RU2786399C1 - Apparatus for continuous multi-parameter monitoring of the physicochemical characteristics of biological suspensions - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to the field of analytical chemistry, namely, to the field of means of determining the state of energy, concentrations of dissolved oxygen, free calcium, membrane potential on the membranes of organelles and cells, and the osmotic volume and other parameters thereof in aqueous suspensions of biological objects, and can be used in various fields of medical and biological research. Apparatus for continuous multi-parameter monitoring of the physicochemical characteristics of biological suspensions is characterised by the fact containing a body, located wherein are a cell with at least six measuring channels made for determining the parameters of the biological suspensions based on the measured optical characteristics, wherein one of the channels is intended for measuring oxygen; a power source; a magnetic mixer located in the cell; a heater for the tested substance and a temperature sensor, located in the cell; an electronic control board; five optical emission sources installed in the measuring channels and five optical emission recorders also installed in the measuring channels, wherein the optical radiation recorders are connected to the inputs of the amplifier and analogue-to-digital converter unit, the output whereof is connected to the input of the recording apparatus, wherein at least the oxygen sensor constitutes an assembly containing at least one Y-shaped fibre cord with a composite core, composed of two physically mixed fibre bundles intended for separating the optical paths of excitation and recording of the optical signal, wherein arranged consecutively against the end of the first fibre bundle of the Y-shaped fibre cord are an excitation emission emitter and a light filter, arranged consecutively against the end of the second fibre bundle of the Y-shaped fibre cord are a light filter and a photodetector, an attachment for placing the test sample is located opposite the common end of the fibre cord, and a power source is connected to all power-consuming elements of the apparatus.

EFFECT: increase in the number of characteristics collected simultaneously from a single sample, reduced test time.

6 cl, 1 tbl

Description

The invention relates to the field of instruments/devices for the simultaneous and continuous measurement of the concentration of dissolved oxygen, calcium ions, membrane potential, redox state of NADH/FAD, and light scattering and other parameters in aqueous solutions and suspensions of biological objects.

Known (RU, patent 2225437, publ. 10.03.2004) is an apparatus containing a temperature-controlled cell, inside which a cuvette is made in the form of a hexagonal prism, equipped with a plug with a hole for introducing samples and reagents, an oxygen consumption sensor and an electronic module for transmitting signals from the sensor to a computer. The temperature-controlled cell is also equipped with sensors that allow additional recording of the membrane potential, calcium ion concentration, and swelling. The sensors have the shape of a truncated cone and are located horizontally in the holes of the cell wall perpendicular to the edges of the hexagonal cuvette.

In the known apparatus, the possibility of multi-parameter monitoring of the concentrations of several ions is difficult when using standard sensors. The mutual influence of standard sensors that generate high currents (oxygen electrode) on the operation of high-resistance potentiometric sensors (H ⁺ , K ⁺ , TPP ⁺ , Ca ²⁺ ), which prevents monitoring of different suspension characteristics in one volume, is known.

Known (RU, patent 198125, publ. 06/19/2020) cell for continuous multi-parameter monitoring of the physicochemical characteristics of biological suspensions, containing a thermostatically controlled working volume with a suspension, a magnet for stirring the suspension, the first channel with an installed sensor for measuring the level of oxygen and channels for monitoring other parameters of the suspension, and in the cell made of a biologically inert material, the second, third, fourth and fifth channels are made, in which optical fiber bundles are installed, with the possibility of delivering excitation light to the suspension, and collecting fluorescence light from the cell to register 5 parameters of the suspension - concentrations of dissolved oxygen, and free ions H ⁺ , K ⁺ , Ca ²⁺ and redox characteristics (NADH, FAD), where the registration of changes in these parameters of a biological object over time (kinetics) is carried out by successive step-by-step switching on of a light source connected to the corresponding fiber at the bundle placed in the second, third, fourth and fifth channels of the cell, and time-synchronized switching on of the device for the appropriate collection of fluorescence light and its transmission to the detector, where the fiber bundles contain evenly distributed fibers for excitation and fibers for collecting fluorescence, which form a hexagonal a fiber distribution configuration within each tow holder configured to mount the holder in the cell channel.

A disadvantage of the known cell is the use of an electrochemical method for measuring oxygen concentration, which requires periodic maintenance, consumes oxygen during the measurement process, and can significantly distort its concentration when operating in a small cell.

The technical problem solved by using the developed device consists in expanding the range of means for performing simultaneous and continuous registration of the optical characteristics of a suspension of microorganisms in an aqueous medium and eliminating the shortcomings of existing measuring instruments.

The technical result achieved in the implementation of the device of the developed design is to increase the accuracy of measurements, as well as to obtain experimental data in biomedical research.

To achieve this technical result, it is proposed to use a device for continuous multi-parameter monitoring of the physico-chemical characteristics of biological suspensions, the developed design. It contains a housing in which a cell with at least six measuring channels is located, which allows, on the basis of optical and temperature characteristics, to determine the parameters of biological suspensions, one of the channels is intended for measuring oxygen, a power source, a magnetic stirrer located in the cell, a heater analyte and a temperature sensor located in the cell, an electronic control board, at least five sources of optical radiation installed in the measurement channels and at least five optical radiation recorders also installed in the measurement channels, with the optical radiation recorders connected to inputs of the amplifier unit and analog-to-digital converters, the outputs of which are connected to the input of the recording device, while at least the oxygen sensor is an assembly containing at least one Y-shaped fiber optic bundle with a composite core, composed of, at least two physically mixed bundles of optical fibers designed to separate the optical paths of excitation and registration of an optical signal, and against the end of the first bundle of fibers of the Y-shaped fiber optic bundle, an excitation emitter and a light filter are sequentially placed, and against the end of the second bundle of fibers of the Y-shaped A light filter and a photodetector are placed in series on the fiber optic bundle, and opposite the common end of the fiber optic bundle there is a device for accommodating a replaceable element with a layer of oxygen-sensitive material applied, and the power source is connected to all power-consuming elements of the device.

The developed device uses well-known measuring tools and approaches to ensure simultaneous and continuous registration of 6 optical characteristics of a cell suspension or isolated mitochondria in an aqueous incubation medium, their storage and analysis. The optical characteristics recorded by the device, in some embodiments, reflect the level and kinetics of changes in the following parameters of the suspension:

1. The state of endogenous NADH, a compound that reflects the energy of the cell

2. Dissolved oxygen concentration

3. The state of endogenous FAD, a compound that reflects the energy of the cell

4. Free calcium concentration

5. Membrane potential value

6. Osmotic volume of biological objects

The developed device consists of:

a) a cell in which the measuring volume is created, which is provided with a lid that provides hermetic isolation of the contents of the measuring volume from the surrounding air, and provided with an opening (s) for introducing reagents, sampling and manipulation of the biological suspension.

b) a housing providing/intended for mounting a power source, an electronic board for controlling independent light fluxes (excitation and fluorescence/phosphorescence) for each of the measuring channels, mechanical mounting elements that provide mounting and mounting of the measuring cell with light guides, mounting of a heater and a mechanical magnetic stirrer.

c) a 220 V mains power supply that provides power to the device's electronic control board, magnetic stirrer and heating elements.

The following are the main principles of operation of the developed device and a brief description of the functions that it has.

Channel #1 (NADH)

Measurement of the level and kinetics (changes in time) of the NADH fluorescence level in solutions and suspensions of biological objects (cells, yeast, mitochondria) from 0 to 100%.

Channel # 2 (Oxygen, O ₂ )

Measurement of the level and kinetics (changes in time) of the phosphorescence level from a sensor sensitive to the concentration of dissolved oxygen in solutions and suspensions of biological objects (cells, yeast, mitochondria) in the range from 0 to 100% saturation.

Channel #3 (FAD)

Measurement of the level and kinetics (changes in time) of the FAD fluorescence level in solutions and suspensions of biological objects (cells, yeast, mitochondria) from 0 to 100%.

Channel # 4 (Calcium, Ca ²⁺ )

Measurement of the level and kinetics (changes in time) of the fluorescence level of a fluorescent dye with Ca ²⁺ -dependent fluorescence (Fluo-5N), to determine the concentration of free Ca ^{2+ ions} in solutions and suspensions of biological objects (cells, yeast, mitochondria) in the range from 0.0 to 1000 μM.

Channel #5 (membrane potential, TMRM, SafraninO)

Measurement of the level and kinetics (changes in time) of the fluorescence level of voltage-dependent fluorescent dyes (TMRM, SafraninO), to determine the membrane potential in suspensions of biological objects (cells, yeast, mitochondria).

Channel #6 (Osmotic volume)

Measurement of the level and kinetics (changes in time) of scattered light intensity (osmotic volume) in suspensions of biological objects (cells, yeast, mitochondria) from 0 to 100%.

The developed device provides a controlled stirring rate of the suspension with a magnetic stirrer in the reactor volume using a rotating external magnet - the stirring speed of the suspension is from 0 to 1500 rpm. The temperature of the suspension of biological objects (cells, yeast, mitochondria) in the volume of the measuring cell is maintained in the range from room temperature to 50°C, with an accuracy of ± 0.5°C over the entire temperature range.

The claimed absolute measurement error of ±1% for all channels (analogues of 0.5%-1%) is sufficient for solving applied problems. The dimensions and weight of the device, combined with the reliability of the mechanical design of the units, make it easy to transport the device. The use in the design of low-power consumers of electrical energy of 100-150 W creates the prospect of developing an autonomous power supply device. The extremely simple design of the device, in which the vast majority of parts are manufactured by standard machining methods, makes the device cheap for mass production.

The device is easy to operate and does not require specific user training, control and registration operations are intuitively transparent in operation and do not require special qualified maintenance. Setting up and calibrating the device is within the power of medium-skilled specialists, and does not require sophisticated equipment. The original use of modern measurement methods made it possible to create a simple, cheap and unpretentious device.

The prototype device for continuous multi-parameter monitoring of the physicochemical characteristics of biological suspensions includes power supply units, radiation (light) source and registration units, temperature control and maintenance units and a magnetic stirrer, signal amplifier units, an ADC and an electronic control board. The power supply provides and maintains the operation of all components of the device. The registered and converted signals are transmitted to a computer with a monitor, where further information processing is carried out.

In table. 1 shows the registration channels used in some implementations and the characteristics of the light interference narrow-band filters used in the device. In other implementations, the measured parameters of several or all channels can be measured, depending on the needs of the user, while the characteristics of the excitation source and the characteristics of the light interference narrow-band filters are selected individually, depending on the indicator(s) used.

Claims (6)

1. A device for continuous multi-parameter monitoring of the physicochemical characteristics of biological suspensions, characterized in that it contains a housing in which a cell with at least six measuring channels is located, which makes it possible to determine the parameters of biological suspensions based on the measured optical characteristics, moreover one of the channels is designed to measure oxygen, a power source, a magnetic stirrer located in the cell, an analyte heater and a temperature sensor located in the cell, an electronic control board, five sources of optical radiation installed in the measuring channels, and five optical radiation recorders, also installed in the measuring channels, and the optical radiation recorders are connected to the inputs of the block of amplifiers and analog-to-digital converters, the output of which is connected to the input of the recording device, while at least the oxygen sensor is th assembly containing at least one Y-shaped fiber bundle with a composite core, composed of two physically mixed bundles of fibers designed to separate the optical paths of excitation and registration of the optical signal, and against the end of the first bundle of fibers of the Y-shaped fiber bundle in series an excitation radiation emitter and a light filter are placed, and a light filter and a photodetector are sequentially placed opposite the end of the second fiber bundle of the Y-shaped fiber bundle, and a device for placing the analyzed sample is located opposite the common end of the fiber bundle, and the power source is connected to all power-consuming elements of the device. 2. The device according to claim. 1, characterized in that it is made with the possibility of adding an oxygen-sensitive (or any other necessary) indicator directly to the analyzed sample placed in the measuring cell. 3. The device according to claim 1, characterized in that the radiation source, the registration sensor and the necessary filters for a single measuring channel are located in a single replaceable unit. 4. The device according to claim. 1, characterized in that some of the measuring channels can be temporarily disabled at the software or physical level. In the latter case, a plug is installed instead of the Y-shaped fiber bundle. 5. The device according to claim 1, characterized in that the order of interrogation of the measuring channels can be changed by the user, including the pairing of radiation sources and/or recording sensors from different measuring channels in order to expand the number of recorded parameters, taking into account the geometric arrangement of the channels in the cell. 6. The device according to claim. 1, characterized in that modulation of the exciting radiation source is used, i.e. the algorithm of operation of the electronic circuit for excitation and processing of the recorded signal is changed.