SU1092173A1 - Apparatus for studying cells in suspension in microscope - Google Patents

Abstract

1. INSTALLATION FOR RESEARCH-. CELLS IN SUSPENSIZ1 UNDER MICROSCOPE, containing a metering pump for generating alternating pressure, a cell cultivator connected by means of pipelines forming a closed loop with a flow cell of variable thickness and a collection of culture fluid connected to the cell cultivator and a droplet separator equipped with the first bactericidal cyanide cell and a pressure sensor, wherein the culture fluid collection is equipped with a level sensor, and on the culture fluid pipelines before the flow cell, the collection -. NIKOM culture fluid and a cell cultivator are mounted, respectively, the first, second and third pinch valves, characterized in that, in order to ensure reliable operation, it is equipped with a biocontainer for placing the cell cultivator and a precursor element of the sterility violation of the culture fluid, installed before the first bactericidal filter the lower part of the drop catcher and connected to the three pinch I valves and the dosing pump, the gas inlet of the latter connected between the first m bactericidal phytron and pressure sensor, and the output is output to the atmosphere, while the output of the cell cultivator in the gas phase after |:) with the second bactericidal filter is brought inside the biocontainer. asA 2. Installation according to claim 1, characterized in that the element of preventing the disturbance of sterility of the culture fluid is a level sensor fluid,. 00

Description

one

The invention relates to the microbiological industry, namely to the technique of studying biological objects in suspension under a microscope under the conditions of their cultivation.

Device for transporting culture liquid with a constant gap into a flow cell and an automatic preparation device, preparation l, is known.

The first device consists of a fermenter with cells, a flow cell of air filters. The channel driver in this case is an airliff pump, which is a significant drawback of this device, since the gas phase supply to the cell line leads to an additional, not always desirable, gas exchange medium — cell and foaming of the culture mass in the fermenter itself. A long process of operation results in the entry of air bubbles in the chamber of the flow cell. The entry of air bubbles into the volume of the flow cell is undesirable, since, under the action of molecular adhesion forces to the body of the cell, they practically do not leave its working volume, but accumulate there during operation, which leads to large inaccuracies in the measurement.

The second device, consisting of a fermenter, a valve, a flow cell and a receiving vessel, has extremely limited use, since the difference between the levels of the fermenter and the receiving vessel in this case serves as a flow driver, and cannot be used in an automatic cultivation mode, as it is consumable method.

A known device for examining cells in suspension under a microscope, containing a metering pump for generating alternating pressure, a cell cultivator connected through pipelines forming a closed loop, a flow cell of variable thickness and a culture fluid collector connected to the cell cultivator and to a droplet separator equipped The first bactericidal filter and pressure sensor, while the collection of culture liquid is equipped with a level sensor, and on the pipelines of the culture liquid before otochnoy

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A cuvette, a collection of culture fluid and a cell cultivator are mounted, respectively, the first, second and third pinch valves 2.

The disadvantages of this installation include the fact that it has three relatively long pipelines connecting the cell cultivator with the installation elements. Two pipelines connect the cultivator with a fluid to the flow cell, and a third pipeline (gas) connects the receiving vessel to the gas space of the cultivator. The presence of a gas conduit complicates the installation, and the possibility of damage to the conduit increases, since the latter mainly uses an elastic silicone tube. In addition, certain equipment is required to protect the flexible conduit from accidental mechanical damage. The process of sterilization, the joining of the gas pipeline is conditional. At the same time, it was established experimentally that the elastic pipeline (silicone tube) partially passes through its walls gas (such as SOL), which gets into the cultivator, disrupts the gas phase and the temperature inside the cultivator. A change in the concentration of the gas phase and temperature worsens the experiment, since the vital activity of the cultivated cell cultures is disturbed, which is especially evident in the study of highly specialized cells, for example, human and animal cells.

On the gas pipeline set-. A flap is a peristaltic metering pump, which works to create alternating pressure in the pipelines. The part of the pipeline that is laid in the pump all the time is experiencing mechanical loads from the pinch elements of the pump, under the action of which the tube is deformed, microcracks can occur, and, as a result, tube breaks. As a result, non-sterile air enters the tube and contamination of the culture fluid in the piping system can occur, and then in the cultivator.

Another source of infection of the system is the bacterium, a cide ilter in case of a backwash of 31 culture fluids on it. This may be due to the unreliable operation of the pinch valves, or if the cover glass of the cuvette is damaged. Thus, the known installation has insufficient reliability due to the possibility of a violation of the sterility of the culture fluid in the cell cultivator, in various emergency situations. The aim of the invention is to increase the reliability of the plant. The goal is achieved by installing a cell in suspension under a microscope, containing a metering pump to create alternating pressure, a cell cultivator connected through pipelines forming a closed loop, a flow cell of variable thickness and a collection of culture fluid connected to the cell cultivator and drip tray equipped with a first bactericidal filter and pressure transducer, while the collection culture culture is equipped with a level sensor, and on pipelines The first, second and third pinch valves, respectively, are equipped with a biocontainer to accommodate the cell cultivator and a culture liquid prevention element, placed in front of the first bactericidal filter in the lower part of the droplet separator and connected with the cell fluid before the flow cell, the culture fluid collector and the cell cultivator. pinch valves and a dosing pump, with the last gas phase inlet being connected between the first bactericidal filter ou pressure sensor, and the output derived to the outside atmosphere, wherein the cultivator cell yield in a gas phase by the second filter bactericidal Ebed inwardly biocontainer and preventing disorders element sterile culture fluid is a liquid level sensor. The drawing shows the installation block diagram. - The installation contains a metering pump 1 for creating alternating pressure, a cultivator 2 cells connected via pipelines 3, forming a closed loop with a groove 3 4 cell 4 of variable thickness, located under the capacitor 5, the field of view of the microscope objective 6, and a collector 7 the culture fluid connected to the cell cultivator 2 and the droplet separator 8. The droplet separator 8 is equipped with the first bactericidal filter 9 and the pressure sensor IO, and the collection 7 of the culture fluid is equipped with a sensor P level. On pipelines 3 of the culture fluid in front of the flow cell 4, the collection 7 of the culture fluid and the cultivator 2 cells, the first, second and third pinch valves 12-14 are mounted, respectively. The installation is also equipped with a biocontainer. 15, in which a cultivator 2 is placed, and an element 16 preventing disturbance of sterility of the culture fluid with the first bactericidal filter 9 installed in the lower part of the drip catcher 8 and connected to pinch valves 12-14 and the metering pump 1. The input of the metering pump 1 is connected in gas phase by means of a conduit 17 between the first bactericidal filter 9 and the pressure sensor 10, and the output is brought outside to the atmosphere. At the same time, the output of the cultivator 2 cells in the gas phase by means of the second bactericidal filter 18 is introduced inside the biocontainer 15. The collection 7 of culture liquid is a Y-shaped glass vessel with inlet nozzles 19 and 20 and an outlet nozzle 21. Element 1-6 warning violation The sterility of the culture liquid is a liquid level sensor 22 mounted on a droplet separator 8. The installation works as follows. Open the valve 12 and turn on the metering pump 1 in the mode of creating a negative pressure (vacuum) in the collection 7. At the same time, the valves 13 and 14 are closed. As soon as the vacuum in the collector 7 reaches a predetermined value, the pressure sensor 10 triggers and the metering pump 1 stops. The culture fluid through the open valve 12 fills the flow cell 4. After some time, the valve I2 closes and opens the valve 13. $ 10 Due to vacuum. in collector 7, part of the culture fluid from cuvette 4 enters collection 7. At the same time, the vacuum in collection 7 decreases, which is detected by sensor 10, which gives a signal that the dosing pump 1 is turned on for vacuum. Gradual pumping of the culture fluid from cuvette 4 to collector 7 occurs. Under the influence of external atmospheric pressure in cuvette 4, a predetermined gap is achieved, which fixes the gap sensor (not shown). After that, the dosing pump 1 is closed to create pressure , in the collector 7, the valve 14 opens and part of the culture fluid from the collector 7 returns to the cultivator 2. When the level sensor 11 is triggered, the valve 14 is closed and the metering pump 1 is turned off. After a certain time, sufficient for the damping of mechanical vibrations, the system performs an intravital morphometric analysis of cells in the field of the microscope. Thus, a cell monolayer is formed in flow cell 4, suitable for in vivo microscopic analysis. In the study, valves 12 and 13 are closed. This ensures the isolation of the cuvette 4 from all external communications. When the installation is in operation, the pump-dosato 1 pumps and pumps air through the bactericidal filter 9. Cultivator 2 cells with all life support equipment (sensors of physical and chemical parameters, agitators, vessels with culture and nutrient media, peristaltic pumps for feeding nutrient media to the cultivator not shown in the drawing) are mounted in biocontainer 15, and the exit of the cultivator of 2 cells in the gas phase is brought out through the second bactericidal filter 18 inside the biocontainer 15. During the installation work, the gas Mixture from the cultivate oracle 2 through bactericidal filter 18 is pushed inside the biocontainer, .15. Thus, the weight of the biocontainer is filled with a homogeneous Gas mixture having the same temperature and gas composition as in Cultivator 2. In addition, the gas Mixture is sterile, as it comes through a bactericidal filter. Moreover, even if the gas penetrates through silicone tubes and other elements of life support equipment, it will not affect either the percentage of the gas phase, nor the temperature, or sterility inside the cultivator. Consequently, the accuracy of maintaining the gas phase and the temperature inside the cell cultivator is improved, the reliability of the installation is increased. In case of accidental damage to the pipeline located in the metering pump, no contamination of the culture fluid occurs, as the {Gas pump-dispenser pumps out and pumps air through the bactericidal filter 9. In an emergency, the culture fluid enters the lower part of the droplet separator 8, which causes the sensor to trigger Level 2, part of the element 16 to prevent the violation of the sterility of the culture fluid. According to the signal of the element 16, the dosing pump 1 is turned off, and the valves 12-14 are brought to the state of the emergency clamping of the pipeline and the signaling of the emergency state of the installation is turned on. Thus, the transport of the culture fluid from the cultivator to the cultivator is turned off, which prevents the culture liquid from the culture from being disrupted. Element 16 can be made on the basis of a capacitive sensor, an electrical conductivity sensor of a bactericidal filter, a liquid displacement sensor, however, the simplest, most reliable and unified element is a culture liquid level sensor 22 (of the same design as sensor P). After the operator has eliminated possible malfunctions and breakdown element .16 is ready for further operation. The presence in the installation of the element of prevention of the sterility violation of the culture fluid established by the bactericidal. filter, allows the operator to signal the possible contamination of the culture fluid, and the faulty area is automatically disconnected. Thus, non-stop, sterile cell culture growth can occur in the cell cultivator, which is especially important during long cell growth processes. Raises 10921

with reliability and safety of work with the installation.

The introduction of the element of preventing the sterility violation of the culture fluid installed in the lower j part of the droplet separator and connected to the pinch valves and the doser pump significantly increases the reliability, unification of the installation and requires only one photosensor which iq is connected to the well-known valves.

The technical and economic effect of the installation is to reduce by 33%

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the number of pipelines and increasing the reliability of work in case of emergency situations.

Thus, the installation allows for the study of cells under more favorable and reliable conditions, since the experimenter will always be suspected of a possible disruption of the sterility of the transport system, and the elements of the system automatically shut off the faulty section. At the same time, favorable living conditions for the grown cells are maintained.

Claims (2)

1. INSTALLATION FOR RESEARCH CELLS IN SUSPENSION UNDER A MICROSCOPE. containing a metering pump for creating alternating pressure, a cell cultivator connected via pipelines forming a closed loop, a flow cell of variable thickness and a culture fluid collector connected to a cell cultivator and a droplet separator equipped with a first bactericidal filter and a pressure sensor, while the culture collector the fluid is equipped with a level sensor, and on the pipelines of the culture fluid in front of the flow cell, collector, the culture fluid and the cell cultivator with the first, second, and third pinch valves are mounted respectively, characterized in that, in order to increase the reliability of operation, it is equipped with a biocontainer for accommodating the cell cultivator and an element for preventing sterility of the culture fluid installed in front of the first bactericidal filter in the lower part of the droplet eliminator and connected to three pinch valves and a metering pump, and the input of the latter in the gas phase is connected between the first bactericidal filter and the pressure sensor, and the output is output to I’m shooting into the atmosphere, while the output of the cell cultivator in the gas phase through the second bactericidal filter is brought inside the biocontainer. 2. Installation according to π. 1, t l and the fact that the element for preventing violations of the sterility of the culture fluid is a liquid level sensor. I