 520, which can also take place before the first step 510, it is determined whether the sample is to be divided in the form of droplets without intermediate walls or in chambers. FIG. 2a schematically shows an arrangement of droplets 110 with a diameter d on a partition surface 101 with a width L, the partition surface 101 being able to be, for example, square or rectangular and delimited by a wall 102 as illustrated. In this case, the partition surface 101 can be arranged in particular in a chamber of a microfluidic cartridge. In an alternative configuration, FIG. The chambers 120 have, for example, as shown, a hexagonal base area 121 with a width d, a wall height D, which corresponds to a chamber depth, and a wall thickness w between each two chambers, with the wall thickness w preferably being selected as small as possible in order to minimize the area of the partition surface 101 by walls 122 of chambers 120 to block. A minimum wall thickness and maximum wall height for maximizing the volume of the chambers 120 can also be limited, in particular, by manufacturing requirements.

If the chamber-based arrangement 120 is selected, the minimum wall thickness w, for example w=25 micrometers {ym), and the wall height/chamber depth D , for example D=380, are determined in a sub-step 521 meh. The partition area 101 can in particular be a surface of a substrate, for example a substrate made of silicon, plastic or a combination of both materials. In the case of the configuration with chambers 120, the chambers 120, in particular the walls 122, can also be made of silicon, plastic or a combination of both materials. In the case of an aqueous sample in particular, a hydrophilic configuration of the partition surface 101 or of the chambers 120 is advantageous.

Then, in a third step 530, a minimum partition size d _m/n is defined, with a size of this minimum partition size d _m/n being determined by manufacturing limitations, also mentioned above depending on the individual case, and a resolution of a detection optics to be used for the analysis of the partitions can. For example, the minimum partition size is d _{m / n} = 10 pm and represents the, preferably corresponds to the diameter d of the droplets 110 in the case of the droplet-based arrangement or the distance between the centers of two chambers 120 or the distance d between two opposite corners in a hexagonal base 121 of the chambers 120 in the case of the chamber-based arrangement. Based on this minimum partition dimension d _m/n , in a fourth step 540 it is calculated how many partitions can be accommodated on the partition area 101, possibly while maintaining the minimum wall thickness w. In the case considered, with a chamber-based approach, this would be A _max =101871 partitions in a hexagonal arrangement, this number being referred to below as the first number of partitions A _max . From the dimensions of the partitions, together with the depth D of the chambers 120, the capacity of an individual partition V _par can be calculated, and after multiplication by the first number of partitions A _max , the entire comprehensible volume V _ana can be calculated. In the present case, this is about V _ana = 2.51 pL and is therefore only about a tenth of the total divisible volume \Z _sys of 25 pL.

The first partition number A _max also defines the maximum theoretical range for a measurement of the concentration of the analyte (with cp/pL as units of copies per microliter), which is from -log(II /A _max )/V _par to -log(l- ( A _max - 1)/A _max )/V _par , where log denotes the natural logarithm. In order to preferably generate two measuring ranges of the same size, according to one fifth step 550 halves this maximum measurement range on a logarithmic scale. The resulting center point l is then at (log(ll /A _max ) * log(l-( A _max -l)/A _max )) ^A 0.5/V _par and in this example corresponds to about 431 cp/pL.

Alternatively, another concentration value l from this measurement range can also be selected, particularly if there are reasons for preferring measurement at lower or higher concentrations.

A preferred alternative to as many partitions as possible is to choose the dimensions of the partitions in such a way that the entire volume \Z _sys is also partitioned. If the partition area and a height that is filled by the partitions are large enough, it is basically always possible to accommodate the entire volume \Z _sys on the partition area 101, and in extreme cases in just a single partition. However, in order to keep the partitioning error as low as possible, when using the maximum possible volume, the volume should be divided into as many partitions as possible. Therefore, according to the sixth step 560 of the method 500, a second partition measure d _max must first be found, which under the given conditions maximizes the partitionable and thus analyzable volume V _ana and at the same time implies as many partitions as possible. This second partition size is also referred to as the maximum partition size d _max and, however, represents the smallest possible partition size given the maximum partitioned total volume. In the example shown, d _max is 128.52 pm with a maximum partitionable volume V _ana of 24.999 pL, i.e. practically the entire volume \Z _sys of 25 pL. The partitionable volume V _ana is divided into 6132 partitions, this number being referred to below as the second partition number A _mm . The sixth step 560 can also be carried out earlier, in particular before or in parallel with one of the preceding steps, provided that the first step 510 and the second step 520 have taken place.

According to a preferably seventh step 570 of the method, the maximum theoretical range for a measurement of the concentration of the analyte is determined when using the second partition number A _mm of partitions with the maximum partition size d _max , this range being analogous to above from -log(ll/ A _min )lVp _ar _2 extends to -log(l-( A _min -1)/ A _min )/Vp _ar _2 and where V _par _2 corresponds to the volume of a partition with partition size d _max . If the center point l calculated above does not fall within this range, according to a sub-step 571 of the seventh step 570, the partitioning is preferably designed according to the first number of partitions A _max with a minimum partition measure d _m/n . If the calculated center point I falls within this range, the method 500 according to this embodiment continues as follows.

According to an eighth step 580 of the method 500, a first uncertainty of a measurable concentration of the analyte when using the first partition number A _max of partitions with a minimum partition measure d _m/n (hereinafter referred to as minimum variant) and a second uncertainty of the measurable concentration calculated using the second number of partitions A _m/n of partitions with maximum partition size d _max (referred to below as maximum variant for short).

The relative uncertainties can preferably be determined using the following approach.

An uncertainty based on the confidence interval of the following probability distribution P{C\H) can be used to calculate the partitioning error: where C is the number of targets in the analyzed sample volume V _ana , H is the number of partitions containing at least one analyte, A is the available number of partitions, and S is the Stirling number of the second kind.

For the subsampling error, an uncertainty based on the confidence interval of the following probability distribution P(C _tot |C, p) can be used: where C stands for the number of targets in the analyzable sample volume V _ana , C _tot for the number of targets in the partitionable volume \Z _sys and p for the fraction of the analyzable volume in the partitionable volume V _ana /V _sys .

When both errors are combined, we get:

Since an exact calculation of this distribution takes a long time, it can be approximated using a Gaussian distribution. With a Gaussian distribution, the confidence interval can be calculated directly from the variance s. In the case of a 95% confidence interval, this is m ± 1.96 Vs, where m represents the expected value. The standard deviation s of a Gaussian distribution can be calculated from the probability at the expected value, i.e. the maximum probability:

This relationship is used in the approximation. The maximum value of P{C _tot \H, p) is set equal to R(m) and then the standard deviation and from it the confidence interval are calculated, which in turn defines the imprecision.

The value at which P{C _tot \ , p) becomes maximum is at

P{C _tot \H, p) is calculated via: This calculation is advantageous in terms of the time required. This approximation allows for a qualitative comparison and the quantitative results are within about 10% of the true, exact value of the uncertainty.

Using this approximation, for the present example the first relative uncertainty of the measurement result s at the center point l when using the minimum variant of about 0.0566 or 5.66% results. When using the maximum variant, the second relative uncertainty at midpoint l is about 0.0254 or 2.54%, i.e. less than half the relative uncertainty

According to a ninth step 590 of the method 500, the two relative uncertainties are now compared and an interpretation of the partitioning is determined as a function of this comparison. In particular, depending on this comparison, a partitioning according to the minimum variant 591 or according to the maximum variant 592 can be implemented, so that the relative uncertainty is preferably as low as possible. For the concrete choice of the variant and in particular for the choice of a concrete value for the partition, several approaches are advantageous, which were explained above in particular.

For example, that interpretation can then be selected which provides the lower uncertainty in the middle of the maximum theoretical measuring range. In this example, with a square partition area of 10 mm edge length, a processed volume of 25 μl, a chamber depth/wall height of 380 μm, a minimum wall thickness of 25 μm and a minimum partition size of 10 μm, the sample is distributed into 6132 hexagonal partitions with the partition measure of 128.52 pm. After the chambers 120 have been filled with the sample according to this partitioning, the chambers 120 can be covered with (transparent) oil in a particular embodiment before subsequent processing or analysis, for example as part of a digital PCR, takes place.

FIG. 3 shows, by way of example, relative uncertainties s calculated according to the approach described above as a function of the partition measure d for various concentrations of the analyte in the sample (10, 50, 100 and 500 analytes per microliter, respectively) when using chambers 120 and the same values for volume, edge length, chamber depth/wall height and wall thickness. As can be seen from FIG. 3, for these boundary conditions, for all calculated concentrations, a design with large partition dimensions is usually associated with a lower relative error, with a design with the smallest possible partition dimension being disadvantageous, especially in the case of low concentrations. This is due to the fact that in these cases the subsampling error dominates over the partitioning error due to the significantly smaller partitionable volume with a very small partition size. With other boundary conditions, on the other hand, smaller relative errors for designs with a small partition size compared to designs according to the maximum variant can also result for certain concentrations.

According to a modification of the embodiment 500 described above, the total dividable volume \Z _sys is increased to 30 pl_. The minimum partition dimension d _mm , the edge length L of the partition surface 101, the wall height/chamber depth D and the wall thickness w remain unchanged at 10 pm, 10 mm, 380 pm and 25 pm, respectively. In this case, the center l of the logarithmic measuring range is around 431 cp/pL. The largest fraction of the partitionable volume \Z _sys can be analyzed at a second/maximum partition measure of d _max = 294.65 pm. With this partition measure, the measuring range extends up to a concentration of approx. 338 cp/pL. Accordingly, this measuring range does not include the center point 1 and therefore, according to sub-step 571 of the seventh step 570, the partitioning would preferably be designed according to the minimum variant.

FIG. 4 shows a flow chart of an exemplary embodiment of the analysis method 600 according to the invention. In a first step 610 of the method 600, a sample can preferably be divided into partitions according to the method according to the invention for designing a partitioning, for example according to the method 500 described above for FIG in a second step 620 at least one partition, preferably all partitions as far as possible, are examined for the presence of the analyte and a conclusion is drawn from this as to a concentration of the analyte in the divided sample. This determination of Concentration is preferably carried out by carrying out a digital PCR, for which the partitions form the basis.

FIG. 5 shows a flowchart of an exemplary embodiment of the production method 700 according to the invention. In a first step 710, a partition area is provided. This can be done, for example, by providing a substrate, with a surface of the substrate forming the partition area. The partition surface or the substrate can be part of a microfluidic cartridge or can be arranged or fixed in the cartridge in the course of the manufacturing method 700 . In a second step 720 of the method, the partitioning is designed according to the method according to the invention for designing a partitioning, for example according to the method 500 described above for FIG

include partition area.

Claims

Expectations

1. Method (500) for designing a partitioning of a microfluidic, in particular biological sample into partitions on a partition surface, in particular for determining a concentration of an analyte in the sample, comprising the steps

• Defining (510, 520) a geometric shape (110, 120) of the partitions (110, 120), a shape of the partition area (101) and a total volume of the sample

• Determination (530, 540) of a minimum partition size of the partitions (110, 120) and a corresponding maximum number of partitions (110, 120) that can be arranged on the partition area (101) with a minimum partition size as the first partition number.

• Determination (560) of a second partition measure of the partitions (110, 120) and a corresponding second number of partitions under the condition that a maximum possible portion of the total volume can be partitioned on the partition area (101) and the maximum possible portion on as many partitions ( 110, 120) on the partition area (101).

• determining (580) a first uncertainty of a measurable concentration of the analyte using a partition measure from a first range around the minimum partition measure and determining a second uncertainty of the measurable concentration using a partition measure from a second range around the second partition measure.

• Interpretation (591, 592) of the partitions with a partition measure from the first range or from the second range depending on a comparison (590) of the first uncertainty with the second uncertainty.

2. Method (500) according to claim 1, wherein an interpretation (591, 592) of the partitions (110, 120) with a partition measure unequal to the maximum partition measure takes place if the first uncertainty is smaller than the second uncertainty, and wherein an interpretation of the Partitions (110, 120) not equal to minimum partition size occurs when the first uncertainty is greater than or equal to the second uncertainty.

3. The method (500) according to claim 1 or 2, wherein the partitions (110, 120) are designed with a partition measure from the first range if the first uncertainty is smaller than the second uncertainty, and wherein the partitions (110 , 120) with a partition measure from the second range if the first uncertainty is greater than or equal to the second uncertainty.

4. The method (500) according to any one of the preceding claims, wherein the partitions (110, 120) are designed with the minimum partition measure if the first uncertainty is smaller than the second uncertainty, and wherein the partitions (110, 120) are designed with maximum partition measure occurs when the first uncertainty is greater than or equal to the second uncertainty.

5. The method (500) according to any one of the preceding claims, wherein the partitions (110, 120) are designed with a partition measure from the first range, in particular with the minimum partition measure, if a measurement of a concentration of the analyte at a predetermined concentration value at a Interpretation of the partitions (110, 120) with a partition size from the second area, in particular with the second partition size, is not possible.

6. The method (500) according to any one of the preceding claims, wherein the first uncertainty is determined using the first partition number of partitions with the minimum partition metric and the second uncertainty is determined using the second partition number of partitions with the second partition metric.

7. Method (500) according to claim 6, wherein the first uncertainty and/or the second uncertainty are determined at a value from the maximum theoretical range for a measurement of the concentration of the analyte, in particular wherein the value corresponds to the logarithmic mean of the maximum theoretical range .

8. The method (500) according to any one of the preceding claims, wherein the geometric shape (110, 120) of the partitions (110, 120) one of the partitions (110,

120) at least partially delimiting wall (122) with a predetermined wall thickness and/or wall height.

9. Analysis method (600) for detecting an analyte in a microfluidic sample, wherein the sample is divided into partitions (110, 120) according to any one of the preceding claims and wherein at least one partition (110, 120) is examined for the presence of the analyte.

10. Analysis method (600) according to claim 9, wherein the analysis method (600) involves performing a digital PCR with at least some of the partitions (110,

120) included.

11. Method (700) for producing a partitioning of a microfluidic

A sample wherein a partition surface is provided and wherein the sample is partitioned according to an arrangement as claimed in any one of claims 1 to 8.