RU2764701C1 - Flow-through unit of a device for diagnosing disorders of cellular hemostasis - Google Patents

Abstract

FIELD: medical technology.SUBSTANCE: invention relates to medical technology and can be used in devices for the diagnosis of cellular hemostasis. The flow-through unit contains a reservoir for a liquid, a valve, a flow-through chamber and a circulation pump connected by tubes to form a circulation loop. Additionally, the flow-through unit contains a flushing system connected to the circulation loop. The flushing system includes a detergent reservoir and a distilled water reservoir, a flushing liquid valve, an air/liquid valve, and a peristaltic flush pump. The fluid reservoir is removable and is located between the flow chamber and the peristaltic pump of the circulation circuit.EFFECT: improving the accuracy and reliability of the results.1 cl, 1 dwg

Description

The invention relates to medicine and can be used in devices for medical diagnostics, in particular in devices for diagnosing cellular hemostasis.

Known laser optical test system for recording the kinetics of platelet adhesion, containing a flow block with an optical substrate, a laser source, two photo detectors, a peristaltic pump and a computer. The peristaltic pump is connected to the flow block and controlled by a computer. Platelet-rich plasma was pumped through the flow block. The flow block of the test system consists of a reservoir into which a sample of platelet-rich plasma is introduced with a micropipette, a peristaltic pump and a flow chamber. Under the action of a peristaltic pump, the plasma circulates through the tube through a flow chamber with an adhesive protein coating into a reservoir, from which it re-enters the tube, ensuring continuous circulation.

(Avtaeva Yu.N., Melnikov I.S., Gabbasov Z.A. Real-time registration of platelet adhesion on a fibrinogen coating immobilized on an optical substrate under flow conditions. - Cellular technologies in biology and medicine, 2018, No. 1, p. 48-52).

The disadvantage of the test system is that there is a “dead zone” in the sample circulation circuit that is not washed when cleaning the device, which leads to mixing of new blood samples in the non-washable “dead zone” with old blood samples, making the results unreliable.

A known device for recording the kinetics of platelet adhesion, containing a flow unit, an optical unit and an electronic computing unit located in the housing. At the same time, the flow block includes a reservoir for biological fluid, a valve, a flow chamber and a circulation pump connected by tubes to form a circulation circuit, while the flow chamber is installed in the optical block on a prism in such a way that the optical surface of the prism, which has the ability for platelet adhesion, forms the wall of the flow chamber, and the electronic computing unit is connected to the circulation pump with the ability to control the flow of biological fluid. The flow block ensures the selection and circulation of a sample of biological fluid in the system (creates conditions for a constant flow controlled by the speed).

(Patent of the Russian Federation No. 2725863, IPC G16H 50/00, published on 07/06/2020, Bull. No. 19)

It is also a design flaw that there is a "dead zone" in the sample circuit that is not flushed when the device is cleaned, and this will cause new blood samples in the non-flushed "dead zone" to mix with old blood samples, making the results obtained unreliable. There is a dead space in any microfluidic valve (usually 10-30 µl). Since the microfluidic device uses small volumes of biological fluid for research (about 300 µl), even a few µl of biological or flushing fluid left over from a previous study and entering the circulating fluid during a new study can affect the results.

The objective of the invention is to create a flow unit of a device for diagnosing disorders of cellular hemostasis, which makes it possible to achieve complete purification of the system from biological and flushing fluids, which affects the most reliable results.

The technical result of the invention is to improve the accuracy and reliability of the results.

This is achieved by the fact that in the inventive flow block of the device for diagnosing disorders of cellular hemostasis, including a reservoir for liquid, a valve, a flow chamber and a circulation pump connected by tubes to form a circulation circuit, according to the invention, it additionally contains a flushing system connected to the circulation circuit, including a reservoir detergent and distilled water reservoir, flush valve, air/liquid valve and peristaltic flush pump, in addition, the fluid reservoir is removable and is located between the flow chamber and the peristaltic pump of the circulation circuit.

The inventive flow block of the device for diagnosing disorders of cellular hemostasis is shown in Fig. 1, where 1 - detergent tank, 2 - distilled water tank, 3 - flushing fluid supply valve, 4 - air/liquid supply valve, 5 - peristaltic flushing pump, 6 - flow chamber, 7 - fluid reservoir, 8 - peristaltic circulation pump.

Studies of biological fluids (whole blood and blood plasma) are carried out in the circulation circuit represented by the flow chamber 6, the reservoir 7 for the liquid, the peristaltic pump 8 of the circulation circuit.

Detergent tank 1, distilled water tank 2, washing liquid supply valve 3, air/liquid supply valve 4, peristaltic washing pump 5 belong to the washing system.

Reservoir 1 with washing liquid contains a detergent with surfactants that provide effective cleaning of the channels of the tubes of the device from proteins and cells remaining after the circulation of biological fluids (blood, blood plasma). Detergent with a long stay in the channels of the tubes can form deposits that violate the geometry of the channels. Also, the detergent will interact with the studied blood and plasma samples, disrupting the function and integrity of cellular elements and proteins.

Distilled water from tank 2 is used to remove detergent from the tube channels.

Tanks 1 and 2 are connected by tubes to valve 3 for supplying flushing fluid.

Switching the supply of detergent from tank 1 or distilled water from tank 2 is controlled by valve 3, depending on what liquid is currently planned to flush the system.

The flushing liquid supply valve 3 is connected by a tube to the air/liquid supply valve 4.

Valve 4 regulates (switches) the flow of flushing liquids from tanks 1 or 2 or atmospheric air. Air is used to eliminate (blow out) distilled water from the tube channels.

Valve 4 is connected by a tube to a peristaltic pump 5, which ensures the flow of washing liquids or air into the flow chamber 6.

The flow chamber 6 is connected by a tube to the Reservoir 7. In the reservoir 7, biological fluid accumulates during research, and flushing liquids during rinsing. The reservoir 7 is removable.

The reservoir 7 is connected by a tube to the peristaltic pump of the circulation circuit 8.

The peristaltic pump 8 of the circulation circuit is used during the study to pump biological fluids through a closed circulation circuit represented by a flow chamber 6, a reservoir 7 and a peristaltic pump 8. During flushing of the system, the peristaltic pump 8 facilitates the pumping of flushing fluids or air through the circulation circuit.

The flow block of the device for diagnosing disorders of cellular hemotasis is used as follows.

A reservoir 7 with a biological fluid is installed and a study is carried out, in which the biological fluid (whole blood or blood plasma) circulates along the circulation circuit (from the reservoir 7, through the peristaltic pump 8 into the flow chamber 6). Upon completion of the study, the reservoir 7 with the biological fluid is removed and replaced with an empty reservoir 7. To prepare the device for diagnosing cellular hemostasis disorders for the next study, it is necessary to remove the remains of the biological fluid from the system from the previous study. To do this, activate the flushing system. The peristaltic flushing pump 5 ensures the supply of detergent from the tank 1 through valves 3 and 4 to the circulation circuit, where the detergent enters the flow chamber 6. The peristaltic pump 8 of the circulation circuit is activated, pumping the detergent supplied by the peristaltic pump 5 along the circulation circuit. The spent detergent accumulates in the tank 7, after which the tank 7 is removed. After performing this flushing procedure, the system is cleared of biological fluid. However, it retains detergent residues, which will inevitably interact with proteins and cells of the biological fluid in a new study, affecting the quality of the test results. Therefore, the second cleaning step is to remove detergent residues.

To do this, the tank 7 is replaced with a clean one. The valve 3 switches, opening the channel from the tank 2 with distilled water, while blocking the channel from the tank 1 with detergent. Under the action of the peristaltic pump 5, distilled water from the tank 2 enters through the valves 3 and 4 into the flow chamber 6 and circulates through the circulation circuit under the action of the peristaltic pump 8 of the circulation circuit. Distilled water washes out the remaining detergent, accumulating in the tank 7, after which the tank 7 is removed. After performing this flushing procedure, the system is cleared of body fluid and detergent. However, the distilled water remaining in the system will interact with the proteins and cells of the biological fluid in a new study, also affecting the quality of the test results.

Therefore, the system is cleaned with air. Tank 7 is replaced. Valve 3 closes the channel from tanks 1 and 2. Valve 4 opens the access of atmospheric air to the system. Under the action of the peristaltic pump 5, atmospheric air is sucked into the tubes and injected into the flow chamber 6, and under the action of the peristaltic pump 8 it is injected into the circulation circuit. Atmospheric air squeezes out the remaining distilled water from the tube channels. Thus, complete purification of the system from biological and flushing liquids is achieved.

Examples of using.

1. To perform the study, a biological fluid (whole blood or blood plasma) is placed in reservoir 7. The peristaltic pump 8 of the circulation circuit is activated, under the influence of which the biological fluid circulates along the circulation circuit (flow chamber 6, reservoir 7, peristaltic pump 8 of the circulation circuit). At the same time, the peristaltic flushing pump 5 remains inactive, blocking the tube of the flushing unit and preventing the flow of biological fluid into it. During the circulation of the biological fluid in the circulation circuit, platelet adhesion is recorded on the optical substrate of the flow chamber 6. After the completion of the study, the biological fluid partially remains in the tubes of the circulation circuit, partially in the reservoir 7. After the completion of the study, the reservoir 7 with the biological fluid is removed and replaced with a new one. To remove biological fluid from the circulation tubes, it is necessary to flush the circulation circuit.

2. After performing the study, in which the biological fluid circulated through the circulation circuit, the reservoir 7 containing the biological fluid is removed and replaced with an empty reservoir 7. Next, it is necessary to remove the remaining biological fluid from the system. To do this, the Peristaltic flushing pump 5 is activated, which ensures the supply of detergent from reservoir 1 through valves 3 and 4 to the circulation circuit. The peristaltic pump 8 of the circulation circuit is activated, pumping the detergent supplied by the peristaltic pump 5 through the circulation circuit. The detergent is accumulated in the tank 7, after which the tank 7 is removed. After performing this flushing procedure, the system is cleared of biological fluid. Tank 7 is replaced. Valve 3 switches, opening the channel from the tank 2 with distilled water and closing the channel from the tank 1 with detergent. Under the action of the peristaltic pump 5, distilled water from the reservoir 2 enters through the valves 3 and 4 into the flow chamber 6 and circulates through the circulation circuit under the action of the peristaltic pump 8. Distilled water washes out the remaining detergent, accumulating in tank 7. Tank 7 is removed. After performing this flushing procedure, the system is cleared of body fluid and detergent.

Tank 7 is replaced. Valve 4 closes the channel from tanks 1 and 2, which goes through valve 3, and opens the access of atmospheric air to the system. Under the action of the Peristaltic pump 5 atmospheric air is sucked into the tubes and injected into the flow chamber 6 and under the action of the peristaltic pump 8 is injected into the circulation circuit. Atmospheric air squeezes out the remaining distilled water from the tube channels. The system is completely cleared and ready for the next study.

Thus, the inventive flow block of the device for diagnosing disorders of cellular hemostasis makes it possible to achieve complete purification of the system from biological and flushing fluids, which has a positive effect on obtaining the most reliable results.

Claims (1)

The flow block of the device for diagnosing disorders of cellular hemostasis, including a reservoir for liquid, a valve, a flow chamber and a circulation pump connected by tubes to form a circulation circuit, characterized in that it additionally contains a flushing system associated with the circulation circuit, including a reservoir with detergent and a reservoir with distilled water. water, flush valve, air/liquid valve and peristaltic flush pump, in addition, the fluid reservoir is removable and is located between the flow chamber and the peristaltic pump of the circulation circuit.

Images