RU2786374C1 - Apparatus for measuring the concentration of dissolved oxygen in aqueous solutions and suspensions of biological objects using a fibre-optic oxygen sensor - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to apparatus made to continuously determine the concentration of dissolved oxygen in aqueous solutions and biological suspensions. Apparatus for measuring the concentration of dissolved oxygen in aqueous solutions and suspensions of biological objects using a fibre-optic oxygen sensor includes a measuring cell configured for a radially oriented oxygen sensor to be tightly mounted, said sensor constituting an assembly containing at least one Y-shaped fibre-optic cord with a composite core, composed of two physically mixed fibre bundles intended for separating the optical paths of excitation and recording of an 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 a replaceable element with a deposited layer of an oxygen-sensitive material is located opposite the common end of the fibre cord; the apparatus also comprises a sealed cover with at least one central hole made to ensure the drainage of excess volume and maintain a constant volume of the reactor to ensure the input of reagents; a magnetic mixer is mounted into the cell.

EFFECT: prevented diffusion of atmospheric oxygen into the volume of the measured sample, higher accuracy and speed of measuring the concentration of dissolved oxygen in a biological suspension.

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Description

The invention relates to the field of instruments/devices for the continuous determination of the concentration of dissolved oxygen in aqueous solutions and biological suspensions.

Known (SU, copyright certificate 1193561, publ. 23.11.1985) dissolved oxygen sensor. Known sensor contains a housing filled with electrolyte, which houses the anode, cathode and pressure compensator, made in the form of an elastic element movably mounted relative to the sensor housing, fixed in its end part with a union nut. The gas-permeable membrane is fixed on the working surface of the cathode, which is made profiled and with risks on the working surface.

The disadvantages of this device are the complexity of the design of the sensor, containing a large number of elements, the complexity and high complexity of manufacturing and assembling the sensor, low reliability.

It is also known (US patent 7208071, publ. 24.04.2007) a device for the analysis of dissolved oxygen, which contains a cathode and an anode separated from the test medium by an oxygen-permeable membrane and immersed in an electrolyte. The known device provides a low background current when a potential is applied to the cathode by choosing a predetermined ratio of the area and length of the diffusion channel for residual oxygen in the electrolyte at the cathode.

However, the known device is rather laborious and short-lived, since it requires periodic monitoring of the analytical characteristics of the device and periodic replacement of the membrane.

Known (RU, patent 2225437, publ. 10.03.2004) is an apparatus for recording oxygen consumption by mitochondria or cells, including a temperature-controlled cell with a cuvette made inside for placing a test sample in it, equipped with a plug with a hole for introducing samples and reagents, an oxygen consumption sensor and electronic module for transmitting signals from the sensor to the computer. The thermostated cell is equipped with sensors that allow additional recording of the membrane potential, the concentration of calcium ions and swelling, the cell is made in the form of a hexagonal prism, while the sensors have the shape of a truncated cone and are located horizontally in the holes of the cell wall perpendicular to the faces of the cell.

A disadvantage of the known apparatus is the use of electrochemical sensors, in particular a polarographic electrode (Clark type) for measuring oxygen concentration. It requires frequent maintenance, consumes oxygen during the measurement process, is susceptible to electromagnetic interference and can be poisoned by sulfur-containing compounds.

This source of information is accepted as the closest analogue of the developed technical solution.

The technical problem solved by using the developed device consists in expanding the range of devices for measuring the concentration of dissolved oxygen in aqueous solutions and suspensions of biological objects and eliminating the shortcomings of known devices.

The technical result achieved by implementing the developed device consists in preventing the diffusion of oxygen from the atmosphere into the volume of the measured sample, which makes it possible to increase the accuracy and accuracy of the analysis of the concentration and the rate of change in the concentration of dissolved oxygen in a biological suspension, while simultaneously and continuously mechanically mixing the sample, and ensuring that a given temperature, which expands the scope of the oxygen sensor in biomedical research, and also eliminates the consumption of oxygen during the measurement process, facilitates the operation of the device (there is no need for periodic replacement of the electrolyte, the device does not have an oxygen-permeable membrane).

To achieve this technical result, it is proposed to use the developed device for measuring the concentration of dissolved oxygen in aqueous solutions and suspensions of biological objects using a fiber-optic oxygen sensor. The developed device contains a measuring cell made with the possibility of hermetically mounting a radially oriented oxygen sensor, which is an assembly containing at least one Y-shaped fiber optic bundle with a composite core, composed of two physically mixed fiber bundles designed to separate the optical paths of excitation and registration of the optical signal, moreover, against the end of the first bundle of fibers of the Y-shaped fiber optic bundle, an exciting radiation emitter and a light filter are sequentially placed, and against the end of the second bundle of fibers of the Y-shaped fiber optic bundle, a photodetector light filter is sequentially placed, opposite the common end of the fiber optic bundle there is a device for accommodating a replaceable element coated with a layer of oxygen sensitive material, the device also contains a sealed cover with at least one central hole designed to drain excess about the volume and ensuring a constant volume of the reactor to ensure the introduction of reagents, a magnetic stirrer is mounted in the cell.

Typically, as the excitation light source of the fiber optic sensor, an LED is used that emits in the light absorption range of the oxygen-sensitive component in the oxygen-sensitive film/material, and a photodiode is used as the light receiver of the fiber optic sensor, which is sensitive in the radiation region of the oxygen-sensitive component in the oxygen-sensitive sensitive film/material.

In some embodiments of the developed device, it is configured to add an oxygen-sensitive indicator to the analyzed sample placed in the measuring cell.

The design of the developed measuring device is distinguished by the presence in the body of the device:

a) a measuring cell, providing a sealed mounting of the oxygen sensor, and a sealed lid with preferably one central hole for draining excess volume, ensuring a constant volume of the reactor and for introducing reagents; the same lid simultaneously seals the contents of the measuring cell and prevents contact of the surface of the aqueous solution and/or aqueous suspension of biological objects with the atmosphere;

b) the design of the cell provides / sealed attachment of the oxygen sensor, by mounting the common end of the fiber bundle, in a way that allows the oxygen sensor to be exposed to the volume of an aqueous suspension, and prevents the exchange of liquid and / or gases with the surrounding atmosphere;

c) the design of the device contains a built-in magnetic stirrer for mechanical stirring of the reactor content in the measuring cell with a magnetic stirrer through the bottom of the measuring cell.

The device works as follows. The metal complex of a porphyrin (or a derivative thereof, such as octaethylporphyrin) can be used to determine oxygen. In this case, an LED with an emission maximum of 405 nm with a light filter that cuts off the ultraviolet and long-wavelength components of the LED emission spectrum is used as a source of exciting radiation. To register the radiation, you can use a silicon photodiode with a wide absorption spectrum with a broadband light filter that cuts off wavelengths of less than 630 nm in the recorded radiation. The indicator is immobilized in a gas-permeable matrix (film) placed near the common end of the fiber bundle, or directly added to the analyzed solution. To measure the concentration of a substance, an indicator in a film or in a solution is irradiated with exciting radiation and the generated fluorescence/phosphorescence is recorded. The intensity of the recorded signal is recalculated into the concentration of the measured substance using the calibration curve method. Instead of intensity, the lifetime of the excited state of the indicator dye can be used as an analytical signal. At the same time, the technical design of the optical circuit is identical, only the algorithm of the electronic circuit for excitation and processing of the recorded signal changes.

In the design of the proposed fiber-optic sensor, another LED is used as an excitation light source, emitting in the range of light absorption by the oxygen-sensitive component in the composition of the oxygen-sensitive film (coating). As a receiver of phosphorescence light, it is proposed to use a photodiode that is sensitive in the region of radiation of an oxygen-sensitive component in the composition of an oxygen-sensitive film (coating).

The design of the developed device makes it possible to prevent the diffusion of oxygen from the atmosphere into the volume of the measured sample, which makes it possible to increase the accuracy and accuracy of the analysis of the concentration and the rate of change in the concentration of dissolved oxygen in a biological suspension, while simultaneously and continuously mechanically mixing the sample, and maintaining the set temperature, which expands the scope oxygen sensor in biomedical research.

To achieve this technical result, the design of an oxygen sensor has been developed, which is horizontally and hermetically mounted in the body of the measuring cell, with the exit of the oxygen-sensitive end, covered with a film containing the oxygen sensor, into the volume of the measuring cell, providing continuous determination of the concentration of dissolved oxygen in biological aqueous fluids. According to the developed measurement technology, a measured sample (aqueous solution or biological aqueous suspension) is introduced into the measuring cell of the device in which the sensor is mounted and hermetically fixed. For introduction into the test solution, a hermetically fixed lid is used, in which holes for microsyringes are provided, which allow a certain volume of liquid to be introduced and withdrawn from the suspension volume, including making additions of solutions of substrates, toxicants, etc.

The proposed solution has no response to external electrical interference or noise, due to the exclusion of electrochemical reactions from the process of measuring oxygen concentration.

Claims (4)

1. A device for measuring the concentration of dissolved oxygen in aqueous solutions and suspensions of biological objects using a fiber-optic oxygen sensor, characterized in that it contains a measuring cell made with the possibility of hermetically mounting a radially oriented oxygen sensor, which is an assembly containing at least one Y-shaped fiber optic bundle with a composite core, composed of two physically mixed fiber bundles designed to separate the optical paths of excitation and registration of the optical signal, and against the end of the first fiber bundle of the Y-shaped fiber optic bundle, an excitation radiation emitter and a light filter are sequentially placed, and against At the end of the second bundle of fibers of the Y-shaped fiber optic bundle, a light filter photodetector is placed in series, opposite the common end of the fiber optic bundle there is a device for placing a replaceable element with a coated layer The device also contains a sealed lid with at least one central hole designed to drain excess volume and ensure a constant volume of the reactor to ensure the introduction of reagents, a magnetic stirrer is mounted in the cell. 2. The device according to claim 1, characterized in that an LED emitting in the range of light absorption by the oxygen-sensitive component in the composition of the oxygen-sensitive film is used as the excitation light source of the fiber-optic sensor. 3. The device according to claim 1, characterized in that a photodiode is used as a light receiver of the fiber optic sensor, which is sensitive in the radiation region of the oxygen-sensitive component in the composition of the oxygen-sensitive film. 4. The device according to claim. 1, characterized in that it is made with the possibility of adding an oxygen-sensitive indicator directly to the analyzed sample placed in the measuring cell.