SU1227181A2 - Device for electrophoresis of blood cells - Google Patents

Description

The invention relates to medicine and medical technology and can be used for the in vivo separation of blood cells and other animal and human tissues into fractions.

The purpose of the invention is to improve the accuracy of the separation of blood cells into fractions.

FIG. 1 shows a diagram of the device; in fig. 2 is a block diagram of a multi-channel dispenser; in fig. 3 and 4 - one of the possible

multi-channel dispenser design; on the dispenser 13.

compressed air control pressure.

The inputs of electropneumatic transducers 15 are connected to the outputs of a pneumatic generator 16. It is fundamentally possible to use instead of the generator 16 and electropneumatic transducers 15 of a pneumatic generator 16, issuing two sequences of pneumatic control pressure signals to the control inputs A and B

FIG. 5 - implementation of the generator.

A device for electrophoresis of blood cells contains a vertical separation chamber 1 and adjacent electrode chambers 2 and 3. To the lower part of the separation

Multichannel dispenser 13 consists of identical channels, the number of which n is equal to the number of separated fractions (Fig. 2). Each of the channels of the dispenser 13 contains in series the first pneumatic control valve 1, which is supplied under an overpressure valve 17, metering volume 18 and

By using the chamber buffer solution from the pressure chamber generator 4. Electrode chambers 2 and 3 connected together are similarly supplied with an electrode buffer from the generator 5 of the pressure of the electrode buffer. The overpressure at the outputs of the pressure generators 4 and 5 can be manually set within certain limits. Generators 4 and 5 are built on the principle of displacing compressed air with liquids from the hermetic20

a second pneumatic valve 19. The inlet of the first valve 17 is the working inlet of the corresponding channel of the dispenser 13 and is connected by a flexible pipe 12 to the cavity of the corresponding vessel 1I for collecting the separated fractions. The outlet of the second pneumatic valve 19 is connected to the atmosphere. The controlled inlets of the second valves 19 of all the channels of the dispenser 13 are interconnected and are the second control vessel. Along the electrode chambers 2 and 25 inlet B of the dispenser 13.

3, passive electrodes, such as platinum (not shown), are fixed to which a constant electric voltage is applied to create a transverse field in the separation chamber 1.

Valves 17 and 19 are control interrupters. If there is no pneumatic signal at control input A, then at the controlled inputs of all the first valves 17 the pressure is equal to atmospheric pressure (zero logical pneumatic signal) and each of these valves 17 connects its input with its output (valve is open). If at the control input A and, therefore, at the controlled inputs of all the first valves 17 there is a pneumatic signal

Valves 17 and 19 are control interrupters. If there is no pneumatic signal at control input A, then at the controlled inputs of all the first valves 17 the pressure is equal to atmospheric pressure (zero logical pneumatic signal) and each of these valves 17 connects its input with its output (valve is open). If at the control input A and, therefore, at the controlled inputs of all the first valves 17 there is a pneumatic signal

In the lower part of the separation chamber 1, a window 6 is located for introducing the cell mixture to be separated into the device.

In the upper part of the separation chamber 1, there is an extraction unit 7 containing

according to the number of fractions withdrawn, the rigid pipes are 35 units, the TG1 7 of which is the exact pressure 7, in contact with the buffer in the section from the valves 17 of the separating chamber 1 and in one row. To the outlets of the rigid pipes 8 equipped with sealing nozzles 9 is attached to the flexible tube 10 connected to the cavity 40

sealed vessels 11 for collecting the separated fractions. The conventionally rigid 8 and flexible 10 tubes, as well as the vessels 11 for collecting the separated fractions, are not all shown in the drawing. The cavities of the vessels 11 are connected by flexible tubes 12 to the working inputs of the multichannel dispenser 13 so that the tubes 12 communicate with the tubes 10 only through the cavities of the respective vessels 11. The number of channels of the dispenser 13 is equal to the number of vessels 11 and the number of hard outlets

There is no connection between its inlet and outlet (the valve is closed).

The same applies to the second valves 19, controlling the logical pneumatic signals from input B.

45

The dosing volumes 18 must be the same in all channels of the dosing unit 13. This will ensure the same buffer consumption in all the separated fractions at the output of the output unit 7.

The dispenser 13 according to FIG. 3 consists of three sections: central 20 and two lateral 21 and 22. Between sections 20-22, flat elastic membranes 23 and 24 are laid.

tubes 8. This number determines the Q surfaces of sections 20-22, facing the maximum number of separated cell membranes 23 and 24, and has cylindrical fractions for which the device is designed. The recesses are 25-28 so that all of them are on Exits 14 of each channel The dispenser 13 moves along one vertical axis and is per- nounced to the atmosphere. Controlling the entrance to her planes. Deepen

Holes A and B of the dispenser 13 are connected to discrete-25, 26 and 27, 28 in pairs facing each other by electropneumatic transducers 15, thirst- 55 gs and are on different sides of which, depending on control, 23 and 24. The number of cylindrical deepening electrical signal at its inputs on each of the surfaces of the sections de gives a high or low output (at - equal to n - the number of separated fractions.

compressed air control pressure.

The inputs of electropneumatic transducers 15 are connected to the outputs of a pneumatic generator 16. It is fundamentally possible to use instead of the generator 16 and electropneumatic transducers 15 of a pneumatic generator 16, issuing two sequences of pneumatic control pressure signals to the control inputs A and B

Multichannel dispenser 13 consists of identical channels, the number of which n is equal to the number of separated fractions (Fig. 2). Each of the channels of the dispenser 13 contains in series the first pneumatic control valve 17, metering volume 18 and

a second pneumatic valve 19. The inlet of the first valve 17 is the working inlet of the corresponding channel of the dispenser 13 and is connected by a flexible pipe 12 to the cavity of the corresponding vessel 1I for collecting the separated fractions. The outlet of the second pneumatic valve 19 is connected to the atmosphere. The control inputs of the second valves 19 of all the channels of the dispenser 13 are interconnected and are the second control input B of the dispenser 13.

Valves 17 and 19 are control interrupters. If there is no pneumatic signal at control input A, then at the controlled inputs of all the first valves 17 the pressure is equal to atmospheric pressure (zero logical pneumatic signal) and each of the indicated valves 17 connects its input to its output (valve is open). If at the control input A and, therefore, at the controlled inputs of all the first valves 17 there is a pneumatic signal

units, TG1 7ekoto7oe, beat the exact pressure d7e - p out of the valves 17

units, TG1 7ekoto7oe, beat the exact pressure d7e - p out of the valves 17

There is no connection between its inlet and outlet (the valve is closed).

The same applies to the second valves 19, controlling the logical pneumatic signals from input B.

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15

Sections 20-22 are joined and fastened with screws 29 and nuts 30.

The cylindrical recesses 25 and 27 are pairwise connected by axial holes in the body of section 20. These holes play the role of metering volumes 18, are made with the same drill on the same machine from the same installation for all channels of the dispenser 13 and are therefore the same with a high degree of accuracy.

The cavities of all the cylindrical recesses 26 are connected by oblique holes in the tete of section 21, and the cavities of the cylindrical recesses 28 are similarly in the body of section 22.

The cavities of the recesses 28 are the controlled inputs of the first pneumatic valves 17, and they are accessed via the control input A through the valve 31.

Similarly, access to the controllable inputs of the second pneumatic valves 19 (cavities of the recesses 26) is provided via the control input B through the nozzle 32.

Adjacent to the entrance to the metering volume 18 from the cylindrical recess 25, there is an opening connected to the working outlet 14 (FIG. 4), and on the side of the recess 27 there is an opening connected to the flexible pipe 12. The outputs 14 communicate with the atmosphere at the side the surfaces of section 20, and the flexible tubes 12 are connected through corresponding fittings on the opposite side surface of section 20 with cavities of vessels 11 for collecting the separated fractions.

The generator 16 consists of a series-connected multivibrator 33 with an adjustable frequency of generation and a counting trigger 34, which is triggered on the rear

20

thirty

generator 4 pressure chamber buffer.

Switch 37 is in the "Preparation. In this case, the second inputs of the elements 35 and 36 are given a logic zero signal and, regardless of the state of their first inputs, there are electrical signals of the logical unit at the outputs A and B. The outputs of the electropneumatic transducers 15 also have signals of a logical unit, but already pneumatic ones (P (). The pressure P {goes to the controlled inputs of valves 17 and 19. The pressure is supplied to the controlled inputs - cavities of the recesses 26 and 28. Elastic membranes 23 and 24 are blown out into the depressions 25 and 27. Both valves 17 and 19 are closed, and the dosing volumes 18 are sealed both from the atmosphere and from the cavities of the vessels 11 to collect the separated fractions.

The chamber buffer generator 4 creates an excessive working pressure of the chamber buffer solution in the lower part of the separation chamber 1. However, the buffer solution in the separation chamber I does not move, because it is balanced by the pressure of compressed air there.

The electrode buffer generator 5 continuously pumps the electrode buffer through the electrode chambers 2 and 3.

The device is ready for the separation of cells into fractions.

The switch 37 is translated B position "Work. The electronic generator 16 begins its work. At the outputs A and B of the generator 16, there are two sequences of pulses of logical zero, shifted in time by half the period. nycTi, in the front of the input pulse, the outputs of which at the start of 35 work, the logical zero signal at the output of the B -generator 16. After working out this signal, the electropneumatic transducer 15 releases pressure at the second B control input of the dispenser 13 to atmospheric.

connected to the first inputs of two logical elements 2I-NOT 35 and 36. The second inputs of elements 35. and 36 are connected via switch 37 to the output of the multivibrator 33, and at their outputs electric logic signals A and B appear that perturbate discrete electropneumatic converters the applicants 15, which convert them into pneumatic logic pressure signals A and B of the same form.

In order to increase the output power required to control the electropneumatic converters 15, power amplifiers (not shown) can be additionally connected between their inputs and outputs of the elements 35 and 36.

Consider the operation of the proposed device for preparative cell electrophoresis.

In the initial position in the separation chamber 1 of the device, as well as in the vessels 11 for collecting the separated fractions, there is an overpressure of compressed air, during which the separation process proceeds. This pressure is pre-set by a separate unit or by

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generator 4 pressure chamber buffer.

Switch 37 is in the "Preparation. In this case, the second inputs of the elements 35 and 36 are given a logic zero signal and, regardless of the state of their first inputs, there are electrical signals of the logical unit at the outputs A and B. The outputs of the electropneumatic transducers 15 also have signals of a logical unit, but already pneumatic ones (P (). The pressure P {goes to the controlled inputs of valves 17 and 19. The pressure is supplied to the controlled inputs - cavities of the recesses 26 and 28. Elastic membranes 23 and 24 are blown out into the depressions 25 and 27. Both valves 17 and 19 are closed, and the dosing volumes 18 are sealed both from the atmosphere and from the cavities of the vessels 11 to collect the separated fractions.

The chamber buffer generator 4 creates an excessive working pressure of the chamber buffer solution in the lower part of the separation chamber 1. However, the buffer solution in the separation chamber I does not move, because it is balanced by the pressure of compressed air there.

The electrode buffer generator 5 continuously pumps the electrode buffer through the electrode chambers 2 and 3.

The device is ready for the separation of cells into fractions.

The switch 37 is translated B position "Work. The electronic generator 16 begins its work. At the outputs A and B of the generator 16, there are two sequences of pulses of logical zero, shifted in time by half the period. nycTi, in the beginning of the work, the logical zero signal on the Vits at the output of the B-generator 16. By working out this signal, the electropneumatic transducer 15 releases the pressure on the second B of the control input of the dispenser 13 to atmospheric.

 23 occupies a neutral position in the contact plane of sections 20 and 21 of the metering unit 13. The dosing volume 18 and the outlet 14 begin to communicate, the second valve 19 opens and the dosing volume 18 is discharged

5 into the atmosphere. At the end of the logical zero pulse at the input B in the metering volume 18, the atmospheric pressure Rathm is established. After that, the second control input B from the generator 16 receives the signal of the logical unit through the electro-pneumatic converter 15, which closes the second valve 19.

A logical zero signal is then applied to the first control input A. This causes, similarly, the opening of the first pneumatic valve 17. At the same time, the dosing volume

55 18 is filled with compressed air from the corresponding vessel 11 through the working inlet 12 to an excessive working pressure in the separation chamber 1 of the device. Signal logs

The ches zero at the first control input A disappears. The valve 17 is closed. The dosing volume 18 again becomes hermetic. Then the process repeats, the contents of the metering volume 18 are re-emitted into the atmosphere, etc.

Since the dosing volumes 18 are the same, in each cycle of operation of the dosing unit 13, the same portions of compressed air are removed from the vessels 11 to the atmosphere through them, which are each time replaced with a chamber buffer with separated cells until the pressure in the vessels 11 and the separation chamber 1 of the device is equal. Thus, the costs of the buffer with cells in all vessels 1 are the same regardless of the hydrodynamic resistance of their supply pipelines.

By adjusting the frequency of the generator 16, it is possible to regulate the speed of movement of the chamber buffer within wide limits. If the dosing volumes of 18 are small enough, and the frequency

Because generator 6 is large enough, this movement is almost the same as continuous.

Some time after the switch 37 is moved to the position of Operation, the separation chamber 1 of the device is completely filled with the chamber buffer. From this point on, the voltage is applied to the electrodes in the electrode chambers 2 and 3, and in window 6 a separable mixture is introduced, which is divided into fractions during electrophoresis. Separated cells enter block 7 of elimination, and from there into vessels 11 to collect separated fractions.

This device allows you to get the same costs in all separated fractions with greater accuracy and stability over time at low flow rates of the chamber buffer solution. This provides high separation accuracy, increases the amount and purity of the separated cell fractions.

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Claims (2)

1. DEVICE FOR ELECTROPHORESIS OF BLOOD CELLS according to ed. St. No. 1069769, characterized in that, in order to improve the accuracy of the separation of blood cells into fractions, it is equipped with a generator with two outputs, two electro-pneumatic converters and a multi-channel dispenser with a number of separated fractions, having a working inlet for each channel connected to the cavity of the corresponding collection vessel divided fractions, and an output connected to the atmosphere, as well as two control inputs common to all channels, connected to the outputs of two electro-pneumatic converters, respectively, the input of each of which is connected with one of the two outputs of the generator, and the vessels for collecting the separated fractions are sealed. 2. The device according to π. 1, characterized in that each dispenser channel contains a first pneumatically controlled valve, a metering volume and a second pneumatically controlled valve, the input of the first pneumatic valve being the working input of the corresponding dispenser channel, the output of the second pneumatic valve connected to the atmosphere, and the controlled input of each valve connected to appropriate control input of the dispenser. Fig. 1> to