Patent Application
20240201219
The present application claims priority to EP Patent Application No. 22213596.4, filed Dec. 14, 2022, the contents of which are hereby incorporated by reference in their entirety.
Laboratory automation devices are used for automating tasks of a laboratory assistant, which, for example, tests a patient for specific diseases. Usually, a sample of the patient's blood, urine, stool, etc. is taken and analyzed by means of a bio-chemical procedure. Such a procedure consists in various operations like adding substances, incubating, separating, etc. and a measurement process which quantitatively or qualitatively measures the amount or presence of a substance indicating the specific disease.
Sometimes laboratory automation devices need to deal with unknown liquids or with liquids such as blood, which have varying physical properties such as density and viscosity. In these cases, it may be that the user of the laboratory automation device wants to know the properties of the liquid. It also may be that the physical properties have to be determined to calculate and set the liquid class parameters such as accuracy correction, asp/dsp speeds, etc. A liquid class for a specific liquid is used for controlling the laboratory automation device, when the laboratory automation device processes this liquid.
Below, embodiments are described in more detail with reference to the attached drawings.
The reference symbols used in the drawings, and their meanings, are listed in summary form in the list of reference symbols. In principle, identical parts are provided with the same reference symbols in the figures.
Described herein are a method, a computer program, a computer-readable medium and a control device for determining physical parameters of a liquid. Furthermore, the method relates to a laboratory automation device.
It is a feature described herein to automate and simplify the determination of physical parameters of liquids used in the context of laboratory automation.
A first aspect relates to a method for determining physical parameters of a liquid to be aspirated and/or dispensed by a laboratory automation device. The method may be performed automatically by the laboratory automation device and in particular a control device of the laboratory automation device. A control device of a laboratory automation device, which control device is adapted for performing the method, also is a further aspect.
According to an embodiment, the method comprises: picking up of a pipette with the laboratory automation device: A pipetting arm may take the pipette. The pipette may be disposable. A disposable pipette may be called “pipette tip”, however, in the following, the end of the pipette with the orifices will be called pipette tip.
The method further comprises: lowering the pipette into a sample container with the laboratory automation device, the sample container containing the liquid. The liquid may be an unknown liquid, for which the physical parameters are to be determined.
The method further comprises: aspirating and dispensing air and liquid with the laboratory automation device in such a way, that a liquid level in the pipette solely rises in a first step and solely lowers in a second step, such that an interior surface of the pipette is wetted with liquid solely one time. For determining the physical properties with high accuracy, they are determined in one pass, where the liquid level in the pipette solely rises once and lowers once. This may mean that in the first step, when the pipette tip is within the liquid, solely an underpressure is generated in the pipette. In the second step, then solely an overpressure is generated.
The method further comprises: during aspirating and dispensing air and liquid, measuring a pressure curve in the pipette and determining the physical parameters from the pressure curve, the physical parameters comprising at least one of a wetting angle and a viscosity. The pressure curve may be measured with a pressure sensor of the laboratory automation device, which pressure sensor may be connected to the interior of the pipette. For example, the pressure sensor may be a part of the pipetting arm or the pump generating the pressure in the pipette.
The physical parameters may be determined from a set of equations, which models the liquid and the pipette. Specific pressure values at different times of the pressure curve, such as specific peaks, may be input into the equations to calculate the physical parameters. The equations furthermore may comprise parameters, which model the pipette, such as a geometric shape of the pipette, a level at which a cylindrical part of the pipette starts, an orifice radius, an opening angle of a cone providing the orifice, etc. These pipette parameters may be fixed and/or stored in the control device, when a normed pipette tip is used.
It has to be noted that the physical parameters already may be determined during the measurement of the pressure curve. However, also the pressure curve first may be recorded completely and, for example, stored in the control device. After that, the pressure curve may be evaluated and the physical parameters may be determined.
According to an embodiment, the pipette is unused and has not been wetted with a liquid before. A wetting of the interior surface of the pipette before this method step may influence the determination of physical parameters, such as the surface tension, volatility, wetting angle and viscosity. Starting with an unused pipette will increase the accuracy of these parameters.
According to an embodiment, the method further comprises: before lowering the pipette into the sample container for a first time: aspirating and/or dispensing air into the pipette; and determining a filter resistance of a filter inside the pipette from the pressure curve during aspirating and/or dispensing air. The filter resistance of a possible filter in the pipette is determined in the beginning of the method without immersing the pipette tip into the liquid. The filter resistance can be determined from a flowrate, which may be provided by the pump, and a pressure difference at the beginning and end of the aspiration and of the dispensing.
According to an embodiment, the method further comprises: determining an aspirating-dispensing asymmetry from the measured pressure values during aspirating and dispensing air. An aspiration filter resistance during aspiration and a dispensing filter resistance during dispensing can be determined and compared with each other. A dispensing asymmetry higher than a threshold may indicate an error or a problem with the pipette.
According to an embodiment, the method further comprises: after lowering the pipette into the sample container for the first time: dispensing air into the liquid and generating at least one bubble in the liquid; determining a surface tension of the liquid from the measured pressure curve during generating the bubble. Possibly after the filter resistance determination and/or before aspirating and dispensing air and liquid in such a way, that a liquid level in the pipette solely rises in a first step and solely lowers in a second step, one or more bubbles may be generated in the liquid. When the bubbles leave the pipette tip, a maximal pressure is related to the surface tension of the liquid and the surface tension can be determined from the generated pressure curve.
The test, whether the pipette tip has been lowered into the liquid, i.e. that the orifice is below the liquid level, may be done by measuring an electric capacitance between pipette tip and liquid. Capacitance liquid level detection may allow to accurately control the submerge of the pipette tip. According to an embodiment, the method further comprises: after generating the one or more bubbles, withdrawing the pipette from liquid and dispensing air to remove liquid from the pipette tip. To enhance the accuracy of the following measurements, the pipette tip and/or the orifice in the pipette may be freed from liquid by dispensing air.
According to an embodiment, the method further comprises: waiting without aspirating and dispensing for a waiting time period, while liquid is in the pipette; and determining a volatility of the liquid from the measured pressure curve during the waiting time period. This may be done after filter resistance determination and/or surface tension determination and/or at the beginning of aspirating and dispensing air and liquid in such a way, that a liquid level in the pipette solely rises in a first step and solely lowers in a second step. Before waiting for the time period, some liquid has to be aspirated and/or during waiting, no aspirating and dispensing should be performed. During the waiting, dissolved gas and/or vapor may leave the liquid inside the pipette causing a pressure change. From this pressure change and a known amount of liquid in the pipette, the volatility may be determined. The known amount of liquid in the pipette can be determined from the flowrate and time of aspiration and the pressure in the tip after aspiration before starting the waiting time period.
According to an embodiment, the method further comprises: determining the wetting angle of the liquid from the pressure curve during a time period with continuously raising and/or lowering of the liquid level in the pipette. This may be done during aspirating and dispensing air and liquid in such a way, that a liquid level in the pipette solely rises in a first step and solely lowers in a second step. The wetting angle can be determined from the pressure curve during a time with continuously raising or lowering the liquid level. The lowering and/or raising may be done with constant speed of the liquid level.
According to an embodiment, an advancing wetting angle is determined for a raising liquid level and/or a receding wetting angle is determined for a lowering liquid level. From these two wetting angles, a mean value may be determined. A hysteresis of the two wetting angles may be determined from the difference of the two wetting angles.
According to an embodiment, the method further comprises: determining a viscosity of the liquid from the pressure curve during a time period with continuously raising and/or lowering of the liquid in the pipette. This may be done during aspirating and dispensing air and liquid in such a way, that a liquid level in the pipette solely rises in a first step and solely lowers in a second step. The viscosity can be determined from the pressure curve during a time with continuously raising or lowering the liquid level. The lowering and/or raising may be done with constant speed of the liquid level. Dispensing of the liquid also may be done, such that the liquid is dispensed in air.
According to an embodiment, the method further comprises: determining a density of the liquid from the pressure curve from two pressures of the pressure curve at two times with two different known liquid levels. The density may be determined from the weight of the difference volume of the liquid between the two liquid levels. This weight depends on the pressure difference at these two liquid levels. The density may also be determined by analyzing the slope of the pressure curve during aspiration and/or dispensing, if other effects such as filter resistance, contact angle, etc., are subtracted.
According to an embodiment, the physical parameters are determined from a set of equations modelling the liquid and the pipette. The equations may be seen as a physical model of the relevant parts of the laboratory automation system. The set of equations comprises the physical parameters of the liquid and parameters of the pipette. Such pipette parameters may comprise a geometric shape of the pipette, the start of a cylindrical part of the pipette, the diameter of the cylindrical part, an orifice radius of the pipette tip, a tip opening angle of the pipette tip and/or its orifice, etc.
The pipette parameters may be fixed and/or stored in the control device. In this case, measured tips may be used to reduce the tolerances of physical parameter determination. However, it is also possible to determine the pipette parameters with the same or an analogous method, however with a known liquid, from which the physical parameters are known. The pipette parameters can be determined from the pressure curve with the help of the known liquid parameters of the known liquid, such as water.
According to an embodiment, the liquid (described above) is an unknown liquid, the pipette is a second pipette and the sample container is a second sample container.
All the parameters may be determined by performing the method twice, once with a known, reference liquid (such as water) and then redoing the method with the unknown liquid for which we are interested in the properties. This may be possible as pipettes from the same lot and in particular from the same cavity of the mold may have exactly the same geometry.
A first pressure curve for the known liquid and a second pressure curve for the unknown liquid may be determined and/or measured. All unknown parameters may be determined from both pressure curves. It has to be noted that also firstly, the second pressure curve with the unknown liquid and after, that the first pressure curve with the known liquid may be determined and/or measured.
According to an embodiment, the method further comprises: pickup of a first pipette with the laboratory automation device, the first pipette being of equal structural form as the second pipette; lowering the first pipette into a first sample container with the laboratory automation device, the first sample container containing a known liquid with known physical parameters; aspirating and dispensing air and the known liquid with the laboratory automation device in such a way, that a liquid level in the first pipette solely rises in a first step and solely lowers in a second step, such that an interior surface of the first pipette is wetted with the known liquid solely one time; during aspirating and dispensing air and the known liquid, measuring a pressure curve in the first pipette and determining parameters of the first and second pipette from the pressure curve.
The first pressure curve for the known liquid may be determined with the same aspiration and dispensing steps as the pressure curve for the unknown liquid.
The determined physical parameters of the liquid may be output to a user of the laboratory automation device, for example for planning an assay procedure with the liquid.
According to an embodiment, the method further comprises: storing the physical parameters in a liquid class for the liquid; and optionally performing an assay procedure with the liquid using the liquid class. A predefined liquid class may be selected and the physical parameters there may be adjusted to the determined values. Also a new liquid class may be defined with the determined values.
It also may be that a liquid class for the liquid is stored in the control device. A liquid class is a data structure used by the control device and/or the laboratory automation device for handling the liquid. For example, the liquid class sets, how fast the liquid is aspirated and dispensed during specific steps of an assay procedure. Another example for a parameter in the liquid class is an accuracy correction or the wait time after aspiration. An assay procedure may be a predefined set of operations that are automatically performed by the laboratory automation device for processing the liquid.
A further aspect relates to a computer program for determining physical parameters of a liquid, which computer program, when being executed by a processor, is adapted to carry out the steps of the method as described above and below. The computer program may be executed in a computing device, such as a control device of the laboratory automation device and/or a PC, which may be communicatively interconnected with the laboratory automation device. It also is possible that the method is performed by an embedded microcontroller of the laboratory automation device.
A further aspect relates to a computer-readable medium, in which such a computer program is stored. A computer-readable medium may be a floppy disk, a hard disk, an USB (Universal Serial Bus) storage device, a RAM (Random Access Memory), a ROM (Read Only Memory), an EPROM (Erasable Programmable Read Only Memory) or a FLASH memory. A computer-readable medium may also be a data communication network, e.g. the Internet and/or a cloud storage, which allows downloading a program code. In general, the computer-readable medium may be a non-transitory or transitory medium.
A further aspect relates to a laboratory automation device.
According to an embodiment, the laboratory automation device comprises a pipetting arm for carrying a pipette; a pressure device for changing a pressure in a volume connected to the pipette for aspirating and dispensing a liquid medium in the pipette; a pressure sensor for pressure measurements in the volume connected to the pipette and a control device for controlling the pump and the pipetting arm and for receiving a pressure signal from the pressure sensor, wherein the control device is adapted for performing the method as described above and below.
It has to be understood that features of the method as described in the above and in the following may be features of the control device, the computer program and the computer-readable medium as described in the above and in the following and vice versa.
These and other aspects will be apparent from and elucidated with reference to the embodiments described hereinafter.
The pipetting arm 12 may move the pipette 14 and the pipette tip 16 in three dimensions, may lower the pipette tip 16 into the sample container 18 and may retract the pipette tip 16 therefrom.
The pipette 14 may contain a filter 20, which prevents entering substances from the pipette 14 into the remaining parts of the laboratory automation device 10.
In the sample container 18, a liquid 22 is contained. When the pipette tip 16 is immersed in the liquid in the sample container 18, the liquid can be aspirated into the pipette 14.
The laboratory automation device 10 comprises a pump 26, which is connected via a hose 30 with the pipette 14. With the pump 26, a pressure may be applied to the hose 30 and to the pipette 14, or more general to a volume 30 connected with the pipette 14, which causes the pipette 14 to aspirate or dispense the liquid 22 or air. For example, the pump 26 comprises a plunger 28, which is moved for generating underpressure and overpressure in the hose 30 and the pipette 14. Any other kind of pumps, e.g. peristaltic pumps, or in general any source of vacuum and pressure may be used. The source of vacuum and pressure may be controlled via valves.
A pressure sensor 32, which may be attached to the hose 30 and/or the pipette 14, is adapted for measuring a pressure in the hose 30 and/or the pipette 14.
A control device 34 of the laboratory automation device 10, which may be a part of the laboratory automation device 10 or connected thereto, may control the pipetting arm 12, the pump 26 and may receive a pressure signal from the pressure sensor 32.
From the pressure curve 40, physical parameters of the liquid 22, such as a surface tension, a wetting angle, a viscosity, etc., can be determined. This may be done by the control device 34 during the steps described in the following or after the complete pressure curve 40 has been measured.
A further graph shows the activity 42 of the pump 26. The activity 42 indicates, whether the pump 26 is operating (upper level of graph) or not (lower level of graph).
The two lines 44 show, when the pipette tip 16 is immersed in the liquid 22. Otherwise, the pipette tip 16 is surrounded by air above the liquid 22.
In region “AA”, air is aspirated with the pipette 14 through the pipette tip 16. In “AD”, air is dispensed. In “LA”, liquid 22 is aspirated. In “LD”, liquid 22 is dispensed. In general, aspiration of air and/or liquid is caused by lowering the pressure 40 in the pipette 14 and dispensing is caused by raising the pressure 40.
During the following test sequence, it is important that the interior surface of the pipette 14 is wetted solely one time. The test sequence is chosen, such that firstly the liquid level inside the pipette is only raising (“LA”) and after that, the liquid level is solely falling (“LD”). Air and liquid 22 is aspirated and dispensed with the laboratory automation device 10 in such a way, that a liquid level in the pipette 14 solely rises in a first step (“LA”) and solely lowers in a second step (“LD”), such that an interior surface of the pipette 14 is wetted with liquid solely one time.
Furthermore, at the beginning of the following test sequence it is important that an unused pipette 14 is used, i.e. that the pipette 14 is empty and that no liquid 22 is in the pipette 14 and in particular was not in the pipette 14, i.e. was not wetted with a liquid 22 before. In such a way it is assured that no liquid 22 is still wetting the interior surface of the pipette 14 and that there is solely pure air inside without any remaining such as water vapor or other gases.
In the beginning, the pipette tip 16 is outside the liquid 22. The sensor 32 needs not be calibrated to 0 and therefore, at the beginning, the pressure 40 is not shown at zero level in
The first peaks 46 in the pressure curve 40 are caused by picking up the pipette 16 with the arm 12.
In step S10, the filter 20 is tested with air. Air is aspirated into the pipette 14 (peak 50), dispensed (peak 52). From the pressure difference, the filter resistance can be calculated by dividing the flowrate through the pressure difference. The flowrate may be determined from a movement difference of the plunger 28, or more general from the speed of the pump 26. In particular, a first filter resistance r is calculated from the flowrate q1 and pressure difference Δp1 between 50 and the neutral pressure level.
Additionally, a second filter resistance r2 is calculated from the flowrate q2 and pressure difference Δp2 between 52 and the neutral pressure level.
Before lowering the pipette 14 into the sample container 18 for a first time, air is aspirated and dispensed into the pipette 14. A filter resistance r1, r2 of the filter 20 inside the pipette 14 is determined from the pressure curve 40 during this aspiration and/or dispensing procedure.
An aspirating-dispensing asymmetry may be determined from the measured pressure values during aspirating and dispensing air in this step, in particular from the first filter resistance r1 and the second filter resistance r2. For example, when their difference is greater than a threshold, an asymmetry is detected and a problem with the filter 22 and/or the procedure may be identified. An average filter resistance r may be determined as average of the first and second filter resistance r1, r2.
In step S12, firstly air is aspirated again into the pipette (peak 54). This is in preparation for the following, as air needs to be aspirated into a plunger based device 10 to be able to dispense air. However, also other types of pumps may be used.
The pipette tip 16 is lowered into the liquid 22. After that, the pressure 40 is raised in the pipette 14 and bubbles are generated at the pipette tip 16. When they grow beyond the radius of the pipette orifice, the pressure drops, resulting in the peaks 58 and these bubbles detach from the pipette tip 16. From the bubble pressure pp at each peak 58, the surface tension σ of the liquid 22 can be calculated.
Where r0 is the orifice radius of the pipette tip 16, g is the gravity acceleration, s is the submerge of the tip orifices (usually 1-2 mm) and p is the density of the liquid 22. Here, it is firstly assumed that p is the density of water. If the later determined density of the liquid 22 deviates for example less than 20% of that from water, this has enough accuracy. Otherwise, the surface tension σ and the following values may have to recalculated with the later determined density.
The bubble pressure
is the maximum of the pressure pmeas at the respective peak 58, when the bubble leaves the tip 16, from which the neutral pressure level p0 and the filter pressure pFilter are subtracted. The filter pressure pFilter=Iν *r is the product of flowrate Iν and filter resistance r. The flowrate l may be determined from the volume change caused by the plunger 28 or more general from the activity of the pump 26.
After lowering the pipette 14 into the sample container 18 for the first time, air is dispensed into the liquid 22 and at least one bubble is generated in the liquid 22. A surface tension σ of the liquid 22 is then determined from the measured pressure curve 40 during generating the one or more bubbles.
From the values of the surface tension σ for each bubble and/or peak 58, also a mean of the surface tension can be calculated. A difference of the surface tension per bubble with the mean surface tension of more than a threshold may indicate a problem with the procedure.
In step S14, the pipette tip 16 is retreated from the liquid 22. Remaining liquid 22 and in particular a potential drop below the tip is removed from the tip by blowing air from the tip (peak 60). After generating the one or more bubbles, the pipette 14 is withdrawn from the liquid 22 and air is dispensed to remove remaining liquid 22 from the pipette tip 16.
Air is then aspirated again (peak 62), to fill up the system behind the pipette 14 with air.
In step S16, the pipette tip 16 is lowered into the liquid 22 again and with several small aspirations (peaks 64) it is tested, when liquid 22 enters the pipette 14. This gives a first estimate of the wetting angle αws (in theory the static wetting angle), to decide if the wetting angle is below 90 degree or above and if above a first estimate. If the pressure rises right after the pipette tip 16 has touched the liquid surface, this means that liquid 22 went into the pipette tip 16 and that the wetting angle is below 90°. If no liquid 22 directly went into the pipette tip 16, the pressure required for liquid 22 to come into the pipette tip 22 gives a first estimate of the wetting angle. In the present example, at the first aspiration in step S16 the pressure just drops, which means no liquid 22 is in the pipette tip 22. After the second aspiration is step S16 the pressure rises again after the drop which means that liquid 22 came in. The wetting angle αw can be determined via
where pt is the measured pressure with hydrostatic pressure subtracted after the last step of S16, r0 is the orifice radius, σ is the surface tension, αt is the tip angle, i.e. the opening angle of the pipette tip 16 at the orifice. This formula also may be used for the wetting angle determination with respects to peaks 68 and 72 below.
In step S18, the raise in pressure caused by gassing out of the liquid 22 is determined, i.e. its volatility ν.
The formula for the ideal gas law p*V=n*R*T (also called general gas equation) can be used to relate the amount of substance (gas) in mol to the pressure in Pascal. Similarly, the change rate of amount of substance or volatility ν in mol/s can be related to the change rate of pressure in Pascal per second.
It is waited without aspirating and dispensing for a specific waiting time period without active pressure change. A volatility ν of the liquid 22 is determined from the measured pressure curve 40 during the time period.
In step S20, first an amount of liquid 22 is aspirated into the pipette 14 (peak 66), until the liquid level reaches the section of the pipette 16, which is close to a cylindrical shape. The position of the liquid level may be determined from the flowrate of the pump 26 and a shape model of the pipette 14 and/or the aspirated volume, which may be determined from the movement of the plunger 28. A small, deviation comes from the volatility ν of the liquid 22, which may be corrected, when the volatility has been determined (see below).
Then, liquid 22 is aspirated causing peak 68, from which the advancing wetting angle αwa can be calculated (see formula above).
After that, the liquid 22 is aspirated with a higher speed and/or higher flowrate causing peak 70. From this, a first viscosity μ1 of the liquid 22 can be calculated. At this time, the liquid level 22 has reached a second defined value.
For determining the viscosity, the Hagen-Poisseuille formula may be used, which has to be integrated along the shape of the pipette 14, in particular its conical and cylindrical sections. For a cylindrical section, the result is
where pHP is the pressure during a constant flowrate, L is the length of the cylindrical section, r0 is the radius of the cylindrical section, and Iν is the flowrate.
Then, liquid 22 is dispensed causing peak 72, from which the receding wetting angle αwr can be calculated (see formula above).
After that, the liquid 22 is dispensed with a higher speed and/or flowrate causing peak 74. From this, a second viscosity μ2 of the liquid 22 can be calculated. From the first viscosity μ1 and the second viscosity μ2, a mean viscosity u of the liquid 22 can be calculated.
In general, the wetting angle away αwa, αwr of the liquid 22 is determined from the pressure curve 40 during a time period with continuously raising and/or lowering of the liquid level in the pipette 14. In particular, the advancing wetting angle αwa is determined for a raising liquid level and/or the receding wetting angle αwr, is determined for a lowering liquid level.
Furthermore, the viscosity μ1, μ2 of the liquid 22 is determined from the pressure curve 40 during a time period with continuously raising and/or lowering of the liquid 22 in the pipette 14.
From the advancing wetting angle αwa and the receding wetting angle αwr, the wetting angle hysteresis can be calculated as the difference of these two angles.
From the pressure difference Δp between the points 76, where the first liquid level and the second liquid level have been reached, the density p of the liquid 22 can be calculated by
where g is the gravity acceleration and h is the difference between the first and second liquid level.
The density p of the liquid 22 is determined from the pressure curve 40 from two pressure values 76 of the pressure curve 40 at two times with two different known liquid levels.
As described above, the physical parameters, such as surface tension σ, volatility ν, wetting angle αwa, αwr, viscosity μ1, μ2 and density p, are determined from a set of equations modelling the liquid 22 and the pipette 14. Examples of such equations are provided above. It can be seen that the set of equations comprises the physical parameters of the liquid 22 and additionally parameters of the pipette 14, such as the orifice radius r0.
The pipette parameters may be stored in the control device 34 for specific types of pipettes and/or may be measured manually before the physical parameters are determined.
It is also possible that the pipette parameters are determined in first pass of performing the method, however, with a liquid, for which the physical parameters are known. This may be done with a pipette of the same type as the pipette, which is used for determining the physical parameters. With the aid of the same set of equations, the pipette parameters then can be determined. The first pass with the known liquid may contain the same aspiration and dispensing steps as the second pass with the unknown liquid, in which the physical parameters of the unknown liquid are determined. The first pass may be performed before or after the second pass.
While the embodiments described herein have been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive; the invention is not limited to the disclosed embodiments. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art and practising the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. A single processor or control device or other unit, such as an FPGA, may fulfil the functions of several items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims should not be construed as limiting the scope.
| Number | Date | Country | Kind |
|---|---|---|---|
| 22213596.4 | Dec 2022 | EP | regional |
