Patent Grant
11313703
This application claims priority to German Patent Application DE 10 2018 130 299.1, filed Nov. 29, 2018, which is incorporated herein by reference in its entirety.
The invention relates to a sensor device with sensor elements which show an optical behavior dependent on an analyte, as well as to a corresponding measuring method.
The optical monitoring of biological structures such as two-dimensional or three-dimensional cell cultures is currently carried out using oxygen- and pH-sensitive dyes in cell culture media (Weyand et al., Biores. Open Access 4, 266-277 (2015)). In some applications this cannot be done without disturbances, as some cells do not tolerate this indication and the interaction with the dye significantly distorts the result.
In addition, there are numerous systems for the measurement of marker molecules, proteins, nutrients and metabolites outside the culture. These require sampling and elaborate sample preparation as well as sophisticated analytical techniques such as capillary electrophoresis, mass spectroscopy or enzymatic assay systems. Sampling removes part of the medium, which can mean the end of cultivation, especially with small culture volumes in 96-well plate format.
Some parameters can be observed directly in the cell medium. Phenol red, for example, is a component of most culture media (approx. 15 mg/L) and serves as a pH indicator as well as an indicator of bacterial contamination.
Fluorescent proteins such as GFP, which are expressed in the cell, provide another way of carrying out investigations in living cells. However, this requires genetic manipulation of the cells, which is not permitted in the case of subsequent medical application of the cell clusters.
In contrast to alternative methods such as fluorescence microscopy, the invention should be able to determine the parameters directly in the process without sample preparation. It should also be possible to use the sample after observation without any processing steps. This is the only way to optimize the process, as this is the only way to ensure that cultivation is not influenced during the measurement.
The advantages of the invention lie in the simplified, miniaturized measuring methodology and its simple application and the possibility of working in complex samples under sterile conditions. The invention determines several (bio)chemical parameters in real-time and with spatial resolution without contamination. In particular, the possibility of determining dissolved CO2 concentrations in biological samples provides a new perspective for studying and optimizing cell growth and metabolism.
The overriding interest in solving the problem lies in the constantly increasing demand for three-dimensional cell cultures, especially in research and development as well as in the field of regenerative medicine. Unfortunately, the extremely high demands on the vitality of the cells of >5% in spheroids, e.g. for use in the transplantation of chondrocytes (cartilage cells), lead to corresponding failure rates in the cultivation of the cells. This in turn leads to immense costs for cell-based therapeutics, caused by the many parallel cultivation approaches. This failure rate could be reduced by up to 20% by targeted cultivation monitoring.
Three-dimensional signal acquisition makes it possible to differentiate between cells at different positions in the cell compound. Since the measurement does not require sampling and the sensor elements and light guides are designed in such a way that they do not inhibit cell growth, further cultivation of the culture is also possible after the measurement without any problems.
Overall, the concept enables, for example, early detection of nutrient deficiencies or contaminations before they become visible during a morphological microscopic revision of the cells, thus enabling timely intervention.
US patent application US 2018/0292393 A1 relates to a device and associated method for the measurement of properties of biological samples. A lid for a microtiter plate is provided with protrusions at the end of which sensors are mounted. When the lid is placed on the microtiter plate, a protrusion dips into each well of the microtiter plate. The sensors are read through the bottom of the microtiter plate. With such an arrangement, maintaining an exact distance to the bottom of the respective well is problematic. The lid is placed as a unit on the microtiter plate; in addition to tolerances in the production of the protrusions, there are also tolerances in the formation of the individual wells, which cannot be compensated for by spacers for the lid due to their individual nature. With this type of lid, one is limited to microtiter plates of a suitable size as sample carriers. It is not possible to record the distribution of the analyte at defined positions.
It is also known to attach sensors to the ends of individual light guides and to position these ends of the light guides in a sample. This results in difficulties with the exact positioning of the sensors in the sample and also with the passing of the individual light guides through the sample. A bundled passing of several such light guides is also possible, which however results in a restriction regarding the positioning of the light guides in relation to each other in the sample, see the article “The multi fiber optode (MuFO): A novel system for simultaneous analysis of multiple fiber optic oxygen sensors” by J. P. Fischer et al., in Sensors and Actuators B: Chemical, Volume 168, pages 354-359, 2012.
It is also known to address the individual wells of a microtiter plate and the sensors located therein via individual light guides, and to bundle the opposite ends of the light guides onto a smaller surface in order to adapt to the format of detector chips, see the dissertation of Gregor Liebsch, “Time-Resolved Luminescence Lifetime Imaging with Optical Chemical Sensors”, University of Regensburg, 2000. Here, too, it is not possible to record the distribution of the analyte at defined positions in the sample.
The international patent application PCT/IB2018/054575 discloses a sensor foil inclined against the horizontal in a sample volume, so that values of the analyte can be recorded at different distances, e.g. from a bottom of the sample container. The various holding devices for the inclined sensor foil represent a noticeable intervention in the sample volume.
It is an object of the invention to provide a sensor device with which an analyte in a sample can be measured at defined positions within the sample volume, whereby the required interventions in the sample volume are to be reduced. A corresponding measurement procedure also is to be specified.
The object with regard to the sensor device is achieved by a sensor device according to claim 1. Claims 10 and 11 relate to manufacturing methods for the sensor device. Claims 12-14 relate to corresponding measuring methods.
The dependent claims relate to respective advantageous embodiments.
The sensor device according to the invention comprises a plurality of light guides. Each light guide has a first end and a second end. The sensor device comprises a plurality of sensor elements. Each sensor element has an optical behavior that depends on at least one analyte. Each sensor element of the plurality of sensor elements is located on a second end of a light guide of the plurality of light guides. According to the invention, the first ends of the light guides are arranged on a carrier at a respective defined position and the second end of each light guide of the plurality of light guides is at a defined perpendicular distance to the carrier. In this way, an analyte can be measured at defined distances from the carrier; in particular, one is not limited to attaching sensor elements to walls of a sample container. The defined arrangement of the light guides on the carrier also eliminates the difficulty of arranging individual light guides in a defined manner in a sample and of fixing them in their respective positions. The carrier with the light guides is intended to be inserted into a sample container unless the carrier itself already forms part of a sample container.
The light guides are sufficiently stable of shape in the sense that the light guides are not significantly deformed either under their own weight or by the effect of a sample in which at least one analyte is to be measured. A significant deformation here is to be understood as a deformation in which the position of the second end of the light guide relative to the carrier changes to an extent which results in an unacceptable corruption of the measurement results, depending on the specific measurement task. For example, the change in position of a second end of a light guide relative to the carrier should not exceed one diameter of the respective light guide; smaller changes in position are of course preferred.
At the second end of a light guide several sensor elements may be arranged, which may be sensitive to different analytes, i.e. each of the sensor elements shows an optical behavior which depends on a respective analyte. The sensor elements may be polymer films in which a sensor substance, such as an indicator dye, is embedded. In this case, it is the sensor substance that shows the optical behavior that depends on the analyte. However, the invention is not limited to this type of sensor element. The sensor elements may also have protective layers that are permeable to an analyte but keep other substances, such as water, away from the sensor substance. The sensor elements may, for example, be generated by one or more coating processes directly at the second ends of the light guides. A different attachment of the sensor elements at the second ends of the light guides is of course also conceivable.
The optical behavior, for example, may be a change in color, a change in reflectivity, or a luminescent phenomenon. Luminescence includes phosphorescence and fluorescence. In luminescence, a relaxation time of the luminescence may depend on the analyte to be measured. Such different types of optical behavior and their exploitation for the measurement of an analyte are known to the skilled person.
According to the invention, the defined perpendicular distances of the second ends to the carrier differ for at least two light guides of the plurality of light guides. In this way, an analyte can be measured at defined different distances from the carrier and, so to speak, results can be obtained on the three-dimensional distribution of the analyte, for example on concentration gradients of an analyte in the direction perpendicular to the carrier.
Generally speaking, concentration gradients can also be measured by moving a sensor, such as a microsensor on a micromanipulator, through a liquid sample and taking measurements when the sensor is at defined positions within the sample. However, the movement of a sensor, even a microsensor, through the sample can cause local mixing of the sample, so that any concentration gradients in the vicinity of the sensor are smeared. When using a sensor device according to the invention, such a local mixing of the sample does not occur because the sensor elements do not have to be moved through the sample; nevertheless, a concentration gradient can be determined.
Sensor devices in which the second ends of all light guides of the plurality of light guides are at the same perpendicular distance to the carrier, apart from any manufacturing tolerances, are also conceivable.
In one embodiment, each light guide follows a predetermined path from its first end to its second end. In this way, a sensor device can be adapted to the geometric conditions of the sample, such as a cell culture. In the simplest case, the light guides run straight and perpendicular to the carrier, more precisely perpendicular to the surface of the carrier on which they are arranged. However, the light guides may also be inclined against this surface or have a curved form. It is always important that the position of the second end of the light guide, and thus of the one or more sensor elements at this second end, is defined relative to the carrier, especially because it is predetermined by the manufacture of the sensor device.
In one embodiment, a group of light guides from the plurality of light guides agree with regard to the sensor elements arranged at their respective second ends, i.e. all light guides in the group have sensor elements of the same type at their second ends, which in particular are sensitive to the same analyte. The group may, but does not have to, include all light guides of the sensor device. For each light guide in the group, the second end is at a different perpendicular distance to the carrier. In this way, an analyte can be measured at different distances perpendicular to the carrier. For example, the distance of the second end of a first light guide of the group perpendicular to the carrier could be 100 μm, the distance of the second end of a second light guide of the group perpendicular to the carrier could be 50 μm, the distance of the second end of a third light guide of the group perpendicular to the carrier could be 10 μm. Neither the mentioned distances nor the number of light guides of a group, however, represent restrictions for the invention.
The carrier is preferably transparent, in particular the carrier may be made of glass or a polymer. In the case of a transparent carrier, light can simply be coupled into the light guides through the carrier and light can also simply be coupled out of the light guides through the carrier.
In an advantageous embodiment, the light guides and carrier are made of the same transparent material and are materially bonded together. In particular, light guides and carrier may form a single one-piece element.
A support for a cell culture, such as a cell crown, may be provided on the carrier. The support may be integral with the carrier, or the carrier may have attachment areas for the support.
In one embodiment, one or more areas for interaction with a positioning device for the sensor device are formed on the carrier. With the positioning device, the sensor device can be placed reliably and with sufficient positioning accuracy in a sample container. For example, it would be conceivable to glue the carrier of the sensor device to a wall of the sample container, whereby the carrier is positioned by the positioning device. For example, the positioning device may hold the carrier by vacuum or the positioning device may be a gripper gripping the carrier at one or more areas intended to interact with the gripper. Other types of positioning devices are also possible. By providing certain areas for interaction with a positioning device, the danger of light guides being damaged or changed in their path by the positioning device is reduced.
In another embodiment, the carrier is formed by at least one wall of a sample container. This means that in this embodiment, the carrier with the light guides is not a separate component that can be inserted into a sample container, but the light guides are formed directly on the wall of a sample container.
The light guides can be formed by 3D printing. In addition, the carrier can also be manufactured by 3D printing. In particular, a carrier with light guides can be produced by 3D printing as a single element. This process is particularly suitable if the carrier and the light guides are made of a polymer.
In an alternative manufacturing process for a sensor device described above, the light guides are manufactured by material ablation and/or material restructuring using laser radiation. This process is particularly suitable if the carrier and light guides are made of glass. A femtosecond laser can be used, for example, in a “Laser μFAB Microfabrication Workstation” from Newport.
For example, a method to measure at least one analyte in a sample is performed as follows: At least one sensor device of the type described above is placed in a sample container. Before or after this placement, the sample is filled into the sample container. Excitation light is then coupled into at least a subset of the light guides of the sensor device, so not all light guides of the sensor device need to be used for each measurement. The excitation light is suitable to excite the optical behavior, dependent on the analyte to be measured, of at least one sensor element which is arranged at the second end of a light guide of the subset of the light guides. The response of the sensor element is light, corresponding to the optical behavior of the sensor element. This light of the response of the at least one sensor element is guided through the subset of the light guides and detected by at least one detector. The output signal of the at least one detector is evaluated to measure the at least one analyte. In a special variant of the method, a respective sensor device is arranged in each of a plurality of wells of a microtiter plate.
One variant of the method uses a sensor device according to the invention in which the carrier is a wall of a sample container. Here the sample container is filled with the sample. Excitation light is then coupled into at least a subset of the light guides of the sensor device; thus not all light guides of the sensor device need to be used for each measurement. The excitation light is suitable to excite the optical behavior, dependent on the analyte to be measured, of at least one sensor element, which is arranged at the second end of a light guide of the subset of the light guides. The response of the sensor element is light, corresponding to the optical behavior of the sensor element. This light of the response of the at least one sensor element is guided through the subset of the light guides and detected by at least one detector. The output signal of the at least one detector is evaluated to measure the at least one analyte.
In the measuring methods, the detection by a detector can be advantageously carried out by taking an image of a transparent carrier from the side of the carrier facing away from the light guides. Due to the defined arrangement of the first ends of the light guides on the carrier, each light guide can be identified in the image. Since the position of the second end of each light guide is also known, it is possible to determine in the recorded image from which location in the sample the respective signals originate.
For the optical excitation of a sensor substance and for the evaluation of the optical response of the sensor substance, the skilled person is familiar with numerous methods. Examples can be found, for example, in the German patent applications DE 10 2011 055 272 A1 and DE 10 2013 109 010 A1, as well as in prior art documents cited therein. Such methods can also be used if the sensor device according to the invention is used. The skilled person is also familiar with a large number of sensor substances and their suitability for measuring the respective analytes.
The measurement of an analyte, i.e. a substance to be detected, means that the concentration or partial pressure of the analyte in the sample is determined up to error limits customary in the field, or that it is determined if concentration or partial pressure of the analyte are within a certain range. This range can have an upper limit and a lower limit, or only an upper limit or only a lower limit.
The sample may be a cell culture medium, but the invention is not limited thereto. The sensor device according to the invention and the measurement methods according to the invention can be generally used for liquid samples, but also for gaseous samples; they can also be used for samples in the form of granular matter.
In the following, the invention and its advantages are explained in more detail using the accompanying figures.
The figures are only examples of how the invention may be configured and serve to explain and illustrate certain details of possible embodiments. Under no circumstances should the figures and their accompanying description be construed as a limitation of the invention to the embodiments depicted in the figures.
The setup described above is shown in
A camera and a ring light or a different source of illumination may of course also be used if the sample container is not a microtiter plate but is configured differently; non-restrictive examples for other sample containers would be beakers, Erlenmeyer flasks, bottles.
To perform its tasks, the control unit 500 has, for example, one or more microprocessors and memory units. The memory units contain program instructions for the execution of measurement protocols and evaluation procedures, as well as additional data required for this purpose, such as calibration data.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2018 130 299.1 | Nov 2018 | DE | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 6620612 | Bertling | Sep 2003 | B1 |
| 9719138 | Zhong | Aug 2017 | B2 |
| 20180292393 | Neilson et al. | Oct 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 10227962 | Jan 2004 | DE |
| 102011055272 | May 2013 | DE |
| 102013109010 | Feb 2015 | DE |
| 0425587 | Jun 1994 | EP |
| H10-281994 | Oct 1998 | JP |
| 2001059432 | Aug 2001 | WO |
| 2003064990 | Aug 2003 | WO |
| 2019008461 | Jan 2019 | WO |
| Entry |
|---|
| Weyand et al., Noninvasive Oxygen Monitoring in Three-Dimensional Tissue Cultures Under Static and Dynamic Culture Conditions, BioResearch, Open Access, 2015, pp. 266-277, vol. 4.1. |
| Laser μFAB Microfabrication Workstation, Data Sheet. |
| Fischer et al., The multi fiber optode (MuFO): A novel system for simultaneous analysis of multiple fiber optic oxygen sensors, Sensors and Actuators B: Chemical, 2012, pp. 354-359, v. 168. |
| Liebsch, Gregor, The Dissertation, Time-Resolved Luminescence Lifetime Imaging with Optical Chemical Sensors, Set-up, controlling, Concepts and Applications, University of Regensburg, Oct. 2000. |
| Number | Date | Country | |
|---|---|---|---|
| 20200173817 A1 | Jun 2020 | US |
