RU178180U1 - Cartridge for highly specific detection of biomarkers on a quartz resonator - Google Patents

Abstract

The utility model relates to medical and biological technology, namely to auxiliary equipment for conducting a markerless analysis of molecular interactions and can be used, for example, when conducting research in the field of genomics, proteomics and molecular diagnostics. The technical result of the development is to achieve high sensitivity and specificity for the detection of biomarkers in the analyzed fluids representing a sample of protein and nucleic nature. The technical result is achieved by the fact that to The cartridge for highly specific detection of biomarkers on a quartz resonator contains a housing in which a cell for introducing a test sample and an analytical cell containing a quartz resonator, which is a polished quartz AT-cut plate with a circular shape with a diameter of 0.85, are formed interconnected through a microfluidic channel system see, on both sides of which there are electrodes, on the conductive paths of which specialized agents for biomarker detection are immobilized, and size The contact system located on the housing provides electrical connection of the resonator electrodes with external sources.

Description

The utility model relates to medical and biological technology, namely to auxiliary equipment for conducting a markerless analysis of molecular interactions, and can be used, for example, when conducting research in the field of genomics, proteomics, and molecular diagnostics.

The technical solution proposed for protection was developed while performing applied scientific research on the topic: “Development of a prototype device for highly specific detection of biomarkers on a quartz resonator”, a unique identifier of applied scientific research is RFMEFI60715X0125, for which Agreement No. 14.607.21.0125 on granting a subsidy to the Russian Ministry of Education and Science was concluded.

A known cartridge for researching biomaterial (patent RU No. 164923), comprising a housing in which there is a cell for introducing the biological sample under study, a microfluidic channel system, at least 4 research chambers, each of which has a pair of electrodes for measuring impedance. Moreover, in three chambers are placed inducers initiating platelet aggregation, and the fourth is implemented as a control.

The known cartridge is intended solely for conducting blood tests by impedance aggregometry and does not allow highly specific detection of biomarkers in the analyzed objects (urine, blood, saliva, model solutions, etc.).

Known, selected as the closest analogue cartridge for the study of biological material (US patent No. 5201215), used in the implementation of the quartz microweighting method.

The known cartridge contains a chamber in which a quartz crystal is placed, which is a round plate with two electrodes on opposite planes.

The quartz crystals used in the analogue under consideration are made of polished plane-parallel AT-cut quartz plates, on the surfaces of which electrodes are formed by thermal spraying of the metal under high vacuum. The diameter of the quartz crystals is 2.54 cm, the thickness is 0.33 mm, and the resonant frequency is 5 MHz.

Quartz crystals have two electrodes located on opposite sides of the plate, with one larger electrode being grounded, and a potential being applied to the second smaller electrode. A larger electrode (grounded) is in contact with the contact-conducting strip, which is also deposited on the side surface of the quartz plate and displayed on the same plane on which the smaller electrode is located, allowing contact with the electrodes on one side of the quartz crystal.

For measurements, quartz crystals are installed in the aluminum mount of the device. Moreover, the device allows you to correctly position the quartz crystal by connecting the RF connector directly to the smaller electrode and making the ground connection with the large electrode. Contact connection is carried out by soldering the corresponding electrodes with the necessary connectors using a solder consisting of 1: 1 Pb: In. The aluminum mount has an opening that allows the liquid to contact the grounded quartz crystal electrode.

The device cited as the closest analogue does not allow solving the technical problem of highly specific and sensitive detection of biomarkers, since the analysis technique does not allow differentiating molecules deposited on the surface. In addition, quartz crystals with a resonant frequency of 5 MHz, having large sizes and specific electrode geometry, are used in the analogue under consideration. These quartz crystals will not allow to achieve the necessary sensitivity.

The disadvantages of the nearest analogue also include the fact that it is a reusable tool, which means that the potentially infected sample is not prevented from entering the workplace or clothing of the operator performing the analysis. In addition, the lack of design of technological solutions for the precise dosing of the test sample in a cell with a quartz crystal is also a disadvantage.

The claimed technical solution is aimed at solving the problem of creating auxiliary devices for conducting highly specific sensitive detection of biomarkers by detecting a bond break on a quartz crystal.

The technical result of the development is the achievement of high sensitivity and specificity for the detection of biomarkers in the analyzed liquids, representing a sample of protein and nucleic nature.

The technical result is achieved in that the cartridge for highly specific detection of biomarkers on a quartz resonator contains a housing in which channels are connected to each other through a microfluidic system, a cell for introducing the test sample, and an analytical cell containing a quartz resonator, which is a polished quartz AT-cut plate round with a diameter of 0.85 cm on both sides of which there are electrodes, on the contact-conducting paths of which specialized These are agents for the detection of biomarkers, and a contact system placed on the housing, which provides electrical connection of the resonator electrodes with external sources.

The essence of the technical solution is illustrated by the following description and the accompanying figures.

In FIG. 1 shows a structural and functional diagram of a cartridge for the study of biological material, reflecting its basic elements and their purpose.

In FIG. Figure 2 shows a schematic diagram of a quartz resonator with electrodes used in a cartridge, the surface of which is subjected to the immobilization of specialized agents in order to detect target biomarkers.

In FIG. 3 is a schematic view of a cartridge explaining the arrangement of its elements inside the housing, where: 1 is a sample input cell; 2 - microfluidic system of channels; 3 - analytical cell; 4 - quartz resonator; 5 - system of electrical contacts.

The solution to a technical problem, the achievement of a technical result is provided as follows.

Firstly, the cartridge is made with a non-separable case, providing isolation of the cartridge elements from the volume outside the case in order to eliminate extraneous influences. The functional elements of the cartridge are implemented inside the housing (see Fig. 1), without the possibility of removing them from the housing and conducting any manipulations with them. Thus, the study excludes the entry into the cartridge of any contaminants that provide analysis errors.

Secondly, the key element of the cartridge is a quartz resonator 4 in the form of a plate, provided with a pair of electrodes on surfaces opposite to each other, located in the analytical cell 3, being specialized agents immobilized on its surface in order to detect target biomarkers.

The cartridge is implemented by a non-separable disposable tool for highly specific detection of biomarkers in the analyzed liquids of protein and nucleic nature. After the first use of the cartridge, reuse of the design is not provided. Thus, the quality and accuracy of the analyzes are guaranteed. The detection technique (for which the design of the resonator has been developed) provides for the elimination of nonspecific binding and allows the detection of specific interactions. The result is a high sensitivity analysis.

Thirdly, the microfluidic system of 2 channels is made in the cartridge, which delivers the analyzed sample to the quartz resonator 4 of a fixed volume, ensuring its optimal flow through the cartridge elements and enters the analytical cell 3. Moreover, system 2 contains an input channel that ensures the sample is received from cell 1 the input of the sample into the analytical cell 3 and the connecting channel, providing communication of the analytical cell 3 with the external space (outside the cartridge housing). The message is necessary for the release of air so as not to impede the flow of the sample into cell 3 from cell 1 and fill it to the required level.

Fourthly, the reception of the sample is limited by the volume of the analytical cell 3 and the volume of channels, which allows you to always carry out the analysis with a fixed sample volume.

An outlet is necessary for the release of air so as not to impede the flow of the sample into the quartz crystal cell 3 from the sample inlet 1 cell and fill it to the required level.

Fifth, a quartz resonator 4 with electrodes and contact-conducting paths is located in the analytical cell 3 with rigid fixation at the edges. Fixation at the edges provides a practical absence of deterioration of the quality factor of a quartz resonator.

The cartridge for the study of biological material is used as follows.

      The cartridge is inserted into the analyzer device, matching the external terminals 5 of the contacts at the end of the case with the corresponding terminals of the analyzer and, thus, supply voltage to the electrodes of the quartz resonator 4. The sample to be examined beforehand, for example, blood, is supplied to sample input cell 1 . Under the action of capillary forces, the fluid representing the sample to be studied flows through the direct channel of the microfluidic system of 2 channels and fills the volume of the analytical cell 3 in which the quartz resonator 4 is placed. It is firmly fixed, has a strictly defined position and its surface contains an immobilized receptor layer. The analyzed sample arriving in cell 3 exerts a displacing effect on the air in the cell. The displaced air through the curved channel of the microfluidic system of 2 channels and the outlet at the end of the housing goes out. The air outlet through a curved channel with a length of at least 3 mm ensures complete filling of the second part of the cavity of the cell 3, without air bubbles in the filled volume, and prevents the excess of the analyzed sample from flowing out through the outlet. Thus, the volume of the analyzed sample is strictly fixed. Upon receipt of the sample in the analytical cell 3, the molecules of the analyzed sample are bound to the receptor layer immobilized on the surface of the quartz resonator 4.

      The contacts 5, each of which is electrically connected to the contact paths of a pair of electrodes on the surfaces of the plate of the quartz resonator 4, are supplied with a control potential difference in the range from 0 to 10 V, in increments of 0.1 V, which leads to shear oscillations of the surface of the quartz resonator, where immobilized agents for biomarker detection associated with bioassay molecules.

      The analyzer performs direct registration for each voltage value of the amplitude of oscillation of the surface of the resonator 4. An increase in voltage leads to an increase in the amplitude of the oscillations and separation of molecules from the surface of the quartz resonator 4, depending on the strength of the bond. The bonds “immobilized receptor - analyzed molecule” break up at a strictly defined value of the applied voltage (the resonant frequency of the quartz resonator 4 is about 14.3 MHz). Thus, by changing the value of stress, one can get rid of nonspecific binding and detect specific interactions.

Claims (1)

A cartridge for highly specific detection of biomarkers on a quartz resonator, comprising a housing in which a cell for introducing a test sample and an analytical cell containing a quartz resonator interconnected via a microfluidic channel system are formed, characterized in that the resonator is a polished quartz AT-slice circular plate forms with a diameter of 0.85 cm, on both sides of which electrodes are located, on the contact-conducting paths of which specialized agents are immobilized s for the detection of biomarkers and on the housing the contact system providing electrical connection with external resonator electrodes sources.

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