RU167544U1 - ELECTROCHEMICAL SENSOR FOR DOPAMINE DETERMINATION - Google Patents

Abstract

Usage: to determine easily oxidized compounds, such as dopamine, in drugs and blood plasma. The essence of the utility model is that the sensor is a glassy carbon electrode in a Teflon housing, the working area of which is covered with a layer of electropolymerized Bismarck brown Y, including pillararene. Technical result: providing the possibility of simplifying the design of the sensor, reducing the detection limit, increasing the range of detectable concentrations, increasing the reproducibility of measuring the sensor signal. 2 ill.

Description

The claimed technical solution relates to the field of analytical chemistry and pharmacology and can be used to determine easily oxidized compounds, such as dopamine, in drugs and blood plasma. The determination of dopamine is necessary for medicine, biochemistry, pharmacology, in the production of drugs and their quality control.

A device is known (patent CN 104483364 A) for determining dopamine based on a carbon paste electrode. The device consists of a lead current collector, a polytetrafluoroethylene tube or a quartz glass tube with an inner diameter of 3 mm filled with carbon paste. Carbon paste is formed by uniformly grinding and mixing graphite powder, paraffin wax and graphene / dodecyl sulfate composite material. The disadvantages of this device include the high cost of the components of the device (composite material), the duration and complexity of manufacturing due to the large number of components, the low reproducibility of the signal due to the difficulty of ensuring the uniformity of the paste formed by grinding and mixing a large number of solid components.

A device is known (Elhag S., Ibupoto ZH, Nur O., Willander M. Incorporating β-Cyclodextrin with ZnO nanorods: A potentiometric strategy for selectivity and detection of dopamine // Sensors, 2014. - V. 14. - No. 1. - P. 1654-1664.) For determining the concentration of dopamine in a potentiometric mode based on zinc oxide nanorods. Zinc oxide nanorods are grown on a glass substrate coated with a gold layer by low-temperature chemical growth from an aqueous solution. On the surface of the nanorods, a polymer membrane is immobilized, including polyvinyl chloride as a film former, beta-cyclodextrin and potassium tetrakis- (4-chlorophenyl) borate.

The device allows the determination of dopamine in a 10 ^-2 M acetate buffer solution at pH 5.45 in the concentration range from 1 × 10 ^-6 to 1 × 10 ^-1 M. The disadvantages of the sensor include the presence of a difficult to manufacture and expensive crystalline base, difficult to manufacture polymer membrane, low detection limit, the complex design of the sensor, the complexity of its manufacture.

In addition, the disadvantages of all solid-contact electrodes with polymer membranes include the difficulty of achieving a uniform membrane thickness made of a large number of components, and the uneven distribution of components in it. The manufacturing procedure of the device is long and multi-stage, which leads to a decrease in the reproducibility of analytical and operational characteristics and the sensor signal.

The closest analogue selected as a prototype for the most matching features and the technical result achieved is a solid-state ion-selective electrode for determining dopamine (Yin, T., Qin, W. Potentiometric determination of dopamine using a solid-contact polymeric membrane ion-selective electrode // Sensor Letters, 2013. - V. 11. - No. 3. - P. 607-612.).

As a solid contact device is used hydrophobic poly (3-octylthiophene). The ion-selective polymer membrane includes polyvinyl chloride as a film former, heptakis (2, 3, 6-tri-o-methyl) -beta-cyclodextrin as an ionophore and sodium tetrakis [3,5-bis (trifluoromethyl) phenyl] borate as an ionic additive. The device is used to detect dopamine in a solution of 2 mM acetate buffer (pH 4.4) in the concentration range from 3.0 × 10 ^-5 h ÷ 1.0 × 10 ^-3 M.

The device allows the determination of dopamine with a detection limit of 1.3 × 10 ^-5 M. The device can be used for direct potentiometric determination of dopamine in aqueous solutions of pharmaceutical preparations.

The disadvantages of the sensor include:

- the presence of complex in the manufacture of a polymer membrane;

- insufficiently low detection limit;

- a narrow range of detectable concentrations;

- complex sensor design, including a large number of components;

-the complexity of its manufacture.

In addition, the main disadvantage of all solid-contact film electrodes with polymer membranes is the difficulty in achieving a uniform thickness of the membrane made from a large number of components, and the uneven distribution of components in it. The manufacturing procedure of the surface layer is multistage, which leads to a decrease in the reproducibility of the characteristics of the membrane and the sensor signal when replacing the polymer layer.

The technical task of creating this utility model is to eliminate the disadvantages of the prototype, namely:

- simplification of the design of the sensor;

- reduction in the cost of the sensor;

- reduction of the detection limit;

- an increase in the range of detectable concentrations;

- increase the reproducibility of measuring the sensor signal.

The claimed technical solution eliminates the disadvantages inherent in the closest analogue, and ensures the implementation of the task.

The technical result consists in simplifying the design of the sensor (due to the presence of an electropolymerized membrane made in one stage and comprising a small number (two) components), providing a wide range of detectable concentrations and reducing the detection limit (due to the use of a preorganized ionophore macrocyclic receptor - pillararena - as part of the electro-polymerized film of Bismarck's brown diazo dye, brown Y), in reducing the cost of the sensor due to the use of the use of a small number of inexpensive components and a potentiometric method for detecting the sensor signal (does not require expensive equipment), and the sensitivity of the potentiometric measurement of the analytical signal is ensured by the presence of the Bismarck brown supramolecular complex with pillararen, which also has the properties of an electron transfer mediator, in increasing the reproducibility of the sensor signal due to the uniform thickness membranes made in one stage from a small amount of co nents (Bismarck brown Y and pillararen), and due to uniform distribution of the components in the membrane due to the one-step process Bismarck brown electropolymerization of a solution containing pillararen forming supramolecular complex with Bismarck brown.

The technical problem is solved due to the presence on the surface of the glassy carbon electrode of a layer of electropolymerized Bismarck brown containing ionophore - pillararen, which facilitates the transfer of electrons in the composition of the surface layer, and due to the presence on the sensor surface of an electropolymerized film in the absence of additional components that can lead to thickening and heterogeneity membranes. The resulting membrane, consisting only of Bismarck brown Y with pillararene included in it, has a simple structure, low cost, short manufacturing time due to the absence of a film former, a uniform composition and the same thickness over the entire surface due to the small number of components and one-stage manufacturing in electropolymerization process. The fundamental difference between the claimed technical solution is the presence of a layer of electrolymerized Bismarck brown, including pilarara, which provides electron-ion conductivity and recognition of the analyte (dopamine), increases the reversibility of electronic exchange, which leads to an increase in the reproducibility of the sensor signal and its magnitude. In addition, the supramolecular complex of pillararene with Bismarck brown is formed during electropolymerization; therefore, the pillararen is not on the surface of the conducting film on the surface of the sensor, but in its volume, as a part of a nanostructured supramolecular complex, which, due to multiple interactions of charged groups, is highly sensitive to the interaction of the ionophore with dopamine.

Thus, the electropolymerized membrane, consisting of a supramolecular complex, including the electropolymerized Bismarck brown and pillararen, has fundamentally new properties for binding and recognition of analytes, and the reproducibility of the sensor signal, the expansion of the range of detected concentrations and the reduction in the detection limit of dopamine are achieved due to the fact that pillararen interacting with dopamine and simultaneously being a mediator of electron transfer, is a part of nanostructure vannogo supramolecular complex formed due to multiple interaction of charged groups.

A solid-state potentiometric sensor for determining dopamine in an aqueous solution, characterized in that the sensor is a glassy carbon electrode in a Teflon housing, the working area of which is covered with a layer of electropolymerized Bismarck brown Y, including pillararene.

This embodiment of the electrochemical sensor provides the opportunity to implement the claimed technical results:

- simplicity of sensor design;

- a wide range of detectable concentrations;

- low detection limit;

- low cost of the sensor due to the use of a potentiometric method for detecting the sensor signal and due to the use of cheap and affordable reagents in the membrane;

- high reproducibility of the sensor signal due to the uniform thickness of the membrane and due to the uniform distribution of components in the membrane, manufactured in one stage from a small number of components.

The presence of an electropolymerized film containing pillararen as an ionophore and an electron transfer mediator provides high dopamine detection sensitivity, a wide range of detectable concentrations and a low dopamine detection limit, signal reproducibility, uniformity and stability of the coating, the characteristics of which are determined by the parameters of electropolymerization and are easily adjusted at the polymer preparation stage .

The claimed technical solution is illustrated by the materials presented in FIG. 1 and FIG. 2

The design of the solid-state potentiometric sensor is shown in FIG. 1. The potentiometric sensor consists of a glassy carbon electrode in a Teflon housing, as well as a polymer nanostructured film of electropolymerized Bismarck brown Y, including pillararen (Fig. 2). The polymer film was made by electrodeposition from a solution containing 0.015-0.05 M phosphate buffer solution, 20-50% acetone, 0.001 M Bismarck brown Y and 5 × 10 ^-4 -2 × 10 ^-3 M pillararen, on a glassy carbon electrode in the potentiodynamic mode in the potential range is -1.0 ÷ 1.0 V, at a potential scanning speed of 80-100 mV / s, 8-10 cycles of potential scanning. After electrolysis, the electrode was rinsed with distilled water, followed by drying in air at room temperature. The characteristics of the electrochemical sensor were determined in a dopamine solution in a concentration range of 5 μM-0.1 M. A dopamine solution was prepared by dissolving an exact weight in distilled water.

The claimed device is used to determine dopamine. The device operates as follows.

A potentiometric sensor and a silver chloride reference electrode are immersed in an electrochemical cell containing 10 ml of 0.05 M phosphate buffer or 0.04 M universal buffer solution. The EMF value is recorded. An aliquot (10-100 μl) of dopamine solution is added to the cell and the cell EMF value is recorded after a constant value is established. An analytical signal is the magnitude of the emf of the cell. The calibration dependence is built in the coordinates “EMF, mV - negative logarithm of dopamine concentration”. The signal reproducibility is 2.0–0.5%. The device allows the determination of dopamine with a detection limit of 0.5 μm.

Thus, in comparison with the prototype of the claimed technical solution has the following advantages:

1) a wide range of detectable concentrations;

2) low detection limit of dopamine;

3) a simple sensor device;

4) low cost of the sensor,%;

5) high reproducibility of the signal,

6) high sensitivity for determining the concentration of analyte,

7) more reliable operation of the device due to the presence in its composition of a homogeneous electropolymerized coating, including the supramolecular complex of Bismarck brown and pilararane.

Claims (1)

A solid-state potentiometric sensor for determining dopamine in an aqueous solution, characterized in that the sensor is a glassy carbon electrode in a Teflon housing, the working area of which is covered with a layer of electropolymerized Bismarck brown Y, including pillararene.

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