Although examples of one or more embodiments, and examples of problems solved by one or more embodiments, are described with reference to sample droplets of disparate volumes suspended in a liquid, one or more embodiments relate generally to techniques for determining a bulk concentration of a target in a source from a digital assay including compartments of disparate volumes formed in a barrier phase.
There are situations in which it is desirable to determine a bulk concentration of a target in a source. For example, to ensure the safety of a large number of people, a government agency may want to determine a bulk concentration of a pathogen (e.g., anthrax or another infectious agent, virus, or parasite), toxin (e.g., botulinum), or other poison (e.g., heavy metals such as lead and mercury, or chemical agents such as a nerve agent) in a municipal water supply, or may want to determine a bulk concentration of an irritant (e.g., pollen or smog), in the air. The bulk concentration is typically expressed as a ratio of the number of “pieces” (e.g., particles, molecules, cells, atoms) of the target per unit volume, or as a normalized ratio of the number of units of a volume occupied by the target to a reference number of units of the volume (e.g., parts per million).
Referring to
Next, each sample 14 is treated with a substance, such as a reagent, that causes the sample to exhibit one or more phenomena each having a respective level related to the concentration of the target 10 in the sample. For example, a reagent added to a sample 14 can bind with the molecules of the target 10, and cause the sample to exhibit a color having an intensity, saturation, hue, or shade that is related to the concentration of the target in the sample, where the color can be caused by the bound reagent absorbing one or more wavelengths of light, luminescing one or more wavelengths of light, or absorbing one or more first wavelengths of light and luminescing one or more second wavelengths of light.
Then, a technician (not shown in
Next, a human technician (not shown in
But a problem with this analog technique is that the technician cannot quantify, with any precision, his/her estimate {circumflex over (λ)}T of the bulk concentration λT of the target 10 in the source 12. That is, with this analog technique, the technician can provide only a coarse, or “rough,” estimate {circumflex over (λ)}T of the bulk concentration λT.
Unfortunately, a “rough” estimate {circumflex over (λ)}T of the bulk concentration λT is insufficient for some applications.
In another analog technique, a technician (not shown in
Although the latter analog technique may provide a more accurate estimate {circumflex over (λ)}T of the bulk concentration λT of the target 10 in the source 12, this technique still depends on the abilities of a human technician to distinguish sometimes subtle differences in the shades of a color, or in the levels of one or more other phenomena.
A digital assay 20 is formed by dividing sample into compartments (also called droplets if the compartments are of a liquid) 22, each of which is small enough (e.g., ≤˜100 picoliters (μL)) such that some compartments include the target 10, and some compartments do not include the target. The number of compartments 22 in the digital assay 20 can range from tens to thousands depending on the application and the amount of precision desired.
The technique is a digital technique because what is considered is whether a compartment 22 does include at least one target 10 (an “on” compartment) or does not include at least one target (an “off” compartment). For example, as described above in conjunction with
Algorithms exist for generating an estimate {circumflex over (λ)}T of the bulk concentration λT of the target 10 in the source 12 in response to characteristics exhibited by a digital assay, the characteristics including the number of “on” compartments 22, the number of “off” compartments, and the aggregate volume of the compartments.
Because the volumes of the compartments 22 are relatively small, low-cost, portable equipment often generates the compartments having significantly different volumes, where the largest compartment volume in the digital assay 20 is, for example, approximately ten or more times the smallest compartment volume. A digital assay having compartments with such disparate volumes is called a “polydisperse digital assay.”
Unfortunately, the accuracy of existing algorithms decreases dramatically as the uniformity of the compartment volumes decreases. Said another way, as the disparity among the compartment volumes increases, the accuracy of the estimated bulk concentration {circumflex over (λ)}T determined by existing algorithms decreases.
Consequently, for many applications, the disparity in the volumes of the compartments 22 generated by low-cost equipment is so large that existing algorithms cannot yield sufficiently accurate values of {circumflex over (λ)}T.
Still referring to
For example, a digital assay 30 has compartments 32 with approximately equal volumes, and such a digital assay is called a “monodisperse digital assay.”
But although a monodisperse digital assay, such as the digital assay 30, significantly increases the accuracy with which existing algorithms can estimate the bulk concentration λT of the target 10 in the source 12, the generation of a monodisperse digital assay is often beset by a number of problems.
For example, equipment for generating a monodisperse digital assay, such as the digital assay 30, can be expensive, bulky, and slow. Such equipment can cost US$150,000 or more; therefore, such equipment is often unattainable by charitable and other organizations with limited funds. Consequently, such organizations send out their samples to a lab for analysis, and typically wait a significant amount of time (e.g., a few weeks to a few months) for an estimate {circumflex over (λ)}T of the bulk concentration λT. Furthermore, such equipment can be on the order of 6 feet×6 feet×2 feet; therefore, it is often unsuitable for on-site applications (e.g., on the bank of a reservoir, at a well for drinking water). Consequently, even if an organization owns, or otherwise has access to, such equipment, transporting the sample from the source to the equipment increases the time for, and the cost of, obtaining an estimate {circumflex over (λ)}T of the bulk concentration λT. Moreover, such equipment can take a relatively long time, e.g., on the order of one minute, to generate each compartment of a monodisperse digital assay. Consequently, because a monodisperse digital assay may include tens, hundreds, or even thousands of compartments, the throughput of such equipment is limited, and, therefore, increases the time for, and the cost of, obtaining an estimate {circumflex over (λ)}T of the bulk concentration λT.
Therefore, a need has arisen for a system that is smaller, less expensive, and faster than existing equipment, yet that is at least as accurate as existing systems.
In an embodiment, such a system includes a compartment-generating device, a compartment detector, and electronic computing circuitry. The device is configured to generate compartments of a digital assay, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments. The detector is configured to determine a number of the compartments each having a respective concentration of a target that is greater than a threshold concentration. And the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to the number.
Compared to equipment for generating a monodisperse digital assay, such a system can be portable, lower-cost, and faster, yet can yield similar accuracy. In an embodiment, these improvements flow from the system being configured to implement an algorithm that allows for accurately estimating the bulk concentration λT of a target in a source from a polydisperse digital assay.
The words “approximately,” “substantially,” “about,” and similar words and phrases, are used below to indicate that a quantity can be in range of ±10% of a value given for the quantity, and that two or more quantities can be exactly equal, or can be within ±10% of each other. Furthermore, use of such a word to describe a range b to c indicates a range of b−10%·[c−b] to c+10%·[c−b].
A container 40, such as a clear test tube of glass or plastic, holds a polydisperse digital assay 42 of compartments 44 suspended in a barrier phase 46, according to an embodiment in which a dark compartment is “on” and a light compartment is “off.” In the described example, each compartment 44 is a respective droplet of a liquid, such as water, and the barrier phase 46 is another liquid, such as an oil, in which the droplets are suspended. The combination of the droplets 44 and the liquid barrier phase 46 is an emulsion.
The system 50 includes a droplet analyzer 52 and a computing device 54. Both the droplet analyzer 52 and computing device 54 include electronic circuitry that is hardwired, or is configured by software or firmware, to perform the respective functions and operates described below.
The droplet analyzer 52 includes an “on”-droplet detector and counter 56, a droplet counter 58, and a droplet-volume determiner 60. The “on”-droplet detector and counter 56 includes electronic circuitry and one more optical sensors configured to detect, and to determine the number of, “on” droplets 44 in the polydisperse digital assay 42. The droplet counter 58 includes electronic circuitry and one or more optical sensors (one or more of which may be shared with the on-droplet detector and counter 56) configured to determine the total number of “on” and “off” droplets 44 in the polydisperse digital assay 42. And the droplet-volume detector 60 includes electronic circuitry and one or more optical sensors (one or more of which may be shared with the “on”-droplet detector and counter 56 or the droplet counter 58) configured to measure, or otherwise to determine, the respective volume of each of the droplets 44.
The computing device 54 can be any suitable computer, such a laptop, a tablet, or a smart phone, that includes one or more microprocessors or microcontrollers.
Referring to
First, at a step 72, a technician (not shown in
Next, at a step 74, the “on”-droplet detector and counter 56 determines the number a of “on” droplets 44 in the polydisperse digital assay 42. For example, the counter 56 can include a combination illumination device and image-capture device, such as a light source and a small camera, which the technician holds up near, or against, the container 40. The illumination device illuminates the droplets 44 so that droplets including the target luminesce a color having shades respectively corresponding to the concentrations of the target in the droplets. The technician then presses a button on the device, or a virtual button displayed by the computer 54, to capture an image of the droplets 44 in the container while the droplets including the target are luminescing. Using conventional image-processing techniques, the computer 54 analyzes the image, detects the droplets 44, and determines whether each detected droplet 44 is “on” or “off” by determining, for each droplet, whether the number of targets (or, said another way, the number of the target) within the droplet exceeds a threshold number (e.g., one target molecule, five target molecules, ten target molecules). For example, an optical signal that the target luminesces has a property (e.g., intensity, color, color shade) indicative of the number of targets within a droplet 44, and the computer 54 determines whether the number of targets within the droplet exceeds the threshold number by determining whether the property of the target-related optical signal exceeds (or is below) a signal-property threshold. Further in example, the computer 54 compares a shade of the color (e.g., green), or an opacity, of a droplet 44 to a threshold shade or opacity, determines that the droplet is “on” if the level of the shade or opacity is greater than or equal to the threshold, and determine that the droplet is “off” if the level of the shade or opacity is less than the threshold. Alternatively, the technician uses the “on”-droplet detector and counter 56 to capture multiple images of the droplets 44 from different orientations relative to the container 40 so that the computer 54 is able to detect droplets that might otherwise be obscured by other droplets in a single image.
Then, at a step 76, the computer 54 generates an estimate {circumflex over (λ)}T of the bulk concentration λT of the target 10 in the source 12 in response to the number a of “on” droplets 44 in the container 40. For example, as described below in conjunction with
The system 50, and the algorithm that the system implements, provide one or more advantages over existing systems and techniques for determining a bulk concentration of a target in a source. For example, the container 40 and the barrier phase 46 are configured to provide inexpensive, on-site, and fast generation of the digital assay 42. Furthermore, the system 50 is configured to provide inexpensive, on-site, and fast estimation of the bulk concentration λT of the target 10 in the source 12 even in response to a polydisperse digital assay 42 having compartments 44 of disparate volumes.
Still referring to
Referring to
First, at a step 82, a technician (not shown in
Next, at a step 84, the “on”-droplet detector and counter 56 determines the number a of “on” droplets 44 in the polydisperse digital assay 42. For example, the “on”-droplet detector and counter 56 may determine the number a using a method that is the same as, or that is similar to, the method described above in conjunction with step 74 of
Then, at a step 86, the droplet-volume determiner 60 determines the respective volume vi of each of the detected “on” droplets 44, and, if necessary, determines the aggregate volume VTotal of the droplets 44 by summing the respective volumes of the detected “on” and “off” droplets. For example, to determine the respective volume vi of each of the α “on” droplets 44, the determiner 60 analyzes the one or more images that the system 50 captured at the step 84 using a conventional droplet-volume-determining algorithm. To determine the aggregate volume VTotal, the determiner 60 also determines the volumes of the “off” droplets 44 in the same way that the determiner determines the volumes vi of the “on” droplets, sums the volumes of the “off” droplets with the volumes vi of the “on” droplets, and sets VTotal equal to the determined sum. Alternatively, the droplet-volume determiner 60 is configured to operate as described above but is part of, or is otherwise included in, the computer 54 instead of the droplet analyzer 52. In yet another alternative, because the aggregate volume of the sample is the same as the aggregate volume VTotal of the droplets 44, and because the volume of the sample is known per step 82, the technician enters into the computer 54 the volume of the sample, and the computer sets VTotal equal to the entered sample volume.
Next, at a step 88, the computer 54 solves for the estimated bulk concentration {circumflex over (λ)}T of the target 10 in the source 12 according to the following equation:
A derivation and explanation of equation (1) is included below.
In an ideal example, each “on” droplet 44 would contain one and only one of the target such that the computer 54 could determine the estimated bulk concentration {circumflex over (λ)}T from the number a of “on” droplets 44 divided by the volume VTotal of the sample 14, where a would also equal the number of targets in the sample.
But because in an actual, non-ideal, example each “on” droplet 44 may contain more than one of the target 10, determining the estimated bulk concentration {circumflex over (λ)}T from α/VTotal may lead to an error caused by an undercounting of the number of the target in the sample 14.
To reduce or eliminate such an undercounting error where the respective number of the target in one or more of the “on” droplets 44 of the sample 14 is unknown, the computer 54 is configured to use equation (1) to estimate the bulk concentration λT of the target in the source 12.
For each “on” droplet 44, equation (1) includes a respective expression for the probability that the droplet includes at least one of the target, the probability being dependent on, and, therefore, the respective expression including, the respective volume of the droplet.
Consequently, equation (1) not only effectively accounts for the possibility that each of one or more of the “on” droplets 44 contains more than one of the target 10, equation (1) also effectively accounts for a larger “on” droplet 44 being more likely than a smaller “on” droplet to contain more than one of the target.
The system 50, and the DVV algorithm that the system 50 is configured to implement, provide one or more advantages over existing systems and techniques. For example, the container 40 and binary phase 46 provide for inexpensive, on-site, and fast generation of the digital assay 42. Furthermore, the system 50 provides for inexpensive, on-site, fast, and accurate estimation of a bulk concentration λT of a target 10 in a source 12 even in response to a polydisperse digital assay 42 having droplets 44 of disparate volumes.
Still referring to
Referring to
At a step 102, a technician (not shown in
Next, at a step 104, the droplet counter 58, or a similar counter, determines the number m of test droplets, and at a step 106, the droplet-volume determiner 60, or a similar determiner, determines a respective volume vi_characterized for each of the m test droplets.
Then, at a step 108, the computer 54 stores the number m of test droplets, and stores the volumes vi_characterized of the test droplets, in a memory (not shown in
The theory behind generating the characterized number m and the characterized volumes vi_characterized is that similar containers, sample substances, and barrier phases will generate similar values for m and vi_characterized such that the values of m and vi_characterized can be used to determine a bulk concentration λT of the target 10 (
Still referring to
Referring to
First, at a step 112, a technician (not shown in
Next, at a step 114, the “on”-droplet detector and counter 56 determines the number a of “on” droplets 44 in the polydisperse digital assay 42. For example, the on-droplet detector and counter 56 may determine the number a using a method that is the same as, or similar to, the method described above in conjunction with step 74 of
Then, at a step 116, the droplet counter 58 determines the number n of all droplets 44 (i.e., the sum of the “on” and “off” droplets) in the polydisperse digital assay 42 in the container 40. For example, to determine the number n of all droplets 44, the droplet counter 58 analyzes the one or more images that the system 50 captured at the step 114 using a conventional droplet-counting algorithm. Alternatively, the droplet counter 58 counts only the number b of “off” droplets 44, and adds this number to the number a of “on” droplets, to generate n=a+b. Alternatively, the droplet counter 58 operates in a similar manner but is part of, or is included in, the computer 54 instead of being part of, or included in, the droplet analyzer 52.
Next, at a step 118, the computer 54 solves for the estimated bulk concentration {circumflex over (λ)}T of the target 10 in the source 12 according to the following equation:
where m is the characterized number of droplets and each vi_characterized is the characterized volume of a respective one of the m droplets as described above in conjunction with
A derivation and explanation of equation (2) is included below.
The system 50, and the DVVA algorithm that the system is configured to implement, provide one or more advantages over existing systems and techniques. For example, the container 40 and barrier phase 46 provide for inexpensive, on-site, and fast generation of the digital assay 42. Furthermore, the system 50 provides for inexpensive, on-site, and fast estimation of a bulk concentration λT of the target 10 in the source 12 even in response to a polydisperse digital assay 42 having droplets 44 of disparate volumes that are unknown.
Still referring to
Moreover, alternate embodiments described above in conjunction with
If the barrier phase 46, e.g., an oil, has a higher density than the droplets 44, then the droplets may “float” over a residual region 120 of the barrier phase that is devoid of droplets as shown in
Conversely, if the barrier phase 46, e.g., an oil, has a lower density than the droplets 44, then the droplets may “sink” to the bottom of the container 40 such that the residual region 120 of the barrier phase that is devoid of droplets “floats” over the droplets (the residual region “floating” over the droplets is not shown in
In addition to the container 40 and the droplet analyzer 52, the kit 130 includes a container stopper 132, a re-openable and re-closable package (e.g., a screw-top bottle) 134 of the barrier phase 46, a re-openable and re-closable optional package (e.g., a screw-top bottle) 136 of a reagent, a dropper 138, and a non-transitory computer-readable medium 140. The stopper 132 is configured to form a liquid-tight seal at the opening of the container 40 to allow shaking of the container to form the polydisperse digital assay 42. The dropper 138 allows a technician to transfer the barrier phase 46 and the reagent from their respective packages 134 and 136 to the container 40, and allows a technician to obtain a liquid sample (e.g., water) from a source (e.g., reservoir) and to transfer the sample to the container. And the computer-readable medium is a suitable non-volatile memory that stores program instructions that, when executed by a portable computer, cause the computer to implement one of the algorithms described above in conjunction with
Still referring to
The computer 54 includes computing circuitry 150, one or more input devices 152, one or more output devices 154, and one or more data-storage devices 156.
The computing circuitry 150 includes circuitry that is configured to perform various functions and operations, such as the functions and operations described above in conjunction with
The one or more input devices 152 are configured to allow an operator or device to provide data or other information or signals to the computer 54. Examples of an input device 152 include a keyboard, mouse, touch screen, audible or voice-recognition component, the droplet analyzer 52 (
The one or more output devices 154 are configured to provide data from the computing circuitry 150 to an operator or device in a suitable form, or to perform a function or operation under control of the computing circuitry 150. Examples of an output device 154 include a printer, video display, audio output components, the droplet analyzer 52 (
The one or more data-storage devices 156 are configured to store data on or to retrieve data from volatile or non-volatile storage media (not shown). Examples of a data-storage device 156 include a magnetic disk, a FLASH memory, other types of solid state memory such as a random-access memory (RAM, SRAM, DRAM, USB “stick”), a ferro-electric memory, a tape drive, an optical disk like a compact disk and a digital versatile disk (DVDs), and so on.
Still referring to
In digital assays, the targets (molecules, cells, etc.) in the bulk sample are randomly distributed into many compartments. A compartment with one or more targets gives a signal (e.g., fluorescent intensity after nucleic acid amplification), and is called an “on” compartment. A compartment without targets does not provide a signal, and is called an “off” compartment. Targets are distributed into compartments following the Poisson distribution. An assay system, such as the system 50 of
For each assay, the bulk concentration needs to be calculated using a certain inference method. The digital-variable-volume (DVV) and digital-variable-volume-approximation (DVVA) methods are based on maximum likelihood estimation; the concentration estimate is the one that maximizes the likelihood of observing a certain experimental result. The choice of maximum likelihood estimation was inspired by its use in multivolume digital PCR (where each assay utilizes a handful of predetermined, precisely controlled volumes), which has been inspired by limiting dilution assays for microorganism counting. In particular, an important feature is that results from different volumes are readily combined by way of multiplying the likelihoods. Below, are derived the expressions used to calculate the concentration estimates and the standard errors using the maximum likelihood framework. The terms relevant to the descriptions of the DVV and DVVA methods are described in Table 1.
x
Begin by calculating the probability that a particular compartment turns “on” given the volume and bulk concentration (equation (a)). It is the same as the probability of having more than one target in the compartment, based on the Poisson distribution with the mean of vλT. This probability is useful in subsequent derivation steps.
Digital Variable Volume (DVV)
The likelihood l(λT) of observing a certain assay result, i.e., particular numbers of “on” and “off” compartments (a and b, respectively) with the associated volumes is the product of individual likelihoods calculated using equation (a).
Πi=1apeach(λT,vi)Πi=1b[1−peach(λT,vi)]=Πi=1a(1−e−v
The value of λT that maximizes l(λT) is then found. Use the natural logarithm of the concentration (Λ≡ln(λT)) and the loglikelihood function (L(Λ) ≡ln(λT)) to conveniently calculate the standard errors and enforce the requirement for positive concentrations. The calculation of the standard error is also more appropriate for Λ than for λT because the distribution of Λ is less skewed. Therefore, the goal is now finding the Λ value that maximizes L(Λ). The expression for L(Λ) and the first and second derivatives are shown below.
To calculate {circumflex over (Λ)}, the root of the first derivative (equation (d)) is determined, i.e., equation (1), which is repeated below, is solved.
Plugging L′(Λ)=0 into equation (e) gives L″(Λ)<0. So the Λ value found using equation (1) indeed maximizes L(Λ). Also, using the derivatives at Λ, the standard error of Λ also can be calculated using the observed Fisher information L″({circumflex over (Λ)}).
This σ{circumflex over (Λ)} can be used to calculate the confidence interval. Calculating σ{circumflex over (Λ)} using the expected Fisher information is not feasible because the volume distribution is unknown. In fact, to implement the DVV technique, the volume distribution is not required and need not be the same from one experiment to another.
Digital Variable Volume Approximation (DVVA)
In general, the probability a compartment turns ON can be calculated using the volume distribution (specified by the probability density function ƒ(v)).
pon(λT)=∫ƒ(v)peach(λT,v)dv=∫ƒ(v)(1−e−vλ
Previously, ƒ(v) has been chosen to follow the gamma distribution or truncated normal distribution. However, in practice, ƒ(v) may not be described by a simple function. And even when that is true, a set of pre-measured volumes (M as in Table 1) still needs to be experimentally obtained to characterize ƒ(v). Therefore, for the DVVA technique, a set of separately measured volumes, M, is used instead of ƒ(v).
The likelihood function can then be obtained using the binomial distribution (for the case of a ON compartments out of n compartments with the probability of pon(λ).
As motivated above, the loglikelihood function can be calculated with the change of variable Λ≡ln(λT), and subsequently, its first and second derivatives.
To maximize L(Λ), the root of L′(Λ) is found (equation (2), which is repeated below), and it is verified that it corresponds to a maximum by checking the sign of the second derivative (equation (m)). An interesting observation is that equation (2) can be obtained by using a/n to estimate pON(λT).
Then σ{circumflex over (Λ)} is calculated using the expected Fisher information, −L″(Λ). The second derivative, L″(Λ), is a linear function of
((equation 2)).
can be plugged into equation (k), and the subsequent result can be plugged into equation (l) to obtain the following expression for σ{circumflex over (Λ)}.
In this particular case, the standard error calculated using the observed Fisher information, −L″({circumflex over (Λ)}), is also the same as equation (n) evaluated at Λ={circumflex over (Λ)}. This can be verified by plugging L′({circumflex over (Λ)})=0 into L″({circumflex over (Λ)}) (equation (0).
Example 1 includes a system, comprising: a device configured to generate compartments of a sample, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments; a detector configured to determine a number of the compartments each having a respective number of a target that is greater than a threshold number of the target; and electronic circuitry configured to determine a bulk concentration of the target in a source of the sample in response to the determined number of the compartments.
Example 2 includes the system of Example 1 wherein the device includes a container configured to generate the compartments of the sample in a barrier phase in response to the container moving.
Example 3 includes the system of any of Examples 1-2 wherein the device includes a container configured to generate the compartments of the sample in a liquid in response to a shaking of the container.
Example 4 includes the system of any of Examples 1-3 wherein the device includes a container configured to generate the compartments of the sample as droplets of the sample in an oil in response to a shaking of the container.
Example 5 includes the system of any of Examples 1-4 wherein the device includes a container configured to generate the compartments of the sample as droplets of the sample in a barrier phase in response to a shaking of the container, the droplets each have a viscosity, the barrier phase having a viscosity that is greater than the viscosity of the droplets.
Example 6 includes the system of any of Examples 1-5 wherein the detector is configured to determine the number of the compartments each having a respective number of the target that is greater than the threshold number of the target in response to a wavelength of electromagnetic energy at which each of the number of the compartments luminesces.
Example 7 includes the system of any of Examples 1-6 wherein the detector is configured to determine the number of the compartments each having a respective number of the target that is greater than the threshold number of the target in response to a wavelength of electromagnetic energy that each of the number of the compartments absorbs.
Example 8 includes the system of any of Examples 1-7 wherein the detector is configured to determine the number of the compartments each having a respective number of the target that is greater than the threshold number of the target in response to a wavelength of electromagnetic energy that each of the number of the compartments passes.
Example 9 includes the system of any of Examples 1-8 wherein the detector is configured to determine the number of the compartments each having a respective number of the target that is greater than the threshold number of the target in response to a wavelength of electromagnetic energy that each of the number of the compartments blocks.
Example 10 includes the system of any of Examples 1-9 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a respective measured volume of each of the number of compartments.
Example 11 includes the system of any of Examples 1-10 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a sum of a respective measured volume of each of the compartments.
Example 12 includes the system of any of Examples 1-11 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a number of the compartments.
Example 13 includes the system of any of Examples 1-12 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a number of other compartments.
Example 14 includes the system of any of Examples 1-13 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a respective measured volume of each of other compartments.
Example 15 includes the system of any of Examples 1-14 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a number of other compartments and a respective measured volume of each of the other compartments.
Example 16 includes the system of any of Examples 1-15 wherein the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to a probability density function of compartment volume.
Example 17 includes a system, comprising: a barrier-phase liquid; a container configured to receive the barrier-phase liquid, to receive a sample including a target, and to generate compartments of the sample suspended in the barrier-phase liquid in response to a shaking of the container, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments; and a detector configured to determine a number of the compartments each having a respective number of the target that is greater than a threshold number of the target.
Example 18 includes the system of Example 17 wherein the barrier-phase liquid includes an oil.
Example 19 includes the system of any of Examples 17-18 wherein the container includes a clear tube.
Example 20 includes the system of any of Examples 17-19 wherein the detector includes an electronic detector.
Example 21 includes the system of any of Examples 17-20 wherein the detector is configured to determine a number of the compartments.
Example 22 includes the system of any of Examples 17-21, further comprising an apparatus configured to obtain the sample from a source including the target.
Example 23 includes the system of any of Examples 17-22, further comprising a computer-readable medium storing instructions that, when executed by a computing circuit, cause the computing circuit to determine a bulk concentration of the target in a source of the sample in response to the number of the compartments each having a respective number of the target that is greater than a threshold number of the target.
Example 24 includes a method, comprising: generating compartments of a sample, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments; determining a number of the compartments each having a respective number of a target that is greater than a threshold number of the target; and determining a bulk concentration of the target in a source of the sample in response to the number of the compartments.
Example 25 includes the method of Example 24 wherein generating the compartments includes generating the compartments suspended in a barrier phase by shaking a container that includes the sample and the barrier phase.
Example 26 includes the method of any of Examples 24-25 wherein generating the compartments includes generating droplets suspended in a liquid by shaking a container that includes the sample and the liquid.
Example 27 includes the method of any of Examples 24-26 wherein determining the number of compartments each having a respective number of the target that is greater than the threshold number of the target includes determining the number of compartments in response to a wavelength of electromagnetic energy at which each of the number of the compartments luminesces.
Example 28 includes the method of any of Examples 24-27 wherein determining the number of the compartments each having a respective number of the target that is greater than the threshold number of the target includes determining the number of compartments in response to a wavelength of electromagnetic energy that each of the number of the compartments absorbs.
Example 29 includes the method of any of Examples 24-28 wherein determining the number of the compartments each having a respective number of the target that is greater than the threshold number of the target includes determining the number of compartments in response to a wavelength of electromagnetic energy that each of the number of the compartments passes.
Example 30 includes the method of any of Examples 24-29 wherein determining the number of the compartments each having a respective number of the target that is greater than the threshold number of the target includes determining the number of compartments in response to a wavelength of electromagnetic energy that each of the number of the compartments blocks.
Example 31 includes the method of any of Examples 24-30 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a respective measured volume of each of the number of compartments.
Example 32 includes the method of any of Examples 24-31 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a sum of a respective measured volume of each of the compartments.
Example 33 includes the method of any of Examples 24-32 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a number of the compartments.
Example 34 includes the method of any of Examples 24-33 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a number of other compartments.
Example 35 includes the method of any of Examples 24-34 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a respective measured volume of each of other compartments.
Example 36 includes the method of any of Examples 24-35 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a number of other compartments and a respective measured volume of each of the other compartments.
Example 37 includes the method of any of Examples 24-36 wherein determining the bulk concentration of the target in the source of the sample includes determining the bulk concentration in response to a probability density function of compartment volume.
Example 38 includes a tangible non-transitory computer-readable medium storing instructions that, when executed by a computing circuit, cause the computing circuit: to determine a number of compartments of a sample each having a respective number of a target that is greater than a threshold number of the target, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments; and to determine a bulk concentration of the target in a source of the sample in response to the determined number of compartments.
From the foregoing it will be appreciated that, although specific embodiments have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the disclosure. Furthermore, where an alternative is disclosed for a particular embodiment, this alternative may also apply to other embodiments even if not specifically stated. In addition, any described component or operation may be implemented/performed in hardware, software, firmware, or a combination of any two or more of hardware, software, and firmware. For example, any of one, more, or all of the above-described operations and functions can be performed by electronic circuitry that is hardwire configured to perform one or more operations or functions, that is configured to execute program instructions to perform one or more operations or functions, that is configured with firmware, or otherwise configured, to perform one or more operations or functions, or that is configured with a combination of two or more of the aforementioned configurations. For example, one or more of the components of the computer 54 of
This application is a continuation of non-provisional U.S. patent application Ser. No. 17/689,539, filed Mar. 8, 2020, titled DETERMINING A BULK CONCENTRATION OF A TARGET IN A SAMPLE USING A DIGITAL ASSAY WITH COMPARTMENTS HAVING NONUNIFORM VOLUMES, and naming first inventor HUYNH, Toan, which is a continuation of non-provisional U.S. patent application Ser. No. 16/200,447, now granted U.S. Pat. No. 11,305,284. The entire contents of the above-referenced applications and of all priority documents referenced in the Application Data Sheet filed herewith are hereby incorporated by reference for all purposes.
Number | Name | Date | Kind |
---|---|---|---|
20140106359 | Litterst et al. | Apr 2014 | A1 |
20170175174 | Chiu | Jun 2017 | A1 |
Entry |
---|
Huynh, Toan, et al. “General methods for quantitative interpretation of results of digital variable-volume assays.” Analyst 144.24 (2019): 7209-7219. (Year: 2019). |
https://www.lawinsider.com/dictionary/electronic-circuitry (Year: 2023). |
https://www.sciencedirect.com/science/article/pii/B9780080511986500114 (Year: 1999). |
Office Action received for Japanese Patent Application No. 2021-529411, dated Feb. 28, 2023, 4 pages (2 pages of Official Language and 2 pages of English Translation). |
Office Action received for CN Patent Application No. 201980077639.0, mailed on Oct. 14, 2023, 15 pages (8 pages of Official copy and 7 pages of English translation). |
Number | Date | Country | |
---|---|---|---|
20230149932 A1 | May 2023 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 17689539 | Mar 2022 | US |
Child | 18151011 | US | |
Parent | 16200447 | Nov 2018 | US |
Child | 17689539 | US |