RU133942U1 - BIOSENSOR CARTRIDGE FOR GLUCOSE ANALYZER WITH THERMAL COMPENSATION - Google Patents

Abstract

1. A biosensor cartridge for a glucose analyzer, comprising an enzyme cell and a temperature sensor located in a cartridge configured to couple the enzyme cell and a temperature sensor with a glucose analyzer through the interface elements of the cartridge, characterized in that the cartridge contains a heat-conducting element through which the thermal sensor is mechanically coupled to enzymatic cell. 2. The biosensor cartridge according to claim 1, characterized in that the heat-conducting element is a ceramic plate, on one side of which there is an enzymatic cell, and on the opposite side there is a thermal sensor. The biosensor cartridge according to claim 1, characterized in that it comprises a storage device electrically connected to the interface elements of the cartridge.

Description

The utility model relates to the field of measurement technology, namely, devices for measuring the level of glucose, as well as lactate in the blood. This useful model can find application in medicine and biological research.

Currently, glucose analyzers with chemical biosensors having enzyme electrodes and amperometric type electrochemical converters are widely used. It is known (Nikolsky B.P. Ion-selective electrodes. L .: Chemistry. 1980, p.131-132) that one of the main characteristics of enzyme electrodes is their stability, that is, the ability to maintain the catalytic activity of the immobilized enzyme in time, depending on including from a factor such as temperature. In this regard, glucose analyzers with enzyme electrodes require thermal compensation to achieve high measurement accuracy.

It is known that the glucose analyzer "SUPER GL ambulance" manufactured by Dr. Müller Gerätebau GmbH contains a temperature sensor (operating instructions, version 4.04, 2010. p.41). however, this sensor is placed outside the biosensor cartridge, which negatively affects the accuracy of the measurements.

A biosensor cartridge for a glucose analyzer is known from patent document RU 2455925 C2, comprising a measuring cell with an enzyme as a bioselective element and an electrochemical transducer located in a biosensor cartridge configured to couple the electrochemical transducer to the glucose analyzer through the interface contacts of the biosensor cartridge. However, this biosensor cartridge also does not contain a temperature sensor, which does not allow to achieve high accuracy of glucose measurements.

The closest analogue of this utility model is a biosensor cartridge for a glucose analyzer according to patent document RU 2470300 C2. The known biosensor cartridge for a glucose analyzer contains an enzymatic cell and a temperature sensor located in the cartridge. In this case, the cartridge is configured to connect the enzyme cell and the temperature sensor with the glucose analyzer through the interface elements of the cartridge. However, in the known cartridge there are no technical means to ensure good thermal bonding of the enzyme cell and the temperature sensor, which may lead to a decrease in the accuracy of glucose measurements, because with this design of the cartridge, the temperature measured by the temperature sensor will differ from the temperature of the enzyme cell. The known device also lacks a storage device for storing calibration data and reference information, for example, characterizing the equations of dependence between the concentrations of the test substance and the output signals. This storage device is known from patent document RU 2455925 C2, however, it is not included in the biosensor cartridge, which does not allow you to take advantage of all the possibilities of the known technical solutions in terms of thermal compensation of measurements.

The objective of this technical solution is to increase the accuracy of measurements.

The technical result provided by the utility model is to enhance the thermal compensation of the measuring channel of the biosensor cartridge.

The technical result is achieved due to the fact that in the biosensor cartridge for a glucose analyzer containing an enzyme cell and a temperature sensor, arranged in a cartridge configured to couple the enzyme cell and a temperature sensor with a glucose analyzer through the cartridge interface elements, the cartridge contains a heat-conducting element through which the temperature sensor is mechanically bound to the enzymatic cell.

In the particular case of the implementation of the biosensor cartridge, the heat-conducting element is a ceramic plate, on one side of which there is an enzymatic cell, and on the opposite side of it there is a thermal sensor.

In another particular case, the biosensor cartridge contains a storage device electrically connected to the interface elements of the cartridge.

A useful model is illustrated in figures 1-3, which schematically shows, respectively, a view of the biosensor cartridge from above, its side view in section and a view from below.

In the cartridge 1, which serves as the housing of the biosensor cartridge, there is an enzymatic cell 2 and a temperature sensor 3. The enzymatic cell contains the enzyme as a bioselective element and an electrochemical transducer, for example, of the amperometric type.

To connect the electrochemical converter of the enzymatic cell 2 and the temperature sensor 3 with the corresponding electrical inputs / outputs of the glucose analyzer, contact plates 4 of the cartridge 1 are designed. The bioselective element of the enzyme cell 2 is connected to the hydraulic system of the glucose analyzer through the input / output channels 5 of the cartridge 1. Contact plates 4 and channels 5 represent a special case of the implementation of the interface elements of the cartridge 1 for communication of the enzyme cell 2 and the temperature sensor 3 with the glucose analyzer s.

The cartridge 1 also contains a thermally conductive element, to which the enzyme cell 2 and the temperature sensor 3 are attached so that the thermal resistance between them is as low as possible. The heat-conducting element is preferably a ceramic plate 6, acting as a carrier base of the cartridge. In this case, the enzymatic cell 2 is located on one side of the plate 6, and the temperature sensor 3 is located on the other side of the specified plate.

On one side of the plate 6 with the temperature sensor 3 is preferably located rewritable memory 7 electrically connected to the temperature sensor 3. Protruding above the surface of the plate 6, the temperature sensor 3 and the memory device 7, it is advisable to protect the back plate 8, which made the technological holes 9 for assembling the cartridge 1 and the guide holes 10, corresponding to the guide protrusions in the socket of the glucose analyzer, designed to facilitate the installation of the biosensor cartridge in the working position.

When the device is operating, the biosensor cartridge must be inserted into the socket of the glucose analyzer to connect their hydraulic and electrical systems.

The glucose analyzer pumps the working fluids through the enzymatic cell 2, thereby exerting an electric effect on it for the electrochemical reaction and receiving a measuring signal from the electrochemical converter corresponding to the concentration of glucose or lactate in the blood. At the same time, the glucose analyzer receives temperature data in the measurement area from the temperature sensor 3. When processing the measurement information received from the electrochemical converter, the glucose analyzer makes a correction depending on the readings of the temperature sensor 3. The closer the readings of the temperature sensor 3 are to the actual temperature of the enzyme cell 2, the more accurate the correction of measurement results.

Due to the fact that the temperature sensor 3 is mechanically connected to the enzymatic cell 2 through a heat-conducting element (ceramic plate 6, which has good thermal conductivity, for example, based on beryllium oxide BeO, aluminum nitride AlN, boron nitride BN or other suitable materials), the temperature sensor 3 receives accurate information about the temperature of the enzymatic cell 2, which allows processing the data to enhance the temperature compensation of the measuring channel of the biosensor cartridge, and therefore to improve the accuracy of measurements.

In the case of the location of the ceramic plate 6 between the enzymatic cell 2 and the temperature sensor 3. the distance between them is the smallest, which ensures the minimum possible heat loss on the way from the enzymatic cell 2 to the temperature sensor 3 and a high degree of thermal compensation of the measuring channel of the biosensor cartridge.

In order to achieve the maximum possible degree of thermal compensation of the measuring channel of the biosensor cartridge when processing the measurement information received from the electrochemical transducer, it is necessary to individually or in aggregate take into account the specific biosensor cartridge: a) its calibration data; b) reference information, for example, characterizing the equations of dependence between the concentrations of glucose and / or lactate and the output signals of a particular electrochemical converter; c) the results of earlier temperature measurements carried out with its help, on the basis of which it is possible to compensate for irreversible changes in the operation of the electrochemical converter that occurred as a result of long-term operation of the device. To record the temperature measurement results and read the recorded information from it, the storage device 7 is electrically connected to the glucose analyzer through the interface elements of the cartridge 1. During the measurement, the glucose analyzer reads the corresponding data from the storage device 7 of the cartridge 1 and takes them into account when calculating the values of the glucose or lactate level in the blood, which gives high accuracy of measurements due to the implementation of good thermal compensation of the measuring channel of the biosensor cartridge.

Claims (3)

1. A biosensor cartridge for a glucose analyzer, comprising an enzyme cell and a temperature sensor located in a cartridge configured to couple the enzyme cell and a temperature sensor with a glucose analyzer through the interface elements of the cartridge, characterized in that the cartridge contains a heat-conducting element through which the thermal sensor is mechanically connected to enzymatic cell. 2. The biosensor cartridge according to claim 1, characterized in that the heat-conducting element is a ceramic plate, on one side of which there is an enzymatic cell, and on the opposite side there is a thermal sensor. 3. The biosensor cartridge according to claim 1, characterized in that it contains a storage device electrically connected to the interface elements of the cartridge.

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