WO2025068396A1 - Disposable fluid-conducting assembly, method for producing the disposable fluid-conducting assembly, microfluidic device comprising disposable fluid-conducting assembly, and biomarker detection device - Google Patents

Abstract

The invention relates to a disposable fluid-conducting assembly (32) for a microfluidic device (12) for analyzing biomarkers in a sample of a body fluid, for example protein defects in a blood sample (212). The invention additionally relates to a microfluidic device (12) comprising the disposable fluid-conducting assembly (32), to a biomarker detection device (10) comprising the microfluidic device (12), and to a method for producing the disposable fluid-conducting assembly (32).

Description

Disposable fluid guide assembly, method for producing the disposable fluid guide assembly, microfluidic device with disposable fluid guide assembly and biomarker detection device

The invention relates to a disposable fluid guide assembly, a method for producing the disposable fluid guide assembly, a microfluidic device comprising the disposable fluid guide assembly, and a biomarker detection device comprising the microfluidic device.

Alzheimer's disease, or Alzheimer's disease (hereafter referred to as Alzheimer's), is a currently incurable, neurodegenerative disease in which nerve cells in the brain steadily die, leading to personality and behavioral changes in those affected as the disease progresses. Millions of people worldwide are affected by Alzheimer's disease.

An early diagnosis of Alzheimer's is particularly important for the course of the disease, as although Alzheimer's is not yet curable, its steady progression can be slowed with early treatment. The earlier treatment is started, the more beneficial it is. Early and reliable diagnosis therefore represents a key challenge in diagnostic medical technology in order to be able to intervene in a timely manner and slow the progression of the disease. Prediagnostic methods play a special role in this regard, as they can be used to predict the risk of a clinical Alzheimer's diagnosis in advance, allowing therapeutic measures to be initiated even before the clinical onset with symptoms of the disease.

Known prediagnostic methods for predicting the risk of Alzheimer's disease are based on the analysis of specific protein defects that develop in the human body decades before the clinical onset of Alzheimer's disease. The analysis of such protein defects enables predictions about the likelihood of developing Alzheimer's disease. From a scientific perspective, It is assumed that misfolding of certain proteins, such as ß-amyloid (Aß) peptides, occurs in the early stages of Alzheimer's disease. According to current research, the misfolding and resulting aggregation of the peptides into beta-sheet-enriched amyloid plaques is crucial for the course and progression of Alzheimer's disease.

For this reason, the presence of misfolded ß-amyloid (Aß) peptides, for example, in the blood plasma of test subjects, is a sign of possible Alzheimer's disease and can be an important indicator for Alzheimer's risk prognosis. Thus, the misfolded ß-amyloid (Aß) peptide represents a candidate biomarker peptide that can be used as a biomarker in prediagnostic methods.

In the field of protein diagnostics, there are a number of methods for detecting candidate biomarker peptides in samples. For example, methods such as enzyme-linked immunosorbent assays (ELISA), surface plasmon resonance spectroscopy (SPR), or surface-based fluorescence intensity distribution analysis (sFIDA) can be used for this purpose. However, it has been found that the aforementioned methods only provide indirect information about structural defects or protein misfolding. Furthermore, these methods require very complex sample preparation and implementation and are designed for low sample throughput, making them unsuitable for large-scale clinical applications.

Another method in the field of protein diagnostics is the immuno-infrared sensor assay (hereinafter referred to as immunoassay), which allows direct measurement of misfolded ß-amyloid (Aß) peptides in body fluids such as blood, blood plasma, blood serum or cerebrospinal fluid without prior isolation and preparation of candidate biomarker peptides.

Such an immunoassay is disclosed, for example, in US 2020 / 0 141 866 A1. The immunoassay described is particularly concerned with the protein diagnostics of misfolded amyloid-ß (Aß) peptides for the risk prognosis of Alzheimer's disease. The basic principle of the method is to attach a antibody, which in turn can specifically bind candidate biomarker peptides based on (Aß) structures.

For this purpose, in a first preconditioning step, a sensor crystal, for example an ATR (attenuated total reflection) sensor crystal such as a germanium or silicon single crystal, is surface-treated with the silane- or thiol-linker-containing conditioning fluids. In a second antibody conditioning step, the sensor surface is surface-treated with an antibody-containing conditioning fluid. In a third sample application step, the sensor is then surface-treated with a sample fluid from a test subject, for example blood plasma, blood, or blood serum, whereby candidate biomarker peptides based on (Aß) structures bind to the antibody-coated sensor surface. In a fourth step, the measuring step, this is irradiated with an IR laser, which passes through the sensor through multiple internal total reaction and records an IR spectrum of the candidate biomarker peptides based on (Aß) structures bound to the sensor surface of the sensor element. The IR spectrum recorded by the bound candidate biomarkers is then evaluated, for example by quantifying the shift of the IR bands of the candidate biomarker peptides based on (Aß) structures with comparative measurements, in order to make a risk prediction about the possible onset of Alzheimer's disease with respect to the sample under investigation.

However, such immunoassays for Alzheimer's risk prediction are in an early phase of development and have so far only been conducted on a laboratory scale and as proof-of-concept trials. In particular, the development of such an immunoassay from the laboratory scale to industrial, large-scale medical application represents an immense challenge.

In known immunoassays, individual devices are used to carry out the above-mentioned steps, which have a number of disadvantages, which are discussed below.

Typically, known immunoassays are based on a flow cell that has a fluid port at each of its opposite ends. Fluid ports are fluidically connected to a common reservoir, so that the sample to be examined is pumped via a peristaltic pump along a circuit between the flow cell and the reservoir.

However, flow cells are costly and require complex preparation. Therefore, time-efficient throughput of larger sample volumes is not possible, and analysis is limited to individual samples.

The use of a peristaltic pump also increases the risk of sample fluid contamination. To avoid this, it is necessary to regularly clean the peristaltic pump, for example, by autoclaving it, to prevent cross-contamination between different sample fluids.

Furthermore, the manual assembly and disassembly of the experimental setup between measurements complicates the reproducibility of the immunoassay and thus an efficient sample throughput.

Furthermore, the conditioning of the sensor surface and the subsequent sample application with the sample fluid do not take place in the same flow cell, so multiple specialized devices are required for sample preparation and measurement. This procedure is time-consuming and increases the risk of sample fluid contamination, as the sensor is passed back and forth between devices for conditioning and sample application.

Parkinson's disease and amyotrophic lateral sclerosis (ALS) should also be able to be predicted early by analyzing specific protein defects in the blood. The invention is therefore intended to encompass, among other things, a device and a method for conditioning sensor elements and analyzing protein defects using the sensor elements for these diseases, i.e., more generally, for preparing and performing an analysis of protein defects.

In this respect, the object of the present invention is to provide a disposable fluid guide assembly, a method for producing the disposable Fluid guide assembly, a microfluidic device with the disposable fluid guide assembly and a biomarker detection device, for example a protein defect diagnostic device, with the microfluidic device, with which at least one disadvantage known from the prior art is overcome.

The object is achieved according to the invention by a disposable fluid guide assembly according to claim 1.

Advantageous aspects of the invention are given in the subclaims, which can optionally be combined with one another.

According to the invention, the disposable fluid guide assembly for a microfluidic device for detecting molecular biomarkers in a body fluid sample, e.g., for analyzing protein defects in a blood sample, comprises a lower part with a fluid side and an opposite lower side, and an upper part with an upper side and an opposite pneumatic side adjacent to the fluid side of the lower part. The upper part on the pneumatic side and the lower part on the fluid side each have a plurality of channels formed by grooves. Furthermore, the disposable fluid guide assembly provides at least one sealing element that fluidically separates pneumatic channels in the upper part, arranged opposite one another between the fluid side and the pneumatic side, from fluid channels in the lower part. An interaction chamber open to the lower side is formed in the lower part and can be closed by a sensor element attachable to the lower side and preferably flush with the lower side. Between the pneumatic side and the fluid side, diaphragm valves are formed by the sealing element or other sealing elements, via which fluid channels leading to and away from the interaction chamber can be opened and closed.

The invention is based on the idea of providing a fluid guide assembly designed for single use in a microfluidic device for sample application of a body fluid to a sensor element for biomarker detection, for example, protein defect diagnosis, and/or for conditioning a sensor element for biomarker detection. By introducing a single-use function, contamination The cross-contamination of sample fluids with conditioning fluids, or cross-contamination between different sample fluids, can be easily prevented because the "used" disposable fluid guide assembly can be disposed of after each sample run and replaced with a "fresh" disposable fluid guide assembly. The same applies to the sample application of a body fluid. This eliminates the time-consuming cleaning of the fluid-carrying channels and the associated valves.

Preferably, all valves that do not come into direct contact with the sample are located in the device but outside the disposable fluid guide assembly in order to have as few complex parts as possible in the disposable fluid guide assembly.

Furthermore, the design with an upper part, a lower part, and an intermediate sealing element represents a particularly efficient and compact fluid guide. In this design, the sealing element provides a sealing effect between the upper and lower parts and also a control effect that can be used to switch a fluid in the fluid channels. In particular, the introduction of diaphragm valves into the disposable fluid guide assembly shifts the complexity of the fluid guide from a microfluidic device to the disposable fluid guide assembly, thereby streamlining the periphery of the disposable fluid guide assembly. This also works synergistically with the disposable functionality of the fluid guide assembly, as the diaphragm valves contaminated with sample fluid can be disposed of after the sample fluid has passed through. This eliminates the need to clean the fluid control system, and the disposable fluid guide assembly enables higher sample throughput without time-consuming cleaning steps. The upper and lower parts can also be easily manufactured from plastic, e.g., by injection molding.

Furthermore, the design of the interaction chamber is particularly advantageous because it is constructed in such a way that it can be sealed fluid-tight from the outside by the sensor element without the need for additional components. The sensor element thus already forms a kind of lid for the interaction chamber.

The terms “top and bottom” are not to be interpreted in a restrictive sense, but merely serve to distinguish the Sides and alignment of the upper and lower parts relative to each other. The upper part is preferably inserted into a microfluidic device with its upper side facing upwards. The upper and lower parts can each be formed as a single piece or assembled from multiple parts.

The term "interaction chamber" refers to a chamber in which at least one fluid flowing through the fluid channels can be brought into contact with the sensor element in order to interact with the surface of the sensor element. The term "chamber" is not intended to be restrictive; it can also refer to a chamber section, a channel, or a channel portion that is open and engageable with a sensor element. In this respect, at least the application of a sample of a body fluid to the surface of the sensor element takes place in the interaction chamber.

A "body fluid" is understood to mean a fluid obtained from a human or animal body, in particular a fluid obtained from a human body. Examples of body fluids include blood, a blood component such as blood plasma or blood serum, lymph, cerebrospinal fluid, intestinal fluid, eye fluid, lung fluid, saliva, and urine. The body fluid can be, for example, blood, blood plasma, blood serum, or cerebrospinal fluid, also known as cerebrospinal fluid or spinal fluid.

The term "body fluid sample" refers to a sample fluid from a subject that is to be tested for a biomarker. Furthermore, the terms "body fluid sample" and "sample fluid" are used synonymously.

A body fluid sample may be a blood sample, i.e. a sample in which the body fluid includes or is blood plasma, blood or blood serum or, more generally, processed blood.

A "biomarker" is a molecular biomarker. The biomarker can be, for example, a protein, a protein complex, a peptide, an antibody, a cell such as a tumor cell, a nucleic acid, an aptamer, or a mixture thereof. The biomarker can be a candidate biomarker peptide or a candidate biomarker protein that undergoes conformational transitions associated with disease progression, for example, an amyloidogenic peptide or a peptide with a characteristic secondary structure composition dependent on the health state. In this case, biomarker detection enabled by the microfluidic device represents a protein defect diagnosis.

Examples of such biomarkers are ß-amyloid (Aß) peptides and tau protein (associated with Alzheimer's disease), alpha-synuclein (associated with Parkinson's disease), prion protein (associated with Creutzfeldt-Jakob disease) or huntingtin protein (associated with Huntington's disease), TDP-43 (associated with amyotrophic lateral sclerosis, ALS) and islet amyloid polypeptide (hIAPP) (associated with diabetes).

In an embodiment in which the sample of a body fluid is a blood sample, the microfluidic device is a device for applying a blood sample to the sensor element for a protein defect diagnosis and/or for conditioning the sensor element for a protein defect diagnosis.

The term “blood sample” also includes blood plasma and blood that has already been treated or processed.

Depending on the embodiments explained below, in addition to the sample application, the conditioning, i.e. the surface treatment of the sensor element surface with a linker-containing or antibody-containing conditioning fluid, as well as the measurement process on the sensor element surface can be carried out in the interaction chamber.

In principle, the interaction chamber can have any shape and geometry. However, it is preferred that the interaction chamber has a larger cross-section, at least in one direction, compared to the other channels in the disposable fluid guide assembly in order to slow the fluid flow and allow the fluid to interact with the sensor element for a longer time.

A “sensor element” refers to any sensor element suitable for protein diagnostics using FTIR spectroscopy. A "channel" or "fluid channel" refers to a tubular connection designed to carry a fluid. The term "channel" or "fluid channel" can also refer to a channel section.

The terms “fluidic” and “fluid” used in this application refer exclusively to liquids.

For example, the conditioning fluid can be selected from the group consisting of distilled water, isopropanol, rinsing fluid, PDS, NaPi, MEA, antibody fluid, TBS, various linker fluids, such as linkers based on silanes or thiol ethers, and Tbd.

According to a first aspect of the invention, it is provided that the upper part has pneumatic channels opening at the top, which end at associated diaphragm valves in order to switch them.

Pneumatic channels represent a simple design for fluidly connecting and switching the top of the upper part with the diaphragm valves located inside the one-way fluid guide assembly. For example, the pneumatic channels can extend vertically and without interruption through the upper part to the diaphragm. However, it is also conceivable for the pneumatic channels to have differently shaped sections that form a common pneumatic channel that connects the diaphragm valve to the top of the upper part. The pneumatic channels can all have the same shape or be shaped independently of one another.

According to a further aspect of the invention, the lower part has fluid channels opening at the bottom and leading to opposite ends of the interaction chamber, which form media channels for the flow of medium for conditioning the surface.

The term “medium” refers to a conditioning fluid or a fluid that is necessary for the conditioning process, i.e. for preparing the sensor element surface for sample application. Media channels represent a simple design for fluidically connecting the interaction chamber to the outside of the lower part. Furthermore, the opening of the media channels on the underside of the lower part ensures particularly bubble-free introduction of medium into the disposable fluid guide assembly. The occurrence of bubbles or air-fluid turbulence in the fluid channels of the disposable fluid guide assembly is undesirable, as these can lead to an irregular fluid flow and thus impair the connected sensors for monitoring the fluid flow.

Furthermore, it's easy to quickly and securely connect the external connections to the ports on the one-way fluid guide assembly, ensuring a tight seal. All pneumatic connections are located on the top and the media connections on the bottom. For example, it's possible to combine connections in blocks into one piece, which is then simply clamped against the top or bottom.

By providing media channels, the disposable fluid guide assembly is designed to precondition a sensor in the interaction chamber for sample application, i.e., to condition it with at least one medium. This eliminates the need to condition the sensor element outside the disposable fluid guide assembly using a separate device. The interaction chamber thus fulfills a dual function, making the disposable fluid guide assembly particularly space-saving.

In particular, sensor windows are provided in the upper or lower part, which extend adjacent to the opposite ends up close to the fluid channels.

The sensor windows provide a clear view of the fluid channels leading to and from the interaction chamber, allowing fluid flow in these channels to be optically monitored. For example, bubbles or a gas or fluid front can be detected via the sensor windows. In principle, the sensor windows can have any geometry, as long as they allow a fluid flow through the fluid channels to be visible to the outside. Therefore, the term "close" means that the sensor windows are Depending on the optical density of the upper and lower parts, they extend from the top and/or the bottom to the fluid channels until they are optically accessible for a sensor system.

Media channels can open at the opposite ends of the interaction chamber, each leading to a media connection in an outer surface of the upper or lower part.

Due to the opposing arrangement of media channels in the interaction chamber, the chamber can be completely permeated by a medium conveyed in the media channels along a longitudinal direction. This allows a sensor element inserted into the interaction chamber to be brought into particularly uniform contact with the medium conveyed in the media channels.

A further aspect of the invention provides that the upper part has at least one first sample receptacle on the upper side, which is fluidically connected to a fluid channel designed as a sample channel, which can be selectively connected to the interaction chamber via a diaphragm valve.

In other words, the disposable fluid guide assembly contains an integrated sample receptacle. This makes the samples to be analyzed particularly easy to handle, as they can be introduced into the disposable fluid guide assembly without the need for any additional separate device. Thus, the interaction of the sample with the sensor element and the necessary fluid flow are limited to the disposable fluid guide assembly. Accordingly, cleaning of peripheral devices is eliminated, as the disposable fluid guide assembly can be disposed of together with the sample receptacle after a single sample run. This ensures particularly low-contamination work.

The sample receptacle refers to a section of the disposable fluid guide assembly that acts as an inlet through which samples can be introduced into the sample channels so that they can pass through the fluid channels into the interaction chamber.

In particular, the sample holder may have the form of a chamber or a molded container into which the samples can be inserted. Alternatively, a container forming a sample receptacle, structurally separate from the upper and lower parts, can be provided, attached to the upper or lower parts. This container is fluidically connected to a fluid channel designed as a sample channel in the disposable fluid guide assembly, which can be selectively connected to the interaction chamber via a diaphragm valve.

The term "blood sample" refers to the sample fluid of a subject to be tested for candidate biomarkers that may indicate a later diagnosis of Alzheimer's disease or another neurodegenerative disease. The blood sample may include, for example, blood plasma, cerebrospinal fluid, blood or blood serum, or, more generally, processed blood. Furthermore, the terms "blood sample" and "sample fluid" are used synonymously.

A further aspect of the invention provides that the sample receptacle is formed by a cavity, i.e. a chamber, in the upper part and an adjoining cavity, i.e. a chamber, in the lower part and the sample channel extends from the cavity in the lower part.

The sample holder design described here creates a fluidic connection from the upper part via the lower part to the interaction chamber located therein. In addition, the sample can be easily introduced into the disposable fluid guide assembly from above, i.e., viewed from the top. This particularly simplifies the handling and introduction of the sample liquid, as this is often still manually pipetted into the sample holder.

In addition, the sample can be introduced spatially separately from the media, which are preferably introduced into the fluid guide assembly via the underside of the lower part, thus ensuring low-contamination fluid guidance and introduction.

According to a further aspect of the invention, a second sample receptacle is formed in the upper part, which is fluidically connected to the interaction chamber and the first sample receptacle via a sample channel. Here, too, the second sample receptacle can alternatively be designed as a separate container that is fluidically coupled to the upper part or the lower part. This arrangement allows sample fluid to flow from the first sample receptacle through the first sample channel into the interaction chamber, then into the second sample channel into the second sample receptacle, and vice versa. For example, one sample receptacle can serve as the initial reservoir, and the other as the receiving reservoir after passing through the interaction chamber.

In particular, the second sample receptacle is arranged as a mirror image of the first sample receptacle with respect to the interaction chamber, i.e., on opposite sides of the interaction chambers. Mirror image does not mean that the distances to a fictitious mirror axis must be exactly the same, but rather that the blood sample receptacles are arranged largely symmetrically and opposite each other on opposite sides of the interaction chambers, or, in the case of a row of interaction chambers, on opposite sides of this row.

Due to the identical design of the sample holders, the samples can be introduced into their assigned interaction chamber reproducibly and with the same flow velocity.

A further aspect of the invention provides that the sample receptacles each have an opening for applying overpressure and negative pressure or overpressure and ambient pressure.

The opening forming the sample inlet can be sealed in a gas-permeable and liquid-tight manner by a membrane element and/or a lid. The membrane element is designed as a hydrophobic, gas-permeable membrane film to allow the sample receptacle to be subjected to positive and negative pressure, or to positive and ambient pressure, via the membrane element.

Advantageously, by applying positive pressure and negative pressure or positive pressure and ambient pressure to the sample receptacle, a sample contained therein can be pumped contactlessly from the sample receptacle into the interaction chamber. This represents a particularly low-contamination transport of sample fluid within the disposable fluid guide assembly. Consequently, a pressure difference must be present between the two ends of the interaction chamber in order to guide the sample through it.

The opening forming the sample inlet can be sealed by a plug of a lid extending into the opening, together with a membrane element that seals a hole in the lid in a gas-permeable and liquid-tight manner. The larger sample inlet facilitates the filling of liquid, while the smaller hole in the lid allows the application of positive or negative pressure without allowing liquid to escape.

The membrane element can be adjacent to one end of the lid, with the lid being formed as a sealing profile on its end facing away from the sample inlet. This design works synergistically with the mirror-image design of the sample receptacles.

By creating a pressure difference between the "mirror-image" sample receptacles, each of which shares a fluidic connection to the interaction chamber via a sample channel, a sample fluid can be pumped back and forth between the two sample receptacles. This easily improves the efficiency of sample application to a sensor element coated with an antibody. The back-and-forth pumping ensures a constant fluid flow within the interaction chamber, ensuring that sample fluid is always brought into contact with the antibody-coated surface of the sensor element, significantly reducing the required sample volume.

The at least one separate container, which forms a sample receptacle, can be fluid-tightly coupled to the upper or lower part by a screw or snap-in connection. However, the container does not have to be designed for a body fluid sample; it can also be designed for other fluids, such as conditioning fluid, rinsing fluid, or as a disposal container for the fluids.

A further aspect of the invention provides that the sample channel and the media channel are combined at an interface to form a common fluid channel, wherein a diaphragm valve is located at the interface, which controls the inflow of the sample liquid or medium into the common fluid channel At the opposite ends of the interaction chamber, media channels open, each of which in turn opens into a media connection on an outer surface of the upper or lower part.

The shared fluid channel significantly reduces the number of channels required within the disposable fluid guide assembly, saving space and simplifying the design of the interaction chamber. The single inlet and sample intake outlet of the interaction chamber can also be optimally positioned.

Furthermore, the provided interface offers the possibility of controlling the flow of the sample from the respective sample channel and of the desired medium via the media channel into the interaction chamber. Accordingly, the interface allows for easy fluid separation of the sample channels and the fluid channels, thus preventing mixing of the sample fluid and the conditioning fluid, as well as preventing the flow of conditioning fluid into the sample receptacle.

In a further aspect of the invention, it is provided that a common fluid channel ends at the opposite ends of the interaction chamber, which then splits into a media channel and a sample channel, wherein a diaphragm valve is provided at each interface in the media channel.

The assignment of an interface with a diaphragm valve to the respective opposite ends of the interaction chamber makes it easy to control the inflow of sample fluid and medium along the fluid channels leading to and from the interaction chamber with the smallest possible number of channels and valves.

A further aspect of the invention provides that the sample channel forms a riser toward the interface, which is surrounded by the valve seat. The media channel splits into two subchannels and runs around opposite sides of the riser. The subchannels reunite downstream of the riser to form the interaction chamber.

This represents a particularly efficient design for fluidically separating the sample channel from the media channel. In the closed state, the A sealing element acts as a diaphragm valve on the valve seat, closing off the riser of the sample channel and thus fluidically separating it from the two sub-channels. Actuating the diaphragm valve at the interface causes the diaphragm to lift upwards from the valve seat toward the upper section, exposing the riser, which is then fluidically connected to the two surrounding sub-channels. The valve is thus opened, establishing a fluidic connection between the sample channel and the interaction chamber. Whether the valve is closed or open, the media channel, which splits into two sub-channels, remains fluidically connected to the interaction chamber.

A further aspect of the invention provides that the riser is formed by a sleeve-shaped extension which has a gusset-shaped nose on opposite sides to the respective branching point of the sub-channels, which delimits the sub-channels in sections.

The gusset-shaped contour divides and joins the media channel with minimal dead space. A contour that is as dead space-free as possible prevents fluid from remaining in a dead space at the interface when the valve is actuated, thus contaminating the diaphragm valve for the next fluid.

In a further embodiment of the invention, the sample channel has a throttle section with a reduced cross-section, in particular an elongated throttle section between the sample receptacle and an interface to the media channel.

Due to the throttle section, increased pressure is necessary to move a sample fluid through the sample channel and the adjacent channels. This simplifies fluid flow, as typically only small volumes of sample fluid need to be moved, which are only subjected to a slight overpressure or underpressure in order to be pumped through the sample channels. However, low pressures are difficult to control. Therefore, the pressure in the sample channels can be "artificially" increased by the throttle section, making the applied pressure easier to control. The throttle section also equalizes flow differences outside the section due to different channel lengths. The throttle section preferably has a Cross-section that is 50-95% smaller than the smallest cross-section outside the throttle section.

In a further embodiment, several interaction chambers, in particular arranged in parallel, are provided on the underside, into which separate membrane valve-controlled fluid channels open at opposite ends.

The provision of multiple interaction chambers offers the advantage that multiple fluids can be introduced into the different interaction chambers in parallel to interact with the associated sensor element surface. This allows for higher sample throughput in a shorter time.

Particularly preferably, the plurality of parallel arranged interaction chambers can be closed on the underside with a single sensor element, so that the interaction chambers each define a section on the sensor element surface that is in fluidic contact with the medium or the sample.

A further aspect of the invention provides that the fluid channels or groups of these fluid channels assigned to one end of the interaction chambers branch off from a common distribution channel which leads to a central media connection.

This simplifies the fluid flow towards the central media connection and there is only a single distribution channel at the media connection through which all media can be introduced into the one-way fluid guide assembly.

A further aspect of the invention provides that a separately valve-controlled outlet for waste medium and/or a separately valve-controlled connection for flushing fluid is present between the media connection and the diaphragm valves in the fluid channels.

For example, the valve-controlled outlet for waste medium allows used and/or contaminated medium to be separately discharged and collected. The valve-controlled connection for flushing fluid, on the other hand, provides a A fluid channel is provided, through which the connected fluid channels can be flushed with a flushing fluid. Separate flushing processes can be performed to clean the fluid channels of the disposable fluid guide assembly to remove any residual fluid and to remove air.

In a further embodiment of the invention, a sample channel opens at the opposite ends of each interaction chamber, in particular wherein the sample channels of similarly directed ends end in series-positioned (i.e. arranged in a row) connections.

When a sample channel merges with a media channel, as optionally explained above, the common fluid channel piece leading into the interaction chamber forms both a section of the sample channel and the media channel, depending on which fluid is currently flowing through.

The arrangement of sample channels on the interaction chamber described above offers the advantage that several samples can be introduced into the respective interaction chambers simultaneously, thus achieving a higher sample throughput.

A further aspect of the invention provides that flushing channels branch off from the fluid channels at one end of the interaction chambers to a flushing fluid container, which can each be opened via their own flushing valves and which preferably merge into a central flushing channel.

This allows flushing, i.e. cleaning and venting of the fluid channels, so that there is no contamination between different media or contamination of sample fluid by media residues and no air is contained.

A variant provides that the disposable fluid guide assembly has at least one liquid tank which is not filled with body fluid and is formed in the upper part and/or in the lower part or is coupled to the upper part and/or lower part as a separate part, ie container, and is fluidically coupled to the at least one interaction chamber. The fluid tank can be filled with cleaning fluid, also called rinsing fluid, or conditioning fluid.

The disposable fluid guide assembly may further comprise at least one disposal container formed in the upper part and/or in the lower part or coupled to the upper part and/or the lower part as a separate part and fluidically coupled to the at least one interaction chamber such that fluid exiting from the interaction chamber can flow into the disposal container.

The optional disposal container may also have at least one vent opening or a connection for applying negative pressure so that it can be filled.

In a further embodiment of the invention, the lower part has a plate-shaped section and a block-shaped section protruding from the plate-shaped section from the underside, in which the at least one interaction chamber is formed, which is open to this underside and/or wherein the upper part is plate-shaped.

The plate-shaped design allows for a particularly compact construction of the one-way fluid guide assembly and a simple design of the channels and chambers. Furthermore, a plate-shaped design offers the largest possible contact surface between the upper and lower sections, whereby the contact surface corresponds to a control surface used by the diaphragm valves to control fluid in the underlying fluid channels. The larger the control surface, the more precisely and variably the diaphragm valves can be positioned.

Furthermore, the block-shaped section offers the advantage that it can be inserted into a peripheral environment of a microfluidic device via a form-fit connection. For example, the block-shaped section can serve as a projection that can engage in a recess of a microfluidic device, allowing the disposable fluid guide assembly to be easily locked via the block-shaped section. The interaction chambers, which are closed by the sensor element(s), can be provided on the underside of the block-shaped section. In this variant, the block-shaped section can be inserted into a holder of a temperature control device, which ensures that the interaction chambers and the sensor element(s) are kept at a desired, constant temperature. The block-shaped section can be a separate part connected to the plate-shaped section of the lower part.

Furthermore, the upper part and the lower part can have at least one of the following properties: the upper part and the lower part are glued, welded, or screwed together; the upper part and the lower part are injection-molded, in particular from cyclo-olefin copolymers (COC); and the upper part and the lower part have assembly aids, in particular in the form of guide pins or recesses.

Preferably, the upper and lower sections are welded together. This represents a particularly proven and reliable connection method, ensuring that no fluid leaks from the sides of the disposable fluid guide assembly during subsequent operation.

Manufacturing the upper and lower parts as injection-molded components is a particularly simple and cost-effective manufacturing process. This is particularly important because the disposable fluid guide assembly is intended for single use.

Cyclo-olefin copolymers (COC) are the preferred material, particularly because they are particularly chemical-resistant and fluid-repellent, making them particularly suitable for conveying medium and body fluids, as samples cannot adhere to the surface.

The assembly aids in the form of guide pins or recesses serve to integrate the disposable fluid guide assembly into the periphery of a microfluidic device with zero play and precise positioning. For this purpose, the guide pins can engage in corresponding recesses in the microfluidic device, or the recesses can engage in corresponding projections of the microfluidic device. This allows the disposable fluid guide assembly to be positioned particularly easily in a microfluidic device. Of course, clamping or locking the upper and lower parts is also possible.

A further aspect of the invention provides that the sealing element is a flat, planar or profiled membrane that forms several membrane valves and separates several pneumatic and fluid channels from each other.

By using a flat, level membrane or a membrane profiled on one or even both sides, the sealing element can be designed as a diaphragm valve in a particularly simple and cost-effective manner.

In particular, the membrane has cutouts to create a fluid connection for a sample between the top and bottom surfaces, thus providing a flow path for a sample from the top of the upper part to the bottom of the lower part and further into the interaction chamber. This offers the advantage that, despite the pneumatic actuation from the top of the upper part, a sample can simultaneously be introduced into the disposable fluid guide assembly via the top of the upper part. Therefore, the sample does not have to be laboriously pumped into the disposable fluid guide assembly from the side or bottom of the lower part.

The invention further relates to a method for producing a disposable fluid guide assembly according to one of the preceding aspects, the method comprising the following steps: a) injection molding a lower part; b) injection molding an upper part; c) arranging the sealing element between the lower part and the upper part; and d) connecting the upper and lower parts to one another while clamping the sealing element.

The resulting disposable fluid guide assembly is particularly simple in design and therefore cost-effective. Advantageously, only the lower part needs to be connected to the upper part, which automatically clamps the sealing element between the two components. Therefore, a separate fastening step for the sealing element is no longer necessary and the process is particularly efficient.

The invention further relates to a microfluidic device for detecting molecular biomarkers in body fluids, e.g., protein defects in a blood sample, comprising a disposable fluid guide assembly according to one of the aforementioned aspects. The microfluidic device comprises a pneumatic unit that can be reversibly coupled to the disposable fluid guide assembly. In the coupled state, the pneumatic unit is fluidly connected to the pneumatic channels and is configured to apply pressure and vacuum to them. Furthermore, the microfluidic device comprises at least one media dosing unit that can be reversibly coupled to the disposable fluid guide assembly. In the coupled state, the media dosing unit is fluidly connected to the interaction chamber via the fluid channels of the lower part.

The present invention is based on the fundamental idea of separating the site of interaction between sample fluid and sensor element surface from as many other components of the microfluidic device as possible, such as the pneumatic unit and the media dosing unit, in order to prevent contamination of these components. Therefore, the site of interaction is limited to the disposable fluid guide assembly, which is disposed of after a single use. This prevents the other components from being contaminated and allows them to be immediately coupled to a "fresh" disposable fluid guide assembly after the interaction and measurement process. This enables a time-efficient and low-cleaning throughput of sample fluids.

Furthermore, the advantages mentioned above for the disposable fluid guide assembly also apply analogously to the microfluidic device. In this respect, reference is made to the above description.

The term “reversibly connectable” means that the disposable fluid guide assembly is designed to be non-destructively connected, i.e. coupled, to the individual components of the microfluidic device and then separated, i.e. decoupled. The term “media dosing unit” refers to an assembly that is designed to supply the disposable fluid guide assembly with at least one medium.

Preferably, the media fluid can be introduced into the fluid channels via the underside of the lower part.

Most preferably, the pneumatic unit can apply pressure or vacuum to the media dosing unit so that the medium can be introduced into the disposable fluid guide assembly without contact.

The pneumatic unit ensures contactless actuation of the diaphragm valves assigned to the pneumatic channels using pressure or vacuum, allowing the diaphragm valves to control the fluid flow in the fluid channels with as little contamination as possible. There is no fixed connection to the diaphragm via mechanical parts, which is a significant advantage.

Furthermore, the invention relates to a biomarker detection device, for example, a protein defect diagnostic device, comprising the microfluidic device for surface treatment of a sensor element for biomarker detection, e.g., protein defect detection, according to the above-mentioned aspect. The biomarker detection device comprises a sensor element that closes the interaction chamber(s) with its surface-treated upper side, and an optical unit that has an IR source, an IR detector, and a beam path through the interaction chamber(s) connecting the IR source and the IR detector. The optical unit is configured to guide the IR radiation generated by the IR source via the sensor element to the detector via the beam path in order to record an IR spectrum from the surface of the sensor element.

The biomarker detection device allows contactless and thus contamination-free biomarker detection on the surface of the sensor element. This is achieved by directing IR radiation generated by the IR source onto the sensor element, which scans the candidate biomarkers bound to the surface of the sensor element and records an IR spectrum of these. The recorded IR spectrum can be used to Conclusions can be drawn about biomarkers, such as defects in proteins bound to the surface. This makes it possible to determine whether the proteins bound to the antibodies on the surface exhibit misfolding, which could indicate early neurodegenerative disease.

Furthermore, the above-mentioned advantages for the disposable fluid guide assembly and the microfluidic device also apply analogously to the biomarker detection device. In this respect, reference is made to the above description.

Further features and advantages of the invention will become apparent from the following description and the accompanying drawings, to which reference is made. In the drawings:

Figure 1 shows a schematic representation of a biomarker detection device according to the invention with a microfluidic device according to the invention and an optical unit;

Figure 2 shows an isometric view of the biomarker detection device according to the invention with the microfluidic device according to the invention from Figure 1;

Figure 3 shows the fluid circuit diagram for the fluid guidance of the microfluidic device of Figure 2;

Figure 4 is an isometric view of an embodiment of the disposable fluid guide assembly of the microfluidic device of Figure 2;

Figure 5 shows a side view of the disposable fluid guide assembly from Figure 4, with the section planes A-A and B-B;

Figure 6 shows a top view of the top of the disposable

Fluid guide assembly from Figure 4, with the section plane C-C;

Figure 7 shows a bottom view of the underside of the disposable

Fluid guide assembly from Figure 4;

Figure 8 is an isometric view of detail B from Figure 7, detail B showing an enlarged view of the interaction chambers; Figure 9A is a sectional view along section plane BB of Figure 5 of the disposable fluid guide assembly, with hatching omitted for clarity;

Figure 9B is a sectional view along section plane A-A of Figure 5 of the disposable fluid guide assembly, with hatching omitted for clarity;

Figure 10 is an isometric sectional view along section plane C-C of Figure 6 of the disposable fluid guide assembly, with details C, D and E;

Figure 11 is an enlarged isometric sectional view taken along section plane C-C of the left side of the disposable fluid guide assembly of Figure 10, with detail F;

Figure 12 is an enlarged isometric sectional view taken along section plane C-C of the right side of the disposable fluid guide assembly of Figure 10;

Figure 13 is an isometric sectional view of detail F of Figure 11, detail F showing an enlarged cross-sectional view of a throttle section;

Figure 14 is an isometric plan view of detail A of Figure 7, detail A showing an enlarged underside view of the throttle section;

Figure 15 is an isometric plan view of detail C of Figure 10, the detail showing a valve at an interface between fluid channel and sample channel, with the section plane D-D;

Figures 16A and 16B are sectional views along the section planes D1-D1 (Figure 16A) and D2-D2 (Figure 16B) of Figure 15, respectively, of the valve of Figure 15;

Figure 16C is an isometric sectional view along the section plane D2-D2 of Figure 15; Figure 16D is an isometric sectional view along the section plane D2-D2 of Figure 15, but with a variant of the sealing element and the lower part;

Figures 17A and 17B show details D and E of Figure 10, respectively, with detail D showing an enlarged view of a fluid channel valve and detail E showing an enlarged view of a fluid channel valve and a flush valve;

Figures 18A and 18B each show an isometric sectional view of two embodiments of the fluid channel valve of Figure 17B;

Figure 19 is an isometric sectional view along the section plane B-B of Figure 5 of a sealing element and the underlying lower part;

Figure 20 shows a schematic flow diagram of the process steps for producing the disposable fluid guide assembly from Figures 4 to 19;

Figures 21 A and 21 B each show an isometric view of a sensor element holder, with and without a sensor element, with the section plane E-E;

Figures 22A and 22B each show a front view of one of the two end faces of the sensor element holder from Figures 21 A and 21 B, with the section plane F-F,

Figure 22C is a sectional view along the section plane E-E of Figure 21A;

Figure 23 is a sectional view along the section plane F-F of Figure 22A of the sensor element holder;

Figure 24 is an isometric view of a combination of the disposable fluid guide assembly of Figure 4 and the sensor element holder with sensor element of Figure 21A, with the section plane G-G;

Figure 25 is a sectional view along the section plane GG of Figure 24 of the combination of disposable fluid guide assembly and sensor element holder of Figure 24; Figure 26 is a sectional view of the sensor element holder of Figure 21A with a centering unit in an uncoupled state;

Figure 27 shows a further sectional view of the sensor element holder of Figure 21A and the centering unit of Figure 26 in a coupled state;

Figure 28 is an isometric view of a base block with centering elements as part of the centering unit from Figures 26 and 27, with the section plane H-H;

Figure 29 is a sectional view along the section plane H-H of Figure 28 showing the centering elements;

Figure 30 is an isometric view of a container as a temperature control unit and centering unit for receiving the disposable fluid guide assembly from Figure 4, with sensor element blocks and fluid inlet blocks, with the section plane l-l;

Figure 31 is a sectional view along the section plane l-l of Figure 30 through the container;

Figure 32 is an isometric view of a fluid inlet block from Figure 30, with the section plane J-J;

Figure 33 is a sectional view along the section plane J-J of Figure 32 of the fluid inlet block, with the section plane K-K;

Figure 34 is a sectional view along the section plane K-K of Figure 32;

Figure 35 is an isometric view of a pneumatic unit with a drive unit;

Figure 36 is an isometric view of the underside of the pneumatic unit of Figure 35;

Figure 37 is a schematic flow diagram of the method steps for a method according to the invention for conditioning a sensor element for biomarker detection and for applying a sample to the sensor element; Figure 38 is a schematic flow diagram of the method steps for a method according to the invention for guiding fluid over a sensor element surface for conditioning and/or sample application;

Figures 39 A and B are enlarged sectional views through the area between the sample containers and the pneumatic unit, and

Figure 40 is a cross-sectional view through another variant of the disposable fluid guide assembly with a separately mounted container.

Figure 1 shows a biomarker detection device 10 for detecting a biomarker in a sample of a body fluid.

In the following, the functioning of the biomarker detection device 10 in the form of a protein defect diagnosis device 10 for analyzing protein defects in a blood sample is described in more detail as an embodiment, which is why the same reference numeral is used below for the biomarker detection device and the protein defect diagnosis device.

It should be understood, however, that the biomarker detection device 10 is not limited to a protein defect diagnostic device for analyzing protein defects in a blood sample, but can also be intended for other types of samples and biomarkers. For example, instead of a blood sample, another sample of a body fluid can be used, such as a sample of cerebrospinal fluid. The optional fluids are described above in the introduction to the description. Therefore, when reference is made to "blood" or "blood sample" below, this should be understood as a placeholder for the more general terms "body fluid" or "body fluid sample," respectively, just as "protein defect diagnosis" should be understood as a placeholder for "biomarker detection."

The protein defect diagnostic device 10 comprises a microfluidic device 12 which is configured to condition a surface of a sensor element for protein defect detection and/or to apply a sample to a conditioned surface. In the embodiment according to Figure 1, the protein defect diagnostic device 10 with the microfluidic device 12 is configured to both condition a surface of a sensor element for protein defect detection and to apply a sample to the conditioned surface. It should be emphasized, however, that it is also possible to condition the surface in a device reduced to conditioning only, as shown in the figures, and to examine the blood sample for protein defects in a separate device, likewise limited to the application and analysis of the blood sample.

In the present case, the microfluidic device 12 comprises a pneumatic unit 14 and a first media dosing unit 16 as well as a second media dosing unit 18, wherein the pneumatic unit 14 can be reversibly coupled to the first and the second media dosing unit 16, 18 and is configured to alternately apply positive or negative pressure or ambient pressure to them.

A reversible coupling of two components is highlighted in Figure 1 with a double arrow.

Furthermore, the microfluidic device 12 comprises a first blood sample receptacle 20 and a second blood sample receptacle 22, which can each be reversibly coupled to the pneumatic unit 14, so that the pneumatic unit 14 can alternately apply overpressure and underpressure to the first blood sample receptacle 20 and the second blood sample receptacle 22.

In addition, the microfluidic device 12 has at least one interaction chamber 24, which is partially closed by a sensor element 26 on one side.

The sensor element 26 is received in a sensor element holder 28 and fastened thereto, so that a surface 30 of the sensor element 26 closes the interaction chamber 24 on one side (here the underside), i.e. in sections.

The interaction chamber 24 is connected to both the first and second

Media dosing unit 16, 18 as well as with the first and second Blood sample receptacles 20, 22 can be reversibly coupled. In the coupled state, the interaction chamber 24 is fluidically connected to the first and second media dosing units and the first and second blood sample receptacles 20, 22 depending on the switching positions of some valves presented below.

Consequently, the interaction chamber 24 provides a defined area in the microfluidic device 12 in which at least one conditioning fluid and/or sample fluid can interact with the surface 30 of the sensor element 26. Details regarding the conditioning fluid and sample fluid, as well as the surface 30 of the sensor element 26, will be explained below.

Depending on the intended application of the protein defect diagnostic device 10, the microfluidic device 12 comprises either all or only some of the aforementioned components. For example, if the microfluidic device 12 is solely intended for conditioning the sensor element 26, the first and second blood sample intakes 20, 22 are omitted. Only the conditioning of the sensor element 26 then takes place in the interaction chamber 24.

However, if the microfluidic device 12 is solely designed for analysis of a blood sample for protein defect detection, the first and second media dosing units 16, 18 are omitted. In the interaction chamber 24, only the sample application to the sensor element 26 takes place.

In the two aforementioned cases, the interaction chamber 24 and the pneumatic unit 14 remain.

However, as shown in the figures, a combination of the above-mentioned embodiments is also conceivable, so that the protein defect diagnostic device 10 with the microfluidic device 12 is set up to first carry out a method for conditioning the sensor element 26 and subsequently a method for applying a sample fluid to the sensor element 26. For this purpose, the first and second media dosing units 16, 18 as well as the first and second blood sample receptacles 20, 22 are provided.

Independently of the above-mentioned embodiments of the microfluidic device 12, some of the aforementioned components may be at least partially integrated into a disposable fluid guide assembly 32, as shown, for example, in Figures 4 to 8, but this is not to be understood as limiting.

In the embodiment of the microfluidic device 12 shown in Figure 2, the first and second media dosing units 16, 18 are arranged outside the disposable fluid guide assembly 32, and the first and second blood sample receptacles 20, 22 are integrated into the disposable fluid guide assembly 32, with the interaction chamber 24 also being integrated into the disposable fluid guide assembly 32. This embodiment is discussed in detail below in the description with reference to Figures 4 to 19.

The protein defect diagnostic device 10 according to Figure 1 further comprises an optical unit 34 for analyzing protein defects in a blood sample.

The optical unit 34 comprises an IR source 36 and an IR detector 38, both arranged in a common optical housing 40. The IR source 36 is configured to generate IR rays, and the IR detector 40 is configured to measure the IR rays generated by the IR source 36. Furthermore, the IR source 36 and the IR detector 38 are radiation-connected via a beam path 42 that leads through the interaction chamber 24.

Basically, the optical unit 34 is configured to direct an IR beam generated by the IR source 36 onto the sensor element 26 via the beam path 42 onto the IR detector 40 in order to record an IR spectrum from the surface 30 of the sensor element 26.

To adjust the IR beam, several mirror elements 44 can be provided along the beam path 42, which reflect the IR beam from the optics housing 40 onto the surface 30 of the sensor element 26 and from there back into the optics housing 40 onto the IR detector 38. Furthermore, the protein defect diagnostic device 10 comprises a control unit 46 (see Figure 2), with a controller 48 and an evaluation unit 50, both of which are housed in a technical housing 52.

The controller 48 and the evaluation unit 50 are connected to each other and to the pneumatic unit 14 in a signal-transmitting manner in order to control the compressed air supply provided by the pneumatic unit 14. For this purpose, the evaluation unit 50 can receive certain signals from the pneumatic unit 14 in the form of parameters and/or measurement data, wherein the evaluation unit 50 transmits a control signal to the controller 48 based on these parameters and/or measurement data. Based on the control signal, the controller 48 can control the pneumatic unit 14.

In particular, the evaluation unit 50 can receive signals from detection units that monitor at least one flow-relevant parameter in the disposable fluid guide assembly 32 and forward it to the evaluation unit 50. The flow-relevant parameter can be a flow direction of a fluid, a flow velocity of a fluid, a fluid volume per unit of time, and the type of fluid, i.e., liquid or gaseous.

The control signal can, for example, be a signal for applying overpressure or underpressure to the first and second media dosing units 16, 18 and the first and second blood sample receptacles 20, 22.

As can be further seen in Figure 2, the protein defect diagnostic device 10 further comprises a drive unit 54 configured to reversibly couple the pneumatic unit 14 to the disposable fluid guide assembly 32. Details of the drive unit 54 are explained further below in the description.

The drive unit is a reversible linear drive that can be moved by motor or, as shown here, manually.

In addition, a centering unit 56 is provided in the protein defect diagnostic device 10, which can be reversibly coupled to the sensor element holder 28 so that the sensor element holder 28 can be aligned with the beam path 42 can, as shown in Figure 2. This is also explained further below in the description in connection with Figures 26 to 29.

Additionally, as can be seen in Figure 2, the protein defect diagnostic device 10 has a temperature control unit 58 that can be brought into contact with the back of the sensor element holder 28 and is configured, in the coupled state, to temperature-control the sensor element 26 via the sensor element holder 28 to a predetermined temperature. Details of the temperature control unit 58 are explained further below in the description in connection with Figure 31.

The fluid circuit diagram of a fluid guide in the microfluidic device 12 is explained in detail below. Reference is made to Figure 3, which is referred to below.

The fluid flow diagram in Figure 3 is divided into different sections, each corresponding to the aforementioned components. The fluid flow within the disposable fluid flow assembly 32 is shown in the center of the diagram. The fluid flow of the first and second blood sample receptacles 20, 22 is integrated into the disposable fluid flow assembly 32. The fluid flow of the first media dosing unit 16 is shown on the left side, and the fluid flow of the second media dosing unit 18 is shown on the right side. The compressed air circuit within the pneumatic unit 14 is shown at the top of the diagram.

The disposable fluid guide assembly 32 is in a coupled state with the first and second media dosing units 16, 18 and with the pneumatic unit 14.

First, the fluid guidance within the disposable fluid guidance assembly 32 is discussed.

Within the one-way fluid guide assembly 32, several fluid channels are provided, which are explained below and can be switched via several valves. Unless otherwise stated, the valves described below are always check valves, in this case diaphragm valves, which can be actuated by means of positive or negative pressure. In particular, the Check valves are designed to completely block or completely release the flow in a fluid channel or a section of a fluid channel.

In particular, the check valves are not designed to regulate the flow rate. Instead, the flow rate is controlled by the pneumatic unit 14 by applying positive or negative pressure to the first and second media dosing units 16, 18 and to the first and second blood sample receptacles 20, 22.

The interaction chamber 24 is arranged centrally in the one-way fluid guide assembly 32, with a first fluid opening 68 provided at a first end 66 of the interaction chamber 24 and a second fluid opening 72 provided at an opposite second end 70. A first fluid channel 74 opens at the first end 66 and is optionally fluidically connected to the interaction chamber 24 via at least one fluid channel valve 76. A second fluid channel 78 opens at the second end 70 and is fluidly connected to the interaction chamber 24 via a second fluid channel valve 80.

As shown in Figure 3, however, there may also be a plurality of interaction chambers 24 from which a plurality of first fluid channels 74 and second fluid channels 78 extend, wherein each interaction chamber 24 is assigned only one first fluid channel 74 and only one second fluid channel 78.

In Figure 3, not all lines, channels, valves, chambers, etc. are provided with reference symbols, but only some of them as examples, if they are units connected in parallel in order to improve clarity.

The fluid guide between the disposable fluid guide assembly 32 and the first media dosing unit 16 will now be discussed.

The circuit diagram of the fluid guide also shows that the first media dosing unit 16 is optionally fluidically connected to the first fluid channel 74 (here all first fluid channels 74) at the first end 66 of the interaction chamber 24 via at least the associated fluid channel valve 76. More precisely, the first media dosing unit 16 has a first media channel 88, in this case a plurality of first media channels 88, which can be reversibly coupled via an associated first media valve 90 selectively to the first fluid channel 74 or the plurality of first fluid channels 74, wherein in the coupled state a fluidic connection is present.

As further shown in Figure 3, however, there may also be a plurality of first media channels 88 which can be reversibly coupled to the first fluid channel 74 or the first fluid channels 74 via first media valves 90, i.e. each media channel has its own media valve 90.

Furthermore, the first media dosing unit 16 has at least one first storage container 94 into which the first media channel 88 opens or from which the first media channel 88 extends.

For example, the first reservoir 94 may be a liquid tank.

A conditioning fluid 96 is stored in the first storage container 94, wherein the conditioning fluid 96 is selected from the group consisting of distilled water, isopropanol, rinsing fluid, PDS, NaPi, MEA, antibody fluid, TBS, various linker fluids, such as linkers based on silanes or thiol ethers, and Tbd.

Preferably, a group of first storage containers 94 is provided, with at least one fluid channel serving as the first media channel 88 extending from each storage container 94. For clarity, only a few media channels 88 are provided with reference numerals. Media channels 88 simultaneously form fluid channels.

Preferably, a different conditioning fluid 96 is arranged in each storage container 94, so that several of the conditioning fluids listed above can be provided.

More precisely, a section is provided between the first media channels 88 and the first storage containers 94, in which the first media channels 88 are designed as first fluid lines 100 in the form of hoses or pipes (see also Figure 2). The first fluid line 100 can extend into its storage container 94 and into the conditioning fluid 96 contained therein.

In addition, at least one first media control valve 104 in the pneumatic unit 14 is assigned to the first media dosing unit 16, which is configured to apply overpressure or underpressure to the first storage containers 94 in order to pump the conditioning fluid 96 contained therein into or out of the first storage container 94.

For example, each first reservoir 94 may be provided with a membrane (not shown here) that is gas-permeable but liquid-tight, so that the first media control valve 104 can couple to the membrane and apply positive or negative pressure to the interior of the first reservoir 94.

As further shown in Figure 3, first media control valves 104 are provided to apply positive or negative pressure to the first reservoirs 94. In the circuit diagram shown in Figure 3, a total of four media control valves 104 are provided, each of which is fluidly connected to at least one first reservoir 94 via a first pneumatic line 108.

In the present case, first pneumatic lines 108 connect the first storage containers 94 with the first media control valves 104.

Each first pneumatic line 108 may, for example, be a hose or tube designed to withstand positive or negative pressure.

The first media dosing unit 16 further comprises a singular first media collection channel 112, in which the group of first media channels 92 are united after the media valves 90, and which can be reversibly coupled to the disposable fluid guide assembly 32 via a central media connection 114.

Furthermore, the central media connection 114 fluidically connects the first media collection channel 112 of the first media dosing unit 16 to a first distribution channel 116 provided in the disposable fluid guide assembly 32. The first fluid channels 74 branch off from the first distribution channel 116. Thus, the first distribution channel 116 is fluidically connected to the associated interaction chamber 24 and thus to all interaction chambers 24 via an associated first fluid channel valve 76.

One option provides that the fluid channels 74 or groups of these fluid channels 74 assigned to one end of the interaction chambers branch off from the common distribution channel 116 or several distribution channels, which lead to a central media connection 114. This also applies below to the second fluid channels, which can also lead in groups to one common distribution channel or several distribution channels.

The fluid guidance of the second media dosing unit 18 is discussed in more detail below.

The circuit diagram shows that the second media dosing unit 18 is optionally fluidically connected to the second fluid channel 78 at the second end 70 of each interaction chamber 24 via at least the respectively associated second fluid channel valve 80.

The second media dosing unit 18 comprises at least one second, here several second, storage containers 118, which are filled with conditioning fluid 96. Each second storage container 118 can be designed in the same way as the first storage container(s) 94 of the first media dosing unit 16.

In the present case, as stated, a plurality of second storage containers 118 are provided, wherein an associated second media channel 122 opens into each of the second storage containers 118 or extends away from them.

Particularly preferably, each reservoir 118 contains a different conditioning fluid 96. However, the reservoirs 118 can also initially be empty in order to receive a conditioning fluid from the first reservoirs 94. In principle, it is not necessary to provide the same number of first and second reservoirs 94 and 118. For example, there can be more first reservoirs 94 than second reservoirs 118, or vice versa. The conditioning fluid is again preferably selected from the group consisting of distilled water, isopropanol, rinsing fluid, PDS, NaPi, MEA, antibody fluid, TBS, various linker fluids, such as linkers based on silanes or thiol ethers, and Tb.

In Figure 3, each second storage container 118 is assigned its own second media channel 122, which extends from the second storage container 118.

Each of the second media channels 122 can be reversibly coupled to the associated second fluid channel 78 via its own second media valve 126, with a fluidic connection being established between them in the coupled state. Alternatively, the media channel 122 can be reversibly coupled to groups of second fluid channels or to all second fluid channels via at least one media valve 126.

The second media valves 126 can be designed, in particular, as electromagnetic valves, so-called Lorentz force valves, to adjust the flow rate from the second media channels 122 to the second fluid channels 78. In Lorentz force valves, permanent magnets generate a constant magnetic field. A coil in the valve housing moves within the magnetic field. This creates a constant force that moves a diaphragm.

As shown in Figure 3, each second media channel 122 can be reversibly coupled to each second fluid channel 78 via its second media valve 126.

More precisely, the second media channels 122 have a section to the second storage containers 118, in which the second media channels 122 are designed as second fluid lines 128 in the form of hoses or pipes.

Furthermore, here too, the second fluid lines 128 can extend into the second storage containers 118 and into the conditioning fluid 96 located therein.

The second media dosing unit 18 is assigned second media control valves 132, each of which is connected via at least one pneumatic line 136 to the second storage containers 118 are reversibly coupled to apply negative or positive pressure to them. By applying negative or positive pressure, a conditioning fluid 96 stored in the second storage containers 118 can be pumped out of or into them.

Furthermore, a second media collection channel 140 is provided in the second media dosing unit 18, in which the second media channels 122 merge. In contrast to the fluid guide in the first media dosing unit 16, the second media collection channel 140 splits again in the direction of the one-way fluid guide assembly 32 into second media channels 122, which correspond to the number of second fluid channels 78 in the one-way fluid guide assembly 32 and are each provided with a media valve.

As shown in Figure 3, the second media collection channel 140 may, for example, be configured to change the number of incoming and outgoing second media channels 120.

In addition, between the second media channels 122, which branch off from the second media collection channel 140 in the direction of the disposable fluid guide assembly, and the second fluid channels 78, a section is provided in which the second media channels 122 are also designed as second fluid lines 128 (e.g., hoses or pipes).

As further shown in Figure 3, in this section the second fluid lines 128 (they thus form sections of the second media channels 122) can each be reversibly coupled to the second fluid channels 78 via a media connection 142.

In the area of the media connections 142, a volume flow measuring unit 144 is provided for each fluid channel 78.

The media channels 88, 122 thus each open at a media connection 114, 142 on an outer surface of the upper part 284 or the lower part 268. In the example shown, the media channels 88, 122 are coupled to the underside of the lower part 268, although this is only an example.

Between the first media dosing unit 16 and the second media dosing unit 18, a bypass channel 148 is also provided, which is connected via a Bypass valve 150 can be switched. More precisely, the bypass channel 148 extends from the first media collection channel 112 to the second media collection channel 140 and fluidically connects the two.

A flow path of one of the conditioning fluids 96 between the first media dosing unit 16 and the second media dosing unit 18 is described below by way of example.

The conditioning fluid 96 is initially arranged in one of the first reservoirs 94. This reservoir can be pressurized via the associated first media control valve 104, so that the conditioning fluid 96 is pumped from the reservoir 94 and via the first fluid line 100 into its own, first media channel 88, where the conditioning fluid 96 encounters the first media valve 90.

After passing through the first media valve 90, the conditioning fluid 96 flows into the first media collection channel 112 and from there via the central media connection 114 into the one-way fluid guide assembly 32.

The conditioning fluid 96 enters the first distribution channel 116 of the disposable fluid guide assembly 32 via the central media connection.

Following the first distribution channel 116, the conditioning fluid 96 is distributed among the first fluid channels 74 with fluid channel valves 76. After passing through the first fluid channels 74, the conditioning fluid 96 flows into the respective interaction chambers 24 and out of them again into the second fluid channels 78.

At the end of every second fluid channel 78, the conditioning fluid 96 passes through the second fluid channel valve 80 and exits the one-way fluid guide assembly 32 via the media connections 142. The conditioning fluid 96 then reaches the volumetric flow measuring unit 144 and the second fluid lines 128. After the second fluid lines 128, the conditioning fluid 96 passes through the second media collection channel 140.

For each conditioning fluid 96, a separate second reservoir 118 is provided so that the appropriate media valve 126 is opened to Allow conditioning fluid 96 to enter its second reservoir 118.

While the conditioning fluid 96 passes through the flow path just described, the second reservoir 118 can be subjected to negative pressure by the second media control valve 132, i.e., while the first reservoir 94 is subjected to positive pressure. The flow path of the conditioning fluid 96 described above is then reversed in the reverse order. To do this, only the second reservoir 118 and the first reservoir 94 must be subjected to positive or negative pressure, respectively.

Each conditioning fluid 96 can thus be reversibly pumped back and forth through all interaction chambers 24 singularly by opening the corresponding valves between its storage containers 94, 118.

The remaining channels and valves are explained in more detail below.

The disposable fluid guide assembly 32 is further equipped with a first flushing channel 152, which extends from outside the disposable fluid guide assembly 32 into the latter and is associated with the first fluid channels 74, wherein each of the first fluid channels 74 is fluidly connected to the first flushing channel 152 via a first flushing valve 154. More specifically, the first flushing channel 152 opens at one end into a flushing container 156 provided outside the disposable fluid guide assembly 32, in which at least one flushing fluid 158 is stored and which can be reversibly coupled to the disposable fluid guide assembly 32, and at its other end into the distribution channel 116.

The rinsing fluid 158 can be selected from the group consisting of water, buffer solution, in particular PBS solution, and combinations thereof.

Furthermore, the disposable fluid guide assembly 32 is equipped with a plurality of second flushing channels 160 on the opposite side of the interaction chambers 24, which merge into a common flushing channel 162 within the disposable fluid guide assembly 32. Each of the second fluid channels 78 is fluidly connected to a second flushing channel 160 via a second flushing valve 164.

The common flushing channel 162 opens into a flushing container 166 arranged outside the disposable fluid guide assembly 32, in which a flushing fluid 158 is also stored or into which flushing fluid can be pumped from the flushing container 156 and pumped back into it.

The flushing container 166 and the common flushing channel 162 are reversibly coupled to the one-way fluid guide assembly 32, with the second flushing valve 164 forming a flushing fluid interface 168 between a second flushing channel 160 and a second fluid channel 78. In particular, the second flushing valve 164 is designed as a two-way valve.

The first rinsing container 156 and the second rinsing container 166 are also reversibly coupled to the pneumatic unit 14 so that they can be alternately subjected to overpressure or underpressure so that the rinsing fluid 158 can be pumped back and forth between the rinsing fluid containers 158 and 166 via the first and second fluid channels 74, 78 and the interaction chambers 24.

Furthermore, a first disposal channel 170 is provided, which is assigned to the first media dosing unit 16. The first disposal channel 170 has a first valve-controlled outlet 172 to a first disposal container 174. In the circuit diagram of the fluid guide, the first disposal channel 170 is fluidically connected to the common first media collection channel 112, so that contaminated and/or used conditioning fluids 96 can be disposed of via the first disposal container 174.

In the second media dosing unit 18, a second disposal channel 176 is provided, which leads via a second valve-controlled outlet 178 to a second disposal container 180. The second disposal channel 176 is fluidically connected to the common second media collection channel 140, so that contaminated and/or used conditioning fluids 96 can also be disposed of into the second disposal container 180 via this channel. The disposable fluid guide assembly 32 is assigned a third disposal channel 182, which can be connected to a disposal container 186 via a third valve-controlled outlet 184. At its other end, the third disposal channel 182 opens into the first distribution channel 116, so that the latter is fluidly connected to the disposal container 186 via the disposal channel 182.

The third disposal container 186 is arranged outside the disposable fluid guide assembly 32 and can be reversibly coupled thereto.

The fluid flow of blood sample receptacles 20 and 22 is discussed in detail below.

Each of the blood sample receptacles 20 is offset with a blood sample from another person so that the blood samples of several people can be analyzed simultaneously.

The first blood sample receptacles 20 are integrated into the disposable fluid guide assembly 32.

The first blood sample receptacles 20 are each fluidically connected to one of the first fluid channels 74 and thus to one of the interaction chambers 24 via a separate first sample channel 188, wherein the respective first sample channel 188 extends from the blood sample receptacle 20.

Each first sample channel 188 is provided with a first shut-off valve 190 so that the flow connection between blood sample receptacle 20 and its interaction chamber 24 can be switched.

In addition, second blood sample receptacles 22 are provided, which are also integrated into the disposable fluid guide assembly 32.

In particular, the second blood sample receptacles 22 are each fluidically connected to one of the second fluid channels 78 and thus to one of the interaction chambers 24 via a separate second sample channel 194, wherein the respective second sample channel 194 extends from the blood sample receptacle 22 or opens into it. Every second sample channel 194 is provided with an associated second shut-off valve 196 so that the flow connection between blood sample receptacle 22 and interaction chamber 24 can be switched.

Specifically, the first blood sample receptacle 20 comprises several first blood sample receptacles 200.

Accordingly, the second blood sample receptacles 22 are also (second) blood sample receptacles 204, which are constructed identically to the first blood sample receptacles 200.

The first blood sample receptacles 200 can be reversibly coupled to a first blood sample control valve 208 of the pneumatic unit 14, and the second blood sample receptacles 204 can be reversibly coupled to a second blood sample control valve 210, wherein the first and second blood sample control valves 208, 210 are each configured to alternately apply overpressure and underpressure to the first and second blood sample receptacles 200, 204, so that a blood sample 212 can be pumped back and forth between the first and second blood sample receptacles 200, 204 through the associated interaction chamber 24.

The blood sample 212 is preferably blood serum, blood or blood plasma.

In order to fluidically separate the conditioning fluid 96 from the blood sample 212 and to prevent mixing of the fluids and thus contamination of the blood sample 212, a first, switchable interface 214 is provided between the first blood sample receptacle 20 and the interaction chamber 24, which first, switchable interface 214 is configured to fluidically separate the fluid flow from the conditioning fluid 96 and the blood sample 212.

More precisely, at the first interface 214, each first sample channel 188 from the first blood sample container 200 meets the first fluid channel 74, which opens into the first media dosing unit 16. Therefore, a valve is provided at each first interface 214, which fluidically separates the first sample channel 188 from the first fluid channel 74. Both channels 74, 188 merge in the direction of the interaction chamber 24 to form a common section 216 of the first fluid channel 74, which leads to the Interaction chamber 74. The specific design of the first interface 214 is explained further below in the description.

Furthermore, a second interface 222 is provided between each second blood sample receptacle 22 and the associated interaction chamber 24, which second interface is configured to fluidically separate the fluid flow from the conditioning fluid 96 and the blood sample 212.

Therefore, a valve is provided at each second interface 222, which fluidically separates the second sample channel 194 from the second fluid channel 78. Both channels 78, 194 merge toward the interaction chamber 24 to form a common section 224 of the second fluid channel 78. The specific design of the second interface 222 is described in more detail below.

In order to apply negative or positive pressure to the first and second dosing units 16, 18, the first and second blood sample receptacles 20, 22 and the first and second rinsing containers 156, 166, these are reversibly coupled to the pneumatic unit 14.

The pneumatic unit 14 is explained in detail below.

For the compressed air supply, a vacuum line 230, an overpressure line 232 and a drive line 234 are provided in the pneumatic unit 14.

The vacuum line 230 is fluidly connected to a first pneumatic pump 236 and the overpressure line 232 and the drive line 234 are jointly connected to a second pneumatic pump 238.

The first and second pneumatic pumps 236, 238 are configured to provide a vacuum or compressed air supply in the respective strands.

The overpressure line 232 has a higher pressure than the drive line 234. For example, the overpressure line 232 can be pressurized to a pressure of approximately 1.5 bar relative to atmospheric pressure and the drive line 234 can be pressurized to a pressure of approximately 0.3 bar relative to atmospheric pressure. To adjust the pressure, pressure regulators can be connected downstream of the second pneumatic pump 238 in the overpressure line 232 and the drive line 234.

Furthermore, each of the three strands 230, 232 and 234 is provided with at least one pressure gauge 240 so that the pressure in the respective strand can be monitored and adjusted if necessary.

Vacuum lines 242 are provided on the vacuum line 230, which open into associated pilot valves 244, into each of which an overpressure line 246 from the overpressure line 232 also opens.

Depending on the switching state, the pilot valves 244 fluidly connect the vacuum line 230 or the overpressure line 232 with at least one associated, switchable valve inside or outside the one-way fluid guide assembly 12, e.g., the aforementioned shut-off valves in the one-way fluid guide assembly 32.

Overall, the first and second fluid channel valves 76, 80, the first and second shut-off valves 190, 196, the first flushing valve 154 and the second flushing valves 164 are each connected downstream of a pilot valve 244 and can be actuated via their pilot valve 244 with vacuum via the vacuum line 230 or with overpressure via the overpressure line 232, i.e. can be opened or closed.

To improve clarity, Figure 3 symbolically shows a pilot valve 244 and a shut-off valve to be switched by it in the top right corner, as a placeholder for all pilot valves and their shut-off valves.

Further vacuum lines 242 branch off from the vacuum line 230, which, together with several drive line lines 248 branching off from the drive line 234, lead into several pilot control valves 250. Thus, each pilot control valve 250 is assigned a drive line 248 and a vacuum line 242. A pneumatic line 251 extends from each pilot drive valve 250 to the respective drive valves 104, 208, 210 and 128 to apply pressure or vacuum to them.

Furthermore, several silencer elements 252 are provided in the pneumatic unit 14.

The following explains how the interaction chamber 32 and the parts that define it are kept constant at a predetermined temperature.

As already explained above, at least one interaction chamber 24 is provided in the disposable fluid guide assembly 32, to which a temperature control unit 58 is assigned.

The temperature control unit 58 comprises a temperature control element 254, which is in physical contact with the interaction chamber 24, in particular with the sensor element 26 adjacent to the interaction chamber 24, in a heat-transfer manner. Consequently, a heat-conducting connection 256 also exists between the temperature control element 254 and the temperature control unit 58, as schematically illustrated in Figure 3.

The temperature control unit 58 is further connected to a temperature control device 258 via a temperature control circuit 260 for heat transfer, wherein the temperature control device 258 is configured to control the temperature control unit 58 to a predetermined temperature via the temperature control circuit 260. In this respect, temperature control is achieved by means of a temperature control fluid flowing through the temperature control circuit 260. For example, a liquid such as water or a mixture of water with an antifreeze such as glycerin, ethylene glycol, ethanol, and/or propylene glycol can be used as the temperature control fluid.

The predetermined temperature can then be passed on from the temperature control unit 58 via the heat-transfer connection 256 to the temperature control element 254 and thus to the interaction chamber 24. To monitor whether the predetermined temperature is present in the interaction chamber 24, the temperature control circuit 260 and the interaction chamber 24 are provided with a plurality of cooling fluid temperature sensors 262. In particular, a sensor crystal temperature sensor 264 is provided, which monitors the temperature of the sensor element 26.

Furthermore, the temperature control unit 58 is connected to a compressed air supply via a compressed air connection 266 so that the temperature control circuit 260 can be easily dried and cleaned.

Figure 4 shows a concrete embodiment of the disposable fluid guide assembly 32 from the previous figures.

The disposable fluid guide assembly 32 has a base 268 which includes a plate-shaped portion 270.

The plate-shaped section 270 has a fluid side 272 and a bottom side 274 facing away from it. Furthermore, the plate-shaped section 270 has two end sides 276 and two longitudinal sides 278 connecting the two end sides 276.

In the embodiment according to Figure 4, the plate-shaped section 270 has a substantially rectangular basic shape.

A projection 280 extends laterally outwards from each of the long sides 278. The projection 280 has a rectangular basic shape and comprises (see Figure 7) a centering bore 282 at each of its two corners and a centering element 283 in the form of a pin provided between the centering bores 282.

Furthermore, the disposable fluid guide assembly 32 (see Figures 4 and 5) has an upper part 284 which has a plate-shaped section 286 which is provided with an upper side 288 and a pneumatic side 290 facing away from it (see Figure 5).

In the embodiment according to Figure 4, the plate-shaped portion 286 has a substantially rectangular basic shape which corresponds to the shape of the plate-shaped portion 270 of the lower part 268. Between the top side 288 and the pneumatic side 290 there are two end faces 292 at the opposite ends, each of which is connected by two long sides 294.

Analogous to the lower part 268, the upper part 284 also has two rectangular projections 296 extending laterally outwards, at each of whose two corners a centering hole 298 is provided. Between the two centering holes 298, a centering element 283 (see figure ?) in the form of a recess is provided centrally on the projection 296.

As shown in Figure 5, the lower part 268 points with its fluid side 272 toward the pneumatic side 290 of the upper part 284a, so that the upper side 288 of the upper part 284 and the lower side 274 of the lower part 268 are freely accessible to the outside. In particular, the two plate-shaped sections 270, 286 lie congruently one above the other.

Most preferably, the upper part 284 and the lower part 268 are fastened to one another, for example by gluing them together in sections, welding them together or by fastening means, as shown in Figures 4 and 5.

In the following figures, the lower part 268 and the upper part 284 are fastened to each other via screw connections 300.

The outer contour of the upper and lower parts 168, 284 is explained in detail below.

The upper side 288 of the upper part 284 has two rectangular, elongated recesses 302, each arranged perpendicular to the extension direction of the first and second fluid channels 74, 78, in particular the first and second common sections 216, 224 of the first and second fluid channels 74, 78. In the present case, one recess 302 is assigned to the first fluid channels 74, and the other recess 302 is assigned to the second fluid channels 78.

A plurality of sensor windows 306 are embedded in the elongated recess 302, which extend close to the underlying first or second fluid channels 74, 78, in particular the common sections 216, 224 of the first or second fluid channels 74, 78. Furthermore, the lower part 268 also has sensor windows 308 in the form of underside sensor windows 308 (see Figure 7), which extend from the underside 274 of the lower part 268 towards the top side 288 of the upper part 284.

The upper and lower sensor windows 306, 308 are arranged opposite one another, so that the first and second fluid channels 74, 78, in particular the common sections 216, 224 of the first and second fluid channels 74, 78, of the disposable fluid guide assembly 32 run between the upper and lower sensor windows 306, 308.

In addition, the top and bottom sensor windows 306, 308 are each configured to accommodate detection units. This will be explained in more detail below in the description.

As can be clearly seen in Figure 6, the upper side 288 has a plurality of pneumatic channel openings 310, only some of which are provided with reference numerals, to which pneumatic channels 311 (see Figure 11) are connected, which run vertically and without interruption to the pneumatic side 290 of the upper part 284.

The pneumatic channel openings 310 are designed to be reversibly coupled to the pneumatic unit 14 in order to be subjected to overpressure or underpressure by the latter.

Figure 7 also shows that a plurality of media channel openings 312 are arranged on the underside 274, which can be reversibly coupled to the first or second media dosing unit 16, 18, so that a conditioning fluid 96 flowing in from the first or second media dosing unit 16, 18 can flow into the lower part 268 via the media channel openings 312.

In addition to the media channel openings 312, a plurality of outlet openings 313 are provided on the underside 274, which can be reversibly coupled to the first or second rinsing container 156, 166 or to the third disposal container 186. A block-shaped section 314 is provided centrally on the underside 274, which protrudes downward relative to the underside 274 of the plate-shaped section 270. The block-shaped section 314 is shown in detail in Figure 8.

A base surface 316 is provided on the side of the block-shaped section 314 facing away from the underside 274.

In the base surface 316, there are several elongated recesses in the form of interaction paths 318, which extend across the base surface 316 and run parallel to one another, forming the interaction chambers 24 in sections. Overall, according to the present embodiment, two pairs of interaction paths 318 are provided, which are spaced apart from one another by longitudinal webs 319 (see Figure 8).

The first and second fluid openings 68, 72 are provided at the respective opposite ends of the interaction paths 318.

Each interaction path 318, together with the fluid openings 68, 72, is enclosed by a frame-like sealing element 320 that protrudes beyond the base surface 316 and, together with the interaction path 318 and the surface 30 of a sensor element 26, defines the interaction chamber 24 (the sensor element 26 has been omitted for clarity). The sensor element presses its surface 30 against the sealing elements 320 and closes the open side of the respective interaction chamber 24.

The sealing element 320 can in particular be designed as a sealing ring and is made of an elastic material.

Specifically, each of the two pairs of interaction tracks 318 is assigned an elongated double sealing ring which has the shape of the figure eight, so that two interaction tracks 318 share one long side of the double sealing ring.

Furthermore, a plurality of sleeve-shaped alignment projections 322 are provided on the base surface 316. The alignment projections 322 can be used to align the block-shaped portion 314 with a sensor element holder 28. The block-shaped section 314 and the lower part 268 are designed as a single piece, which is not necessarily the case.

The inner part of the disposable fluid guide assembly 32 is explained in more detail below. This is particularly clearly visible in Figures 9A and 9B, which show the unfolded disposable fluid guide assembly 32 along the sectional planes B-B and A-A, respectively. Figure 9A shows the fluid side 272 of the lower part 268, and Figure 9B shows the pneumatic side 290 of the upper part 284. For the sake of clarity, a sealing element 330 (see Figure 4) has been omitted from Figures 9A and 9B. This is shown schematically in Figure 19, which will be briefly discussed below.

In principle, the upper part 284 on the pneumatic side 290 and the lower part 268 on the fluid side 272 each have a plurality of fluid channels formed by grooves 326. Recesses 328 on the pneumatic side 290 can be associated with the grooves 326 on the fluid side 272, which, together with a sealing element 330 arranged between the fluid side 272 and the pneumatic side 290, can act as valves.

The sealing element 330 is designed as a flat, profiled membrane that extends substantially completely over the fluid side 272.

In more detail (see Figure 18), the sealing element 330 comprises a first membrane layer 332 and an overlying second membrane layer 334, wherein the first membrane layer 332 is arranged between the second membrane layer 334 and the fluid side 272.

Preferably, the first membrane layer 332 is thinner than the second membrane layer 334.

As further shown in Figure 19, the sealing element 330 has blood sample container recesses 336 so that a breakthrough through the first membrane layer 332 and the second membrane layer 334 is provided.

In the area of the recesses 328, the sealing element 330 is part of a diaphragm valve 338, so that the fluid channels adjacent to the recesses 328 and formed as grooves 326 can be switched. The fluid-conducting grooves 326 are arranged substantially on the fluid side 272 of the base 268, as shown in Figure 9A. In more detail, the fluid side 272 includes various grooves 326, each with a different geometry.

In the top view of Figure 9A, the left and right sides of the fluid side 272 have different grooves. A central axis is symbolized by a dashed line. The left and right sides essentially correspond to the fluid guide in the circuit diagram in Figure 3. In this sense, the left side is assigned to the first fluid channels 74 and the right side to the second fluid channels 78, as discussed below.

On the left side, a wave-shaped groove 340 is provided, which extends along or parallel to the end face 276 of the lower part 268. The beginning of the wave-shaped groove 340 is a dead end 339, and the other end represents an inlet opening 341 corresponding to the outlet opening 313.

The outlet opening 313 (see Figure 7) on the underside 274 is fluidically connected via a bore to an inlet opening 341 (see Figure 9A bottom left) on the fluid side 272.

The wave-shaped groove 340 has no direct connection to other grooves, but acts as a distribution channel.

The media inlet opening 345 on the fluid side 272 is fluidically connected to a media channel opening 312 (see Figure 7) on the underside 274 and is spaced from the groove 340.

The groove 340 is spatially separated from partially linear grooves 346.

Each groove 346 extends to the center of the fluid side 272 and opens into a fluid interaction chamber opening 348, which fluidically connects the linear groove 346 to the interaction chamber 24.

The grooves 346 run parallel to each other in sections.

On the right side of the fluid side 272, linear grooves 346 can be seen, each extending from an associated media inlet opening 345 towards the center of the fluid side 272 and in a Fluid interaction chamber opening 348, which fluidically connects the respective linear groove 346 with the associated interaction chamber 24. Thus, the right side has four inlets for the conditioning fluid 96.

A groove 346 on the left side is fluidically connected to a groove 346 on the right side via the respective interaction chamber 24.

Furthermore, each groove 346 is assigned an inlet opening 341 on the right side, which is located between the fluid interaction chamber opening 348 and the media inlet opening 345.

In the fluid circuit diagram of Figure 3, the wave-shaped groove 340 corresponds to the first distribution channel 116 and the linear grooves 346 on the left side correspond to the first fluid channels 74 and the first common section 216, and the linear grooves 346 on the right side correspond to the second fluid channels 78 and the common section 224. The inlet openings 341 on the left side are assigned to the first flushing container 156 and the third disposal container 186, and the media inlet opening 345 is assigned to the central media connection 114. The inlet openings 341 on the right side are assigned to the second flushing container 166.

In addition, the pneumatic side 290 has a plurality of recesses 328, which together with the sealing element 330 form diaphragm valves 338. Here, too, for the sake of simplicity, reference numerals are not provided for all valves, grooves, channels, openings, etc.

On each diaphragm valve 338 there is a pneumatic channel 311 (see Figure 10), which opens into the recesses 328 and extends through the upper part 284 to the pneumatic side 290.

The fluid flow of the conditioning fluid 96 and the blood sample 212 in the disposable fluid flow assembly 32 is explained in more detail below. Reference is made to Figure 10, which shows an isometric cross-sectional view along the section plane C-C and provides an insight into the disposable fluid flow assembly 32.

Basically, the flow paths for the conditioning fluid 96 within the one-way fluid guide assembly 32 run on the left and right Fluid side 272 is different. However, it is also conceivable that both sides have the same fluid flow for the conditioning fluid 96.

In contrast to the fluid flow of the conditioning fluid 96, the fluid flow for the blood sample 212 is identical for the left and right sides. Therefore, the design of the fluid flow for the blood sample 212 will be discussed first.

As shown in Figure 11, the blood sample receptacle 20 includes a blood sample receptacle 200 provided on the upper side 288 of the upper part 284. This receptacle encloses a cavity 351 for receiving the blood sample 212.

As can be seen in Figure 10, the blood sample container 200 has a cavity 352 in the upper part 284, which is adjoined by a cavity 354 in the lower part 268, and which form the common cavity 351.

Viewed from the upper side 288 of the upper part 284, the blood sample containers 200 merge into one another and form a kind of tower-like structure with an upper end face 365.

In addition, each blood sample container 200 is provided on the common end face 365 with a sample inlet 366 through which a blood sample 212 can be introduced into the cavity 351.

Each sample inlet 366 is sealed in a liquid-tight manner by a membrane element 368, in particular a hydrophobic membrane. In particular, the membrane element 368 is designed to be gas-permeable, so that the cavity 351 in the blood sample receptacle 20 can be subjected to negative or positive pressure by the pneumatic unit 14. Alternatively, instead of the membrane element 368, a lid is provided at the sample inlet 366. This lid can be opened to fill the blood sample and then closed again.

As can be clearly seen in Figure 13, the cavity 354 in the lower part 268 has a bottom section 370 which is shaped as a trough which tapers conically towards the bottom and opens into a central opening 372. The blood sample 212 can be fed into an outlet line via the central opening 372

374, which extends vertically downwards from the central opening 372 towards the bottom 274.

The outlet line 374 is followed by a throttle channel 375 which extends through a throttle section 376.

A constriction 378 is provided in the throttle channel 375. For example, this can be achieved by changing the cross section of the throttle channel

375 is tapered in the area of the throttle section 376 due to the constriction 378.

As can be clearly seen in Figures 13 and 14, the constriction 378 is realized by a plate element 380, which is screwed from the underside 274 to the lower part 268 via several screw connections 382. As a result, the cross-section of the throttle channel 375 in the region of the constriction 378 is tapered to a slot-like cross-section due to the plate element 380, effectively reducing the cross-section of the throttle channel 375. The throttle channel 375 is bounded at the bottom by the plate element 380 and from above by the underside 274 of the lower part 268.

Furthermore, the throttle channel 375 is fluidically connected to a sample riser 384. In contrast to the constriction 378, the sample riser 384 again has a cross-section typical for the disposable fluid guide assembly 32. The sample riser 384 extends from the bottom 274 to the fluid side 272 and opens into a valve seat 386. This can be seen particularly clearly in Figures 15 and 16.

The sample riser line 384, the throttle channel 375 and the outlet line 374 correspond to the first sample channel 188 according to the circuit diagram of the fluid guide in Figure 3.

The valve seat 386 forms, with a sealing element 330 resting on the valve seat 386, a diaphragm valve 338 which corresponds to the first interface 214 in the fluid circuit diagram of Figure 3.

As can be clearly seen in Figure 15, a first fluid channel 74 coming from the left runs into the first interface 214 and meets a branching point 388. From the branching point 388, the first fluid channel 74 is divided into two sub-channels 390, each of which runs around a sleeve-shaped extension 392 of the sample riser 384 and reunites in a branching point 388 located behind it to form a common section 216, which runs to the right in Figure 15 and is fluidically connected to the interaction chamber 24.

In order to ensure a particularly dead-space-free contour of the first interface 214, the valve seat 386 is provided with two gusset-shaped noses 394, each of which is aligned in the direction of the two branching points 388, at which the two sub-channels 390 reunite.

As can be clearly seen in Figure 16A, the valve seat 386 has a concave shape between the gusset-shaped nose 394 and the opening of the sample riser 384. In this respect, the gusset-shaped nose 394 is a raised portion.

The section of the valve seat 386 that annularly surrounds the opening of the sample riser 384 is higher than each of the two gusset-shaped lugs 394. However, it is also conceivable for the gusset-shaped lug 394 to be lower, as long as a depression is present between the gusset-shaped lug 394 and the opening of the sample riser 384. Such a depression is particularly advantageous for preventing the membrane from sagging in the region of the branching point 388. In particular, the gusset-shaped lug 394 forms a support for the membrane, so that a further support in the form of a column or projection in the region of the branching point 388 can advantageously be omitted. In this way, the membrane can rest sealingly on the valve seat 386 in the unactuated state, and unhindered volume flow along the sub-channels 216 is also possible in this state.

Furthermore, as shown in Figures 16B and 16C, an anchoring point 396 in the form of a recess 398 is provided on the pneumatic side 290 of the upper part 284 in the region of the recess 328, into which the sealing element 330 can engage via a membrane projection 400. Figure 16D shows a variant in which the sealing element 330 on the fluid side has a circumferential membrane projection 440 which projects into a recess 398 in the lower part 268.

Preferably, the anchoring point 396 is annular and circumferentially completely encloses the recess 328 of the first interface 214.

Figures 16A to 16C show the diaphragm valve 338 in a non-actuated state in which the sealing element 330 rests on the valve seat 386 and thus closes the sample riser 384 in a fluid-tight manner.

Opposite the sample riser 384, a pneumatic channel 311 is provided, which fluidically connects the recess 328 to the upper side 288 of the upper part 284. In the actuated state, a vacuum is applied via the pneumatic channel 311, so that the sealing element 330 is pulled upward toward the upper side 288 into the recess 328, thereby opening the sample riser 384, which is then fluidly connected to the sub-channels 390.

The common section 216 is followed by the fluid interaction chamber opening 348, which opens into an interaction chamber line 402 (see Figures 10 and 12).

The interaction chamber line 402 extends as a straight channel through the lower part 268 and through the block-shaped section 314 and opens into the interaction chamber 24 via the fluid opening 68 or 72. The fluid opening 68, 72 widens the interaction chamber line 402 in the direction of the interaction chamber 24 and forms a conical section 406 (see Figure 10) which is opposite the interaction paths 318.

The above description of the first blood sample intake 20 applies analogously to the second blood sample intake 22, in this respect reference is made to the above description.

The flow path 410 of the blood sample is explained in more detail below. The flow path 410 is shown by the dashed line in Figures 11 and 12.

First, the membrane element 368 or the cover is removed from the

Sample inlet 366 is removed and the blood sample 212 is placed in the blood sample receptacle 20 For example, the blood sample 212 can be pipetted manually into the sample inlet 366.

Subsequently, the sample inlet 366 is closed again by the membrane element 368. This can then be reversibly coupled to the pneumatic unit 14 so that the blood sample 212 located in the blood sample receptacle 20 can be subjected to positive or negative pressure. To move the blood sample 212, positive pressure is applied to the first blood sample receptacle 20 and negative pressure is applied to the second blood sample receptacle 22. However, only positive pressure can be applied to the first blood sample receptacle 20.

Due to the applied overpressure in the blood sample receptacle 20 (see Figure 11), the blood sample 212 is pressed into the central opening 372. From there, the blood sample 212 flows via the outlet line 374 and along the throttle section 376 via the throttle channel 375 into the sample riser line 384. The throttle section 376 ensures that the applied pressure increases, so that an overall higher pressure can be applied to the blood sample receptacle 20 to move the blood sample 212. An increased pressure is advantageous because, due to the small volume of blood sample 212, very low pressures would be necessary for transport, which, however, are difficult to control.

From the sample riser 384, the blood sample 212 enters the section of the interface 214. This section is closed by the diaphragm valve 338. By applying a vacuum on the pneumatic side 290 in the pneumatic channel 311 corresponding to and opposite the sample riser 384, the first membrane layer 332 is lifted from the valve seat 386 and pressed against the ceiling of the recess 328, so that the sample riser 384 is fluidically connected to the subchannels 390.

The blood sample 212 can then flow via the sleeve-shaped extension and the gusset-shaped nose 394 through the branching point 388 into the first common section 216 of the fluid channel 74 and further via the common section referred to as the interaction chamber line 402 into the interaction chamber 24. From the interaction chamber 24, the blood sample 212 takes the same path into the blood sample receptacle 22 as described above for the first blood sample receptacle 20. In this respect, reference is made to the explanations above.

As already shown above with reference to Figure 10, the fluid flow of the conditioning fluid 96 differs for the left and right sides of the disposable fluid flow assembly 32. Therefore, the fluid flow for the conditioning fluid 96 will first be explained for the left side. Reference is made to Figure 11 for this purpose.

A media riser 414 extends from the media channel opening 312 on the underside 274 and opens into the media inlet opening 345 (see Figure 17A), which is opposite a recess 328 on the pneumatic side 290.

A pneumatic channel 311 is arranged opposite the media riser 414, which is fluidically separated from the media riser 414 by the sealing element 330, in particular the first membrane layer 332, wherein the sealing element 330 has been omitted in Figure 11 for the sake of clarity.

Here, too, the sealing element 330 forms a diaphragm valve 338, which is the first fluid channel valve 76 in the circuit diagram of the fluid guide according to Figure 3.

An enlarged view of the corresponding second fluid channel valve 80 on the right side of the one-way fluid guide assembly 32 is shown in Figures 18A and 18B, which has the same structure as the first fluid channel valve 76.

The structure and operation of the fluid channel valve 76 are explained below with reference to the second fluid channel valve 80, with reference to Figure 18A, which shows an enlarged view of the second fluid channel valve 80 from Figure 17B.

In the non-actuated state of the second fluid channel valve 80, the media riser 414 is spatially separated from the second fluid channel 78 in the plane of the fluid side 272 by a partition wall. In particular, the first membrane layer 332 lies flat on this partition wall and thereby covers the media inlet opening 345 of the media riser 414 and the second fluid channel 78.

To create a fluidic connection between the media riser 414 and the second media channel 78, the recess 328 is a trough- or box-shaped recess 416 which, when viewed from the top side 288, conceals the media riser 414 and an initial section of the second fluid channel 78. Actuation of the second fluid channel valve 80 causes the first membrane layer 332 to be raised toward the recess 416, thereby creating a fluidic connection between the initial section of the second fluid channel 78 and the media inlet opening 345.

As further shown in Figure 18A, the second membrane layer 334 is provided next to the first membrane layer 332, which is arranged above the first membrane layer 332 and faces the upper side 284. Furthermore, the second membrane layer 334 is cut out in the region of the box-shaped recess 416, so that only the first membrane layer 332 rests on the opening of the second fluid channel 78 and the opening of the media riser 414 in the unactuated state.

The above explanation applies equally to the first fluid channel valve 76, as shown in Figures 17A and 18B. In contrast to Figures 18A and 17B, the media riser 414 in Figure 17A is fluidly connected to the first distribution channel 116, 340 via the recess 416 when the first fluid channel valve 76 is in an open state. In contrast to Figure 18A, only a first membrane layer 334 is provided in Figure 18B. This can be held on the pneumatic side 290 of the upper part 284 via an anchoring point 396 in the form of a recess 398, wherein the sealing element 334 can engage in the recess 398 via a membrane projection 400. However, two membrane layers 332 and 334 could also be provided, as shown in Figure 18A.

The flow path 412 of the conditioning fluid 96 is explained in detail below. The conditioning fluid 96 can enter or exit the one-way fluid guide assembly 32 from both the left and right via the media channel openings 312. It is assumed below that the Conditioning fluid 96 enters the disposable fluid guide assembly 32 via the right side.

The conditioning fluid 96 reaches the second fluid channel valve 80 via the media channel opening 312 and the media riser 414. When the second fluid channel valve 80 is open, the conditioning fluid 96 flows from the media riser 414 into the second fluid channel 78.

From there, the conditioning fluid 96 flows via the two sub-channels 390 of the flushing fluid interface 168 to the second interface 222 (see Figure 12).

At the second interface 222, the conditioning fluid 96 divides again into the two sub-channels 390 and reunites towards the second common section 224. It enters the interaction chamber line 402 via the fluid interaction chamber opening 348 and flows further into the interaction chamber 24.

From there (see Figure 11), the conditioning fluid 96 enters the next interaction chamber line 402 upwards towards the top side 288 and thus reaches the first common section 216.

The conditioning fluid 96 flows along the first common section 216 to the first interface 214.

There, the conditioning fluid 96 is divided according to the two sub-channels 390 and reunites in the first fluid channel 74 and meets the first fluid channel valve 76 further downstream.

When the first fluid channel valve 76 is open, the conditioning fluid 96 flows into the first distribution channel 116. From there, it encounters another first fluid channel valve 76 and flows via this into the media riser 414 and leaves the one-way fluid guide assembly 32 via the media channel opening 312. Of course, the flow path 412 of the conditioning fluid 96 can also be in the opposite direction.

Furthermore, Figure 17B shows the flushing fluid interface 168 to the left of the second fluid channel valve 80. The flushing fluid interface 168 has the same structure as the first interface 214 explained above, with the difference that instead of the sample riser 384, a Flushing fluid riser 418 is provided, which corresponds to the second flushing channel 160.

Figure 20 shows a schematic flow diagram of the steps of a method for manufacturing the disposable fluid guide assembly 32.

In a first step S1, the lower part 268 is injection-molded. Preferably, the lower part 268 is made of COC because the material is fluid-repellent, preventing samples from adhering to the surface.

Optionally, the plate element 380 for the throttle section 376 can be injection-molded and then attached to the underside 274 of the lower part 268, thereby sealing the throttle channel 375 in a fluid-tight manner. Preferably, the plate element is also made of COC. Particularly preferably, the plate element 380 can be welded to the underside 274, in particular laser-welded.

Subsequently, the upper part 284 is injection-molded in a second step S2. The upper part 284 is preferably made of COC.

The sealing element 330 is then arranged between the lower part 268 and the upper part 284 (S3).

Finally, the upper and lower parts 268, 284 are fluidically connected to each other by clamping the sealing element 330 (S4).

Particularly preferably, the upper and lower parts 268, 284 are welded together, in particular laser welded.

The mounting of the sensor element is explained below with reference to Figures 21-23. In Figure 21A, two sensor elements 30 are attached to the common sensor element holder 28. The sensor element holder 28 has a plate-shaped body 420 (see Figure 21A) with a substantially rectangular basic shape.

The plate-shaped body 420 comprises a front side 422, a rear side 424 facing away from it, and two longitudinal sides 426 between the front side 422 and the rear side 424, which each connect two end sides 428. A pre-tensioning mechanism 432 is mounted in the wall on each of the long sides 426.

In the center between the two preloading mechanisms 426, stop elements 434 are provided, spaced apart perpendicular to the direction of movement Rv of the preloading mechanism 432, against which the sensor elements 30 are clamped. The direction of movement Rv is shown in Figure 22C.

In particular, the stop elements 434 are designed as projections in the form of longitudinal webs, each having an extension direction that is perpendicular to the direction of movement R _v of the pretensioning mechanism 432.

As can be seen in Figure 21A, the pretensioning mechanism 432 is located centrally between the stop elements 434, as seen in its direction of movement.

In particular, at least the two stop elements 434 can each merge integrally into the sensor element holder 28.

Furthermore, the plate-shaped body 420 has recesses 436 formed by recesses on its front side 422 for the sensor elements 26. The stop elements 434 protrude from a bottom 438 of the recess.

The receptacles 436 are, in particular, a continuous recess extending perpendicular to the direction of movement R _v of the pretensioning mechanism 432.

Each preloading mechanism 432 is designed to act laterally in the direction of the two knock-off elements 434 and thus to preload a sensor element 26 arranged in the receptacle 436 laterally against the stop element 434 in a captive manner.

The pretensioning mechanisms 432 are formed mirror-symmetrically to a mirror plane 437, so that a pretensioning mechanism 432 and an associated receptacle 436 are present on each of the longitudinal sides 426 adjacent to the front side 422, wherein the mirror plane 437 extends through the stop elements 434. As can be seen in Figure 21B, the bottom 438 of each recess is provided with a plurality of shoulders 440, each having an upwardly facing contact portion. The contact portions are designed as flat surfaces. Grooves 444 extend between the shoulders 440.

More precisely, the recess comprises, at each of its lateral edges, a lateral contact section 441 formed as a shoulder 440, on which the sensor element 26 can rest flatly at the edge. Between the lateral contact sections 441, at least one central contact section 443 is provided, running parallel to the lateral contact section 441, on which the sensor element 26 also rests.

In a coupled state of sensor element 26 and sensor element holder 28, an intermediate, air-filled reflection channel 445 (see Figures 21A and 22A) is formed between the adjacent contact sections 441, 443.

As can be seen particularly clearly in Figures 21A, 22A and 25, each sensor element 26 in each receptacle 436 forms two reflection channels 445 in the region of the grooves 444. Each reflection channel 445 has an inlet opening 446, which corresponds to a first end face 428, and an outlet opening 447, which corresponds to the opposite second end face 426 of the sensor element holder 28.

The preloading mechanism 432 is explained in more detail below.

Each preloading mechanism 432 is associated with a clamping element 448.

The clamping element 448 comprises a guide section 450 in the form of a block, which is embedded in a matching recess 454 (see Figure 23) in one of the longitudinal sides 426. The guide section 450 guides the pretensioning mechanism 432 linearly in the plate-shaped body 420. The recess 454 is longer than the block in the direction of movement R _v of the pretensioning mechanism 432, so that the block can be guided linearly along the direction of movement R _v of the pretensioning mechanism 432.

A guide web 456 projects upwards from the guide section 450 and extends along the direction of movement R _v of the pretensioning mechanism 432 In particular, the guide web 456 and the guide section 450 merge into one another in one piece.

As shown in Figure 22C, the guide web 456 extends through the one recess in the sensor element holder to the respective receptacle 436.

The guide web 456 has a contact nose 460 (see Figure 21B) oriented toward the stop element 434, with a flat front end that has beveled flanks on both sides. The flat end of the contact nose 460 presses against the front of the sensor element 26 to securely clamp it in the receptacle 436.

To adjust the preload, the preload mechanism 432 is also assigned an adjusting screw 468, which can be screwed into a threaded bore 476 in the plate-shaped body 420 to different depths in order to move the preload mechanism 432.

Furthermore, a spring 482 is provided in an enlarged bore in the guide section 450, which spring preloads the adjusting screw 468 and thus the preloading mechanism 432 against the direction of movement R _v of the preloading mechanism 432.

To the side of the adjusting screw 468 (see Figure 23), each clamping element 448 has two lateral openings 484 for receiving guide pins 486, which are pressed into the plate-shaped body 420 and serve as linear guides.

The clamping element 448 is in particular made of a softer material (e.g., plastic) than the plate-shaped body 420, the stop elements 434, and the sensor element 26.

In addition, a through hole 491 (see Figure 23) is provided in the plate-shaped body 420.

The sensor element 26 is a crystal block. This has a substantially rectangular basic shape and has a sensor element back 494 (see Figure 22A) and two adjacent side surfaces 496, which terminate at the surface 30 of the sensor element 26. Between the Surface 30 of the sensor element 26 and the sensor element back 494 each have beveled end faces 498 provided.

Particularly preferably, the angle between the sensor element back 494 and the beveled front side is approximately 45 degrees.

Figure 22A further shows that the crystal block is placed with its sensor element backside 494 on the contact sections 441 and 443 for clamping into the sensor element holder 28. A side surface 496 of the crystal block rests against the end face of the contact nose 460. Tightening the adjusting screw 468 causes a linear advance of the clamping element 448 in the direction of the stop elements 434, so that the crystal block is clamped in the receptacle 436 between the stop element 434 and the clamping element 448.

Furthermore, as shown, for example, in Figure 21B, a notch 500 is provided in the plate-shaped body 420 in the area around the outlet opening 447 and the inlet opening 446, so that the beveled end faces 498 are not covered by the base 438 or the receptacle 436 in the direction of the rear side 424. As a result, an IR beam can impinge freely and almost perpendicularly on the beveled end face 498.

The sensor element holder 28 together with the sensor elements 26 accommodated therein can be engaged with the disposable fluid guide assembly 32, in particular with the base surface 316 of the block-shaped portion 314.

The coupled state of sensor element holder 28 with the sensor element 26 accommodated therein and the disposable fluid guide assembly 32 is shown in Figure 24.

For this purpose, the sensor element holder 28 is brought into planar contact with its front side 422 on the section of the base surface 316 surrounding the interaction paths 318 and is aligned with the block-shaped section 314 via upper recesses 502 (see Figure 21 B) provided on the front side 422 of the sensor element holder 28, in that its sleeve-shaped, protruding alignment projections (see Figure 8) penetrate precisely into the recesses 502. Screws 600 then protrude through the central holes of the Alignment projections 322 and are screwed into internal threads in the block-shaped section 314 in order to press the sensor elements 26 against the block-shaped section 314 and to close the interaction chambers 24 previously open on this side.

In order to attach the sensor element holder 28 to the disposable fluid guide assembly 32 in a manner that is secure from confusion and precisely positioned in the installation position, an alignment projection 322 and a recess 502, for example, are larger in diameter than the others.

The sensor element holder 28, which is attached to the disposable fluid guide assembly 32 and contains the sensor element 26, can then be coupled to the optical unit 34 of the protein defect diagnostic device 10. For this purpose, the sensor element holder 28, with the sensor element 26 contained therein, must be aligned in the beam path 42 in order to record an IR spectrum from the surface. Alignment is performed by the previously mentioned centering unit 56, which is explained in more detail below.

In order for the sensor element holder 28 to interact with the centering unit 56, the sensor element holder 28 is provided with an underside alignment geometry in the form of an elongated hole 606 and a round hole 608, which will be discussed in more detail below with reference to Figures 26 - 30.

The centering unit 56 has a contact side in the form of the base 616 (see Figure 27), which can be reversibly coupled to the sensor element holder 28 and on which the sensor element holder 28 rests flatly with its rear side 424. This is shown by way of example in Figures 26 and 27.

Furthermore, it can be clearly seen in Figures 26 and 27 that the centering unit 56 has the shape of a container 612. Preferably, the container 612 is made of a heat-conducting material, preferably a metallic material or an alloy.

The term “container” in connection with the accommodation of a part of the disposable fluid guide assembly 32 together with the sensor element holder 28 and sensor element 26 is intended to mean that a receptacle for these parts is designed here in order to supply heat or To enable heat dissipation. This does not require a closed or fluid-tight container, but rather a bottom 616 and one or more side walls 618 for heat transfer. Optionally, the bottom 616 and side wall(s) 618 can also be in contact with the sensor element holder 28 and the one-way fluid guide assembly 32. However, if the block-shaped section 314 is surrounded on all sides by the container 612, heat transfer is maximized.

A central recess 614 is provided in the container 612, which is defined by a bottom 616, a container opening opposite the bottom 616 and four side walls 618.

The floor 616 is closed, surrounded by the four side walls 618 in a frame-like manner.

Preferably, the shape of the central recess 614 corresponds to the shape of the cross section of the block-shaped portion 314 and/or the sensor element holder 28 in order to accommodate them without a large lateral gap. In the present case, the central recess 614 therefore has a rectangular basic shape.

As shown in Figure 27, the sensor element holder 28, which is equipped with the sensor element 26, can be inserted into the central recess 614 together with the block-like section 314, so that the rear side 424 rests flat on the base 616. The base 616 forms the contact side of the centering unit 56.

To align the sensor element holder 28 in the beam path 42, the centering unit 56 has two centering elements. These are explained in more detail in Figures 28 and 29.

The centering elements are designed as spring-loaded guide pins 622, each of which is guided in an associated through hole 624 in the bottom 616 of the container 612.

As shown in Figure 28, the guide pins 622 are not anchored in the container 612, but in a base block 626 which is arranged below the container 612 and supports it. The base block 626 has a substantially U-shaped profile, with two feet 625 and a support surface 627 on which the container 612 can be mounted. The guide pins 622 are also anchored in the support surface 627. The base block 626 can, for example, be attached to a base plate (not shown here) via its two feet 625.

Each of the two guide pins 622 has a conical end 628 which faces away from the base block 626 and projects into the central recess 614 of the container 612.

Adjoining the conical end 628 is a shaft 630 (see Figure 27), which extends laterally through the through-hole 624 in the bottom 616 of the container 612 and terminates in a centering recess on the contact surface of the base block 626, where it is anchored. Alternatively, the guide pins 622 can also be conical over the entire area in which they extend into the sensor element holder 28.

A preloading mechanism 634 with springs 642 is assigned to the centering recess to axially spring-load the guide pins 622 upward. To accommodate the springs 642, the guide pins 622 have a widened shaft section that is mounted in the base block 626.

The guide pins 622 can deflect in the axial direction to such an extent that the rear side 424 of the sensor element holder 28 strikes the bottom 616.

Centering via the centering unit 56 can be carried out as follows (see Figure 27). The sensor element holder 28 is first attached to the disposable fluid guide assembly 32 and can then be inserted with the rear side 424 first into the central recess 614, with a guide pin 622 engaging in the elongated hole 606 and a guide pin 622 engaging in the round hole 608. The sensor element holder 28 is thus aligned in the xy plane. For alignment along the z-axis and perpendicular to the z-axis, the sensor element holder 28 is pressed further towards the base 616, with the guide pins 622 yielding and guiding the sensor element holder 28 down to the base 616, where it comes into contact with its rear side 424. The sensor element holder 28 is thus aligned in the z-axis and perpendicular to it. The elongated hole 606 has an oval contour or is bevelled so that the guide pin 622 can engage better.

Furthermore, the container 612 is provided with two beam path shafts 645 (see Figures 27 and 28) which extend through two side walls 618, are arranged opposite each other and open into the central recess 614.

Consequently, the underside alignment geometry and the centering elements are coordinated with each other in such a way that the inlet opening 446 and the outlet opening 447 each point in the direction of one of the two beam path shafts 645.

Furthermore, the beam path shafts 645 each terminate at the base block 626 with their end facing away from the recess 614, wherein the base block 626 also contains beam path shafts 645 corresponding to and adjoining the beam path shafts 645 in the container 612. These also extend essentially completely through the base block 626. The beam path shafts 645 are configured to receive the beam path 42 and to guide it from the optical unit 34, which is typically arranged below the base block 626, via the beam path shafts 645 into the recess 614, into the sensor element 26, and out again.

Typically, the two beam path shafts 645 extend at a 45° angle to a plane in which the bottom 616 of the container 612 lies, so that the beam path has a right angle to the beveled end face 498.

Furthermore, a leakage protection unit (not shown here) can be provided, with a collecting basin (not shown here) that at least partially, preferably completely, surrounds the container 612 and a sensor (not shown here) for detecting fluid in the collecting basin, which sensor is connected to the controller 48, which is designed to output a signal when fluid escapes.

Furthermore, the container 612 (see Figure 30) has two media connection blocks 646, each of which is accommodated in a separate receiving opening 648 in the container 612. The media connection blocks 646 serve, as mentioned, to quickly and safely reversibly couple the conditioning fluid-carrying channels in the disposable fluid guide assembly 32 to the storage containers 94 and the disposal containers 174.

The receiving openings 648 for the media connection blocks 646 have an elongated, box-like shape and are provided on two opposite sides of the container 612. The two media connection blocks 646 will be discussed in more detail below in the description.

Furthermore, the container 612 has two receiving openings 650 for sensor element blocks 652, as shown in Figure 30.

The receiving openings 650 for sensor element blocks 652 have an elongated, box-like shape and are provided on opposite sides of the recess 614. In particular, a receiving opening 650 for sensor element blocks 652 is arranged between a receiving opening 648 for media connection blocks 646 and the central recess 614.

In particular, the two sensor element blocks 652 may each be detection units 653 equipped with optical sensors 651.

The detection units 653 are configured to contactlessly monitor the fluid flow adjacent to the ends 66, 70 of the interaction chamber 24.

For example, the detection unit 653 may be a source for generating radiation with specific wavelengths with which the fluid channels of the disposable fluid guide assembly 32 can be irradiated, or it may be a detector 684 that can detect radiation with specific wavelengths.

On the side of each of the two recess openings 650 facing away from the recess 614, a cable duct 654 is provided, which extends to the outer contour of the container 612 and connects it to the recess opening 650. Cables can be laid in the cable ducts 654 in order to connect the sensor element blocks 652 to the control unit 46, in particular the evaluation unit 50 and the controller 48, in a signal-transmitting manner. Furthermore, the two receiving openings 650 are each delimited by a wall 656 on a side facing the receiving openings 648, so that the sensor element blocks 652 are received in a securely positioned manner.

Above this, on the bottom 616 of the container 612, a thermal sensor element 660 is arranged which projects relative to the bottom 616, is axially prestressed and resiliently mounted (see Figure 31).

The thermal sensor element 660 extends in the coupled state into the through hole 491 in the sensor element holder 28 to detect the temperature of the sensor element backside 494 of the sensor element 26.

The media connection blocks 646 are explained in more detail below using Figures 32 to 34.

Each media connection block 646 has a block-shaped housing 686 with a top side 688 and a bottom side 690 arranged opposite thereto.

Between the top side 688 and the bottom side 690, end faces 692 extend at the opposite ends, which are each connected to one another via two longitudinal sides 694.

The media connection block 646 is received with the bottom 690 first in the receiving opening 648 so that the top 688 is exposed.

On the upper side 688, a plurality of first media inflow openings 698 are provided, only some of which are provided with reference numerals, as well as a plurality of second media inflow openings 700, wherein the plurality of first media inflow openings 698 are assigned to one longitudinal side 694 and the plurality of second media inflow openings 700 are assigned to the other longitudinal side 694. In more detail, the plurality of first media inflow openings 698 and the plurality of second media inflow openings 700 each lie on a straight line.

The first media inflow openings 698 and the second media inflow openings 700 of the upper side 688, each arranged in a row, are designed to be reversibly coupled to the media risers 414 of the disposable fluid guide assembly 32. The first media inflow openings 698 are each fluidically connected to openings 698' on one longitudinal side 694 and the second media inflow openings 700 are each fluidically connected to openings 700' on the other longitudinal side 694 via L-shaped media channel sections 702 (see in particular Figure 34).

The first openings 698' and the second openings 700' on the longitudinal sides 694 are designed to be reversibly coupled to the first or second fluid lines 100, 128 of the first and second media dosing units 16, 18, wherein a fluidic connection is present in the coupled state.

In the present case, eight first media inflow openings 698 and three second media inflow openings 700 are provided on the top side 688 and on a longitudinal side 694. Of course, the number can be varied.

Furthermore, the upper side 688 can have a flushing fluid connection 704 which is fluidically connected to a flushing fluid connection 704' on the longitudinal side 694 via an L-shaped flushing fluid channel section 706.

Furthermore, two disposal channel connections 708 are provided on the upper side 688, which are each fluidically connected via an L-shaped disposal channel section 710 to a disposal channel connection 708' on the longitudinal sides 694.

Advantageously, the media connection block 646 just described can be used for both the left side of the disposable fluid guide assembly 32 and the right side of the disposable fluid guide assembly 32, since two different flow paths through the plurality of first and second media inflow openings 698, 700 are provided in a single component. In other words, depending on the application, either the first media inflow openings 698 or the second media inflow openings 700 couple to the media risers 414 of the disposable fluid guide assembly 32 and to the fluid lines 100, 128 of the first and second media dosing units 16, 18.

Furthermore, on the upper side 688 (see Figure 33) a sealing element 712 in the form of a flat, elastic membrane is provided, which has a plurality of recesses which are connected to the underlying media inlet openings 698, 700 on the upper side 688. The sealing element 712 is designed to seal the fluidic connection in the coupled state with the media risers 414 of the disposable fluid guide assembly 32 by clamping the sealing element 712 flatly between the upper side 696 and the underside 274 of the lower part 268 and elastically deforming it.

Furthermore, the media connection block 646 has alignment geometries 718 on its top side 688, which can be engaged with counter-alignment geometries 720 (see Figure 36) on the one-way fluid guide assembly 32 in order to align with the one-way fluid guide assembly 32.

The alignment and counter-alignment geometries 718, 720 may, for example, be corresponding pins and openings that each engage with each other during coupling.

The media connection block 646 is equipped at its two opposite ends on the underside 690 with an anchor pin 722, with which it is received with an oversize in corresponding holes in the area of the receiving opening 648.

Optionally, the anchor pins 722 can be assigned a locking mechanism provided in the receiving opening 648, so that the receiving openings 648 can be reversibly coupled to the media connection blocks 646. This allows the media connection blocks 646 to be easily removed from the receiving openings 648 and cleaned.

Furthermore, the media connection blocks 646 can be deflected towards the rear side 424 of the sensor element holder 28 and/or tilted in several spatial directions and are in particular resiliently mounted.

The resilient mounting is achieved by a first pair of springs 724, which support the underside 690 against the top of the associated receiving opening 648.

In addition, a plurality of second springs 726 are provided, in particular between the first pair of springs 724. The plurality of second springs 726 are also associated with the underside 690, but extend almost completely into the block-shaped housing 686. As a result, only a portion of the A group of second springs 726 protrudes from the underside 690. The springs 724 and 726 simulate a cardanic suspension.

The following section discusses the temperature control unit 58 in detail. This is particularly clearly visible in Figure 31.

The temperature control unit 58 comprises the temperature control element 254, which can be brought into surface contact with the rear side 424 of the sensor element holder 28. The temperature control unit 58 is configured to bring the sensor element 26 to a predetermined temperature in a coupled state of the sensor element holder 28, the sensor element 26, and the temperature control element 254.

The predetermined temperature is preferably room temperature. Room temperature is defined as a temperature between 17°C and 26°C.

Particularly preferred, as shown in the present case, is the entire container 612 or sections of it forming the temperature control element 254. This allows a particularly compact design of the protein defect diagnostic device 10 to be achieved.

In the coupled state between the disposable fluid guide assembly 32 and the temperature control element 254, the interaction chamber 24 can be received together with the sensor element holder 28 and the sensor element 26 in the recess 614, so that the rear side 424 of the sensor element holder 28 rests on the bottom 616 of the container 612, in particular wherein the side walls 618 of the disposable fluid guide assembly 32 and/or the sensor element holder 28 rest against side walls 618 of the container 612 or are only minimally distant from them.

Consequently, the block-like portion 314 protruding from the underside 274 of the lower part 268 is completely received in the container 612.

As shown in Figure 31, the tempering element 254 comprises at least one tempering channel 728 inside the container 612, which passes through one or more side walls 618 and/or the bottom 616 of the container 612.

Particularly preferably, several temperature control channels are provided which extend through the container 612. For this purpose, the container 612 has an inlet 732 and an outlet 734, between which the one or more tempering channels 728 extend in the container 612.

In other words, the temperature control channels 728 completely surround the circumference of the recess 614, so that the latter is temperature-controlled particularly evenly. Since the temperature control channels 728 extend almost completely through the interior of the container, the media connection blocks 646 are also advantageously temperature-controlled.

A tempering fluid (not shown here) flows through the tempering channel 728, which is introduced into it by the tempering device 258. The tempering device 258 tempers the tempering fluid to the predetermined temperature or to a temperature slightly higher or lower than the predetermined temperature in order to compensate for temperature losses during transport.

The temperature control device 258 is arranged outside the container 612 and is fluidically coupled to the inlet 732 and the outlet 734, creating the aforementioned temperature control circuit 260. In this circuit, the temperature control fluid is introduced from the temperature control device 258 into the inlet 732 of the container 612. There, it flows through the temperature control channels 728, thereby controlling the temperature of the container 612. This can bring the sensor element holder 28 and thus also the sensor element 26 to the predetermined temperature, since they are connected in a heat-transfer manner when coupled.

The pneumatic unit 14 is discussed in detail below. Reference is made to Figures 35 and 36.

Specifically, the pneumatic unit 14 is designed as a pneumatic connection block 758, which has a bottom side 760 facing the disposable fluid guide assembly 32 and a top side 762 facing away from it.

The top side 762 is provided with a plurality of pneumatic units 764 which are fluidly coupled to pump inlets 766 provided on the top side 762.

As can be seen in Figure 36, the underside 760 has a media dosing interface 768 at opposite ends, which is connected to a elastic sealing membrane 770, at which pump outlets 772 open, which are fluidly connected to the pump inlets 766 on the top side 762 and of which only some are provided with reference numerals.

The sealing membrane 770 therefore has recesses corresponding to the pump outlets 772.

Each media dosing interface 768 is configured to fluidly couple, in a coupled state with the disposable fluid guide assembly 32, to the pneumatic channel openings 310 of the pneumatic channels 311 in order to apply positive or negative pressure to the pneumatic channels 311.

In particular, each media dosing interface 768 is formed as an elongated, rectangular elevation having a rib-shaped contact surface 774 on its opposite longitudinal sides, against which the rib-shaped structure of the outer side of the sample receiving containers 200, 204 can be supported in the coupled state. Consequently, in the coupled state, the disposable fluid guide assembly 32 is held securely in the pneumatic connection block 758.

In addition, the underside 760 of the pneumatic connection block 758 is equipped with a detection unit 653 in the form of a sensor unit 776, which is provided with several sensors 777.

The sensors 777 can be either sources and/or detectors that interact with corresponding sources and/or detectors in the sensor element blocks 652. In the coupled state, a beam path exists between the two, via which optical signals can be sent and received. The free exchange of optical signals is ensured by the sensor windows 306, 308, which allow a beam path perpendicular through the one-way fluid guide assembly 32 and provide optical access to other fluid channels adjacent to the sensor windows 306, 308 for the beam path. In addition, the underside 760 is provided with alignment geometries, for example in the form of guide pins 780, with which the pneumatic connection block 758 can be aligned to the one-way fluid guide assembly 32.

In addition to the media dosing interfaces 768, a blood sample intake interface 784 is provided, which is shaped as a recess.

The blood sample containers 202 and 204 can engage in the recess to be supported in a way that prevents them from slipping.

The pneumatic connection block 758 is further coupled to a drive assembly 788 associated with the surface 30 of the sensor element 26 (see Figure 35), which is configured for linear displacement of the pneumatic connection block 758 and thus for rapid fluidic coupling and decoupling and thus replacement of the disposable fluid guide assembly 32.

For this purpose, the drive assembly 788 has a drive, e.g., a crank 790, to which a spindle 792 is connected in a rotationally fixed manner. The spindle 792 passes through a threaded nut 796, which is attached to a drive block 798, which has a drive surface 800 on its underside for engagement with the pneumatic connection block 758.

The drive block 798 is guided linearly via rods 804 in the base block 662.

In order to put the protein defect diagnostic device 10 into operation, the sensor element holder 28 and thus the disposable fluid guide assembly 32 are first aligned by the centering unit 56.

When the disposable fluid guide assembly 32 is placed on and pressed down, the two movably mounted media connection blocks 646 align with the disposable fluid guide assembly 32. Subsequently, by operating the crank 790, the pneumatic connection block 758 can be guided downward along the centering rods 804 toward the container 612 until the underside 760 of the pneumatic connection block 758 rests against the top side 288 of the disposable fluid guide assembly 32. The pneumatic connection block 758 also extends toward the disposable fluid guide assembly 32. This means that the entire device is aligned according to the position of the optical unit 34. Overall, a positive connection is created between the media connection blocks 646 and the one-way fluid guide assembly 32, which is clamped between the media connection blocks 646 and the pneumatic connection block 758. The clamping achieves a fluid connection of the one-way fluid guide assembly 32 to the pneumatic connection block 758 as well as a fluidic connection between the media connection blocks 646 and the one-way fluid guide assembly 32.

Furthermore, the disposable fluid guide assembly 32, in particular the sensor element holder 28, is finally aligned in the beam path 42. The protein defect diagnostic device 10 is in an operational state, so that the surface 30 of the sensor element 26 can either be conditioned and/or brought into contact with a blood sample. Furthermore, an IR spectrum of the surface 30 of the sensor element 26 can now be recorded via the optical unit 34.

A hydraulically or purely electrically operated drive assembly 788 is also conceivable.

Figure 37 shows a schematic flow diagram of the method steps for conditioning a sensor element for a protein defect diagnosis and for applying a blood sample to a sensor element for a protein defect diagnosis as well as for analyzing protein defects in a blood sample.

The procedural steps are explained in more detail below.

First, a sensor element is attached to the disposable fluid guide assembly such that the sensor element closes several interaction chambers on one side, wherein the sensor element has a surface to be treated which forms the previously open side of the interaction chamber (step S5).

Thereafter, a linker-containing conditioning fluid is introduced into the interaction chambers below a preconditioned surface on the sensor element to which at least one linker is bound, to which antibodies can specifically bind (step S6). Next, the linker-containing conditioning fluid is passed out of the interaction chamber via the fluid channels (step S7).

Optionally, the interaction chamber can be flushed with a flushing fluid (step S8), which serves for cleaning and venting.

Optionally, the interaction chamber can be in contact with a fluid until an antibody-containing conditioning fluid is introduced into the interaction chamber. The fluid can, for example, be a buffer fluid to prevent the interaction chamber from running dry. This can be achieved by leaving a residue of a fluid, e.g., a buffer fluid, in the interaction chamber after the respective process steps. This can then be displaced by the antibody-containing conditioning fluid, so that the interaction chamber is always kept moist.

Thereafter, the antibody-containing conditioning fluid is introduced into the interaction chamber below an antibody-conditioned surface on the sensor element to which at least one antibody is bound, to which a candidate biomarker can bind in a protein-specific and conformation-independent manner (step S9).

Optionally, the interaction chamber can be rinsed with a rinsing fluid after the previous step (step S10). Subsequently, further corresponding steps can be performed with other conditioning fluids to condition the surface of the sensor element.

Optionally, the interaction chamber can be in contact with a fluid until a blood sample is introduced into the interaction chamber. Here, too, the fluid can be a buffer fluid, for example, to prevent the interaction chamber from running dry. This can be achieved by leaving a residual fluid in the interaction chamber after the respective process steps. This can then be displaced by the blood sample, keeping the interaction chamber moist until the sample is applied.

Subsequently, the blood sample is introduced into the interaction chamber below a surface that is in a ready-to-measure state (step S11). Finally, the surface, which is in a ready-to-measure state, is irradiated with IR radiation below an IR spectrum (step S12).

Figure 38 shows another schematic flow diagram for the process steps for analyzing protein defects in a blood sample. The individual process steps are explained in detail below.

In the first step, a conditioning fluid is passed from the first fluid channel through the interaction chamber into the second fluid channel (step S13).

Subsequently, the conditioning fluid is returned along the second fluid channel through the interaction chamber into the first fluid channel (step S14).

Steps S13 and S14 may be repeated for a predetermined period of time or until a predetermined number of cycles is reached.

Subsequently, a blood sample can be passed along a first flow direction from a first sample receptacle through the interaction chamber into the second blood sample receptacle (step S15).

Optionally, the fluid flow of the blood sample can be measured along the first flow direction, whereby upon detection of an air front or an irregularity in the fluid flow, a flow reversal opposite to the first flow direction is initiated.

Thereafter, the blood sample can be guided along a second flow direction, which is opposite to the first flow direction, from the second sample receptacle through the interaction chamber into the first sample receptacle S16.

Optionally, the fluid flow of the blood sample can be measured along the second flow direction, wherein upon detection of an air front or an irregularity in the fluid flow, a flow reversal opposite to the second flow direction is initiated. Preferably, the flow reversal is initiated when the respective container from which the fluid flow originates is completely empty. This can be determined in particular by detecting the air front, since this means that the respective The fluid-conveying container is completely emptied. This ensures particularly precise control of the fluid flow. By initiating the flow reversal, air bubbles can be prevented from entering the interaction chamber right from the initial filling stage.

Steps S15 and S16 may be repeated for a predetermined number of cycles or for a predetermined period of time.

Finally, the surface of the sensor element is irradiated with IR radiation to obtain an IR spectrum (step S17).

Optionally, steps S15 and S16 may be performed during step S17.

In particular, during at least one of the steps S15 - S17, the surface of the sensor element can be tempered, in particular to room temperature.

Also, during at least one of the steps S15 - S17, preferably all steps S15 - S17, the surface of the sensor element can be tempered, in particular to room temperature.

Figures 39 A and B show alternative couplings between the one-way fluid guide assembly 32 in the area of the membrane element 368 (see Figure 10) to the adjacent pneumatic connection block 758.

Optionally, one or more seals 900 serving as covers can be provided on the adjacent pneumatic connection block 758 between the disposable fluid guide assembly 32 in the region of the membrane element 368 and the pneumatic connection block 758 located above it (see Figure 39 A), which seals close one or more sample receptacles 200 in the region of the sample inlets 366, together with the hydrophobic membrane element 368 clamped between the pneumatic connection block 758 and the sample receptacle 200.

The pneumatic connection block 758 may have one or more annular projections on the underside opposite the seal 900, which press into the seal 900 and improve the sealing effect. The seal 900 has a hole 904 that leads to the interior of the sample receptacle 200.

Furthermore, conversely, a seal 900, which forms a lid and simultaneously acts as a flat pinch seal, can be inserted into a sample inlet 366 like a plug (see Figure 39B). This seal 900 is attached to the disposable fluid guide assembly 32 and not only seals the larger opening in the form of the sample inlet 366 in the disposable fluid guide assembly 32, but also, thanks to its flange, forms a seal between the front side of the sample receptacle 200 and the opposite underside of the pneumatic connection block 758.

For example, a hydrophobic membrane element 368 is bonded to the top of the seal 900 and seals off liquids against an opening 902 in the pneumatic connection block 758, but allows air to pass through so that pressure can be applied to the sample via the hole 904 in the seal 900 or negative pressure can be applied in the sample receiving container 200.

The seal 900 has a protruding annular bead 908 in the area of its flange at the top and/or bottom, which acts as a sealing ring. Thus, the seal 900, which acts as a cover, has a sealing profile on its end face facing the sample inlet 366 and on the opposite end face.

It should be emphasized that other receptacles or containers of the device can also be designed with a corresponding membrane element and/or lid, e.g. the disposal container 175 or the rinsing liquid container(s) 158, 166, which can alternatively be designed as separate containers outside the disposable fluid guide assembly, as separate containers directly coupled to the disposable fluid guide assembly, or as containers formed integrally with the disposable fluid guide assembly.

Generally speaking, one or more fluid tanks, which can be filled with body fluid or other fluid, are designed either as a separate part in the form of a container that is attached to the disposable Fluid guide assembly 20 can be coupled or can be an integral part of the upper part 284 or the lower part 268.

The just mentioned separate design of the container is described below in Figure 40 using the example of the sample receiving container 200, 204, whereby this design is not limited to a sample receiving container, but is also applicable to the disposal container or a rinsing liquid container which can be coupled to the disposable guide assembly.

In Figure 40, the sample receiving containers 200, 204 are designed as separate containers 912 and are no longer an integral part of the upper part 284. This separate container 912 is coupled to the upper part 284 via a snap-in connection 920, in that snap-in fingers protrude from the upper part 284 and engage a recess in the container 912.

To ensure that the liquid-filled container 912 is sealed upon delivery, it is preferably sealed at its bottom with a film (not shown). A spike protrudes upward from the upper part 284 in the area of the sample riser 384. This spike pierces the film when the container 912 is placed in place and an annular seal 922 between the container 912 and the upper part 284 has already been slightly compressed, so that the container 912 already rests tightly against the upper part 284.

Alternatively, a screw connection can be provided instead of the snap-in connection. The fingers shown are then a circumferential, protruding sleeve with an internal thread, and the container 912 has a corresponding external thread on its outside.

On the top side, the container 912 is optionally closed by a lid and/or a hydrophobic membrane element at the sample inlet 366, as previously mentioned.

Claims

Patent claims 1. Disposable fluid guide assembly (32) for a microfluidic device (12) for detecting molecular biomarkers in a sample of a body fluid, comprising a lower part (268) with a fluid side (272) and an opposite lower side (274) and an upper part (284) with an upper side (288) and an opposite pneumatic side (290) adjacent to the fluid side (272) of the lower part (268), wherein the upper part (284) on the pneumatic side (290) and the lower part (268) on the fluid side (272) each have a plurality of channels formed by grooves (340, 346), wherein the disposable fluid guide assembly (32) further provides at least one sealing element (330) which has oppositely arranged Pneumatic channels (311) in the upper part (284) and fluid channels (74, 78, 216, 224) in the lower part (268) are fluidically separated from one another, wherein an interaction chamber (24) which is open to the underside (274) is formed in the lower part (268) and which can be closed by a sensor element (26) which can be attached to the underside (274) and is preferably flat to the underside (274), wherein diaphragm valves (76, 80, 190, 196) are formed between the pneumatic side (290) and the fluid side (272) by the one or more sealing elements (330), via which fluid channels (74, 78, 216, 224) leading to and away from the interaction chamber (24) can be opened and closed. 2. Disposable fluid guide assembly (32) according to claim 1, characterized in that the upper part (284) has pneumatic channels (311) opening at the upper side (288) which end at associated diaphragm valves (76, 80, 190, 196) in order to switch them. 3. Disposable fluid guide assembly (32) according to claim 1 or 2, characterized in that the lower part (268) has fluid channels (74, 78, 216, 224) opening at the underside (274) and leading to opposite ends of the interaction chamber (24), the media channels (88, 122) for the flow of Form a medium (96) for treating the surface (30), in particular wherein sensor windows (306, 308) are provided in the upper or lower part (268, 284) which lead adjacent to the opposite ends (66, 70) up to close to the fluid channels (74, 78, 216, 224). 4. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the upper part (284) has at least one first sample receptacle (20) on the upper side (288), in particular in the form of a chamber or a molded-on container (200), or a container (912) forming a sample receptacle (20), structurally separate from the upper part (284) and the lower part (268), and attached to the upper part (284) or to the lower part (268) is provided, wherein the molded-on or the separate container (912) is fluidically connected to a fluid channel (74) designed as a sample channel (188) in the disposable fluid guide assembly (32), which fluid channel can be selectively connected to the interaction chamber (24) via a diaphragm valve (190, 196). 5. Disposable fluid guide assembly (32) according to claim 4, characterized in that the sample receptacle (20) is formed by a cavity (352) in the upper part (284) and an adjoining cavity (354) in the lower part (268) and the sample channel (188) extends from the cavity (354) in the lower part (268). 6. Disposable fluid guide assembly (32) according to claim 5, characterized in that a second sample receptacle (22) is formed in the upper part (284), which is fluidically connected to the interaction chamber (24) and the first sample receptacle (20) via a sample channel (194), or wherein the second sample receptacle (22) is designed as a separate container (912) which is fluidically coupled to the upper part (284) or to the lower part (268), in particular wherein the second sample receptacle (22) is a mirror image of the first with respect to the interaction chamber (24). 7. Disposable fluid guide assembly (32) according to claim 5 or 6, characterized in that the sample receptacles (20, 22) have an opening forming a sample inlet (366) for applying pressure or negative pressure, in particular that the opening forming the sample inlet (366) is closed in a gas-permeable and liquid-tight manner by a membrane element (368) and/or a cover, wherein the membrane element (368) is designed as a hydrophobic, gas-permeable membrane film is designed to be able to subject the sample holder via the membrane element to overpressure and negative pressure or to overpressure and ambient pressure. 8. Disposable fluid guide assembly (32) according to claim 7, characterized in that the opening forming the sample inlet (366) is closed by the cover projecting into the opening as a plug together with a membrane element closing a hole (904) in the cover in a gas-permeable and liquid-tight manner, in particular wherein the membrane element (368) adjoins an end face of the cover and the cover is formed as a sealing profile on its end face facing away from the sample inlet (366). 9. Disposable fluid guide assembly (32) according to one of claims 5 to 8, characterized in that the at least one separate container (912), which forms a sample receptacle (20, 22), is coupled in a fluid-tight manner to the upper part (284) or to the lower part (268) by a screw or a snap-in connection. 10. Disposable fluid guide assembly (32) according to claim 3 and additionally according to one of claims 5 to 9, characterized in that media channels (88, 122) open at opposite ends (66, 70) of the interaction chamber (24), each of which opens at a media connection (114, 142) on an outer surface of the upper part (284) or lower part (268), and in that the sample channel (188, 194) and the media channel (88, 122) are combined at an interface (214, 222) to form a common fluid channel (216, 224), wherein a diaphragm valve (190, 196) is located at the interface (214, 222) and controls the inflow of body fluid or medium (96) into the common fluid channel (216, 224). 11. Disposable fluid guide assembly (32) according to claim 10, characterized in that the diaphragm valve (190, 196) at the interface (214, 222) can control the inflow of body fluid and a further diaphragm valve (76, 80) is provided in the media channel (88, 122) between the interface (214, 222) and a media connection (114, 142) in order to control the media flow. 12. Disposable fluid guide assembly (32) according to claim 10 or 11, characterized in that for each interaction chamber (24) a common fluid channel (216, 224) ends at opposite ends (66, 70), which then splits into a media channel (88, 122) and a sample channel (188, 194), wherein a diaphragm valve (190, 196) is provided at the respective interface (214, 222) and in the media channel (88, 122). 13. Disposable fluid guide assembly (32) according to one of claims 10 to 12, characterized in that the sample channel (188, 194) forms a sample riser (384) towards the interface (214, 222), which is surrounded by the valve seat (386), wherein the media channel (88, 122) splits into two sub-channels (390) and runs around opposite sides of the sample riser (384), wherein the sub-channels (390) reunite after the sample riser to form the interaction chamber (24). 14. Disposable fluid guide assembly (32) according to one of claims 10 to 13, characterized in that the sample channel (188, 194) has a throttle section (376) with a reduced cross-section, in particular an elongated throttle section (376) between the sample receptacle (20, 22) and an interface (214, 222) to the media channel (88, 122). 15. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that a plurality of interaction chambers (24), in particular arranged in parallel, are provided on the underside (274), into which fluid channels (74, 78, 216, 224) controlled by separate diaphragm valves (76, 80, 190, 196) open at opposite ends (66, 70), in particular that the fluid channels (74) or groups of these fluid channels assigned to one end (66, 70) of the interaction chambers (24) branch off from a common distribution channel (116) which leads to a central media connection (114). 16. Disposable fluid guide assembly (32) according to claim 15, characterized in that flushing channels (152, 160) branch off from the fluid channels (74, 78) at one end of the interaction chambers to a flushing fluid container (156, 166), which can each be opened via their own flushing valves (154, 164) and which preferably unite to form a central flushing channel (162). 17. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the disposable fluid guide assembly (20) has at least one liquid tank which is not filled with body fluid and is formed in the upper part (284) and/or in the lower part (268) or is coupled to the upper part (284) and/or to the lower part (268) as a separate part and is fluidically coupled to the at least one interaction chamber (24), in particular wherein the liquid tank is filled with cleaning fluid or conditioning fluid (96). 18. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the disposable fluid guide assembly (20) has at least one disposal container (175) which is formed in the upper part (284) and/or in the lower part (268) or is coupled to the upper part (284) and/or to the lower part (268) as a separate part and is fluidically coupled to the at least one interaction chamber (24) such that fluid emerging from the interaction chamber (24) can flow into the disposal container (175). 19. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the lower part (268) has a plate-shaped section (270) and a block-shaped section (314) projecting from the plate-shaped section (270) from the underside, in which the at least one interaction chamber (24) is formed, which is open to this underside (274) and/or wherein the upper part (284) is plate-shaped. 20. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the upper part (284) and the lower part (268) have at least one of the following properties: • the upper part (284) and the lower part (268) are glued, welded, screwed together, • the upper part (284) and the lower part (268) are injection-molded, in particular from cyclo-olefin copolymers (COC), • the upper part (284) and the lower part (268) have assembly aids, in particular in the form of guide pins (283) or recesses (282, 298). 21. Disposable fluid guide assembly (32) according to one of the preceding claims, characterized in that the sealing element (330) is a flat, planar or profiled membrane which forms a plurality of membrane valves (76, 80, 190, 196) and separates a plurality of pneumatic (311) and fluid channels (74, 78) from one another, in particular wherein the membrane (330) has cutouts (336) to create a fluid connection for a blood sample (212) between the upper side (288) and the lower side (274). 22. A method for manufacturing a disposable fluid guide assembly (32) according to any one of the preceding claims, the method comprising the following steps: a) injection molding a lower part (268); b) injection molding an upper part (284); c) arranging the sealing element (330) between the lower part (268) and the upper part (284); and d) connecting the upper and lower parts (268, 284) to one another while clamping the sealing element (330). 23. A microfluidic device (12) for detecting molecular biomarkers in body fluids, in particular protein defects in a blood sample (212), comprising a disposable fluid guide assembly (32) according to any one of claims 1 to 22, and a pneumatic unit (14) which can be reversibly coupled to the disposable fluid guide assembly (32), wherein the pneumatic unit (14) is fluidly connected to the pneumatic channels (311) in the coupled state and is configured to apply pressure and vacuum to them, and at least one media dosing unit (16, 18) which can be reversibly coupled to the disposable fluid guide assembly (32), wherein the media dosing unit (16, 18) is fluidly connected to the interaction chamber via the fluid channels (74, 78) of the lower part in the coupled state. 24. Biomarker detection device (10), comprising a microfluidic device (12) for surface treatment of a sensor element (26) for protein defect detection according to claim 24, wherein the Biomarker detection device (10) comprises a sensor element (26) which closes the interaction chamber (24) with its surface-treated upper side (30) on the underside, and an optical unit (34) which has an IR source (36), an IR detector (38) and a beam path (42) through the interaction chamber (24) connecting the IR source (36) and the IR detector (38), wherein the optical unit (34) is configured to guide the IR radiation generated by the IR source via the sensor element (26) to the IR detector (38) via the beam path (42) in order to record an IR spectrum from the surface (30) of the sensor element (26).