JP2005147990A - Method for measuring substrate concentration - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring method in order to reduce measurement errors due to Hct of blood, in the case of quantitatively determining a substrate included in the blood. <P>SOLUTION: The measuring method includes a voltage applying step (T0-T1) for preprocessing the blood; a voltage applying step (T2-T3) for compensating data; and a voltage applying step (T4-T5) for oxidizing a generated reduced electron carrier after a certain period of time. A parameter depending on hematocrit is calculated, based on a ratio of a peak current value (i2) which is obtained in the voltage applying step for compensating, to a peak current value (i4) which is obtained in the voltage applying step for oxidizing the generated reduced electron carrier after the certain period of time, and the amount of substrate is compensated by using the parameter. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a measurement method using a biosensor and a measurement device to which the biosensor is mounted in order to quantify a substrate contained in blood, and particularly for reducing measurement errors due to hematocrit in blood. A new quantitative method is provided.

  A biosensor is a sensor that uses the molecular recognition ability of biological materials such as microorganisms, enzymes, antibodies, DNA, RNA, etc., and applies the biological material as a molecular identification element to quantify the substrate content in a sample solution. That is, the substrate contained in the sample solution is quantified using a reaction that occurs when the biological material recognizes the target substrate, for example, oxygen consumption due to respiration of microorganisms, enzyme reaction, luminescence, and the like. Among various biosensors, enzyme sensors have been put to practical use. For example, enzyme sensors that are biosensors for glucose, lactic acid, cholesterol, and amino acids are used in the medical measurement and food industries. This enzyme sensor, for example, reduces an electron carrier by electrons generated by a reaction between a substrate contained in a sample solution that is a specimen and an enzyme, and the measuring device electrochemically measures the reduction amount of the electron carrier. Thus, the quantitative analysis of the specimen is performed.

  Various types of measurement methods using such biosensors have been proposed. Therefore, a conventional measurement method will be described. (For example, refer to Patent Document 1.) In order to quantify the substrate content in the sample solution, after inserting the biosensor into the measurement device, the sample is applied in a state where a constant voltage is applied to the electrode of the biosensor described later by the measurement device. The liquid is supplied to the sample spotting part. The spotted sample solution is sucked into the biosensor and the reagent layer starts to dissolve. The measuring device detects the electrical change that occurs between the electrodes of the biosensor and starts the quantitative operation.

  The profile after detecting the sample liquid supply is shown in FIG. This profile includes three continuous periods, for example, a first application period from time t0 to t1, a standby time from time t1 to t2, and a second application period from time t2 to t3. By providing this first application period, measurement errors due to hematocrit can be suppressed.

In addition, a biosensor measurement method for correcting the influence of error and obtaining the concentration of an analysis object will be described. (For example, refer to Patent Document 2.) The voltage determined in the biosensor is applied twice to promote the electrochemical reaction, and the following parameters P1 and P2 are calculated from the current values obtained as a result. The analyte concentration is calculated by correcting the error by the technique. P1: A ratio (If / Ib) of the current value (If) after the maximum value in the first excitation or the current value (If) after the maximum value and the current value (Ib) at an arbitrary time point in the second excitation. P2: Current value (Ib) at an arbitrary time point of the second excitation.
JP 2003-156469 A WO99 / 60391 pamphlet

  However, the conventional measurement method has a problem that blood hematocrit affects measurement sensitivity. Hematocrit is the volume ratio (%) of the formed component in the blood. In general, red blood cells account for 40 to 50% in people without anemia. In chronic renal failure and renal anemia, the hematocrit may fall below 15%, and there are large individual and gender differences.

  On the other hand, shortening of measurement time is desired as a specification required for recent biosensors. When a substrate is measured quickly using a biosensor, the viscosity of the sample greatly affects the measurement accuracy. In particular, when human blood is used as a sample solution, the response level is relatively low and the viscosity is low (Hct is low: hereinafter, low Hct) in the case of blood having high viscosity (high Hct: hereinafter, high Hct). ) In the case of blood, the response level is relatively high, and this tendency may become more prominent as the measurement time is shortened. This phenomenon suggests that the solubility of the reagent layer in blood and the diffusion rate of dissolved species are affected by Hct.

  FIG. 6 is a diagram showing the relationship between measurement time and hematocrit. This is a result of measurement according to the measurement method of Patent Document 1 shown in FIG. The measurement time is t3 shown in FIG. 5, and is a plot of current values at t3 when measured using low and high Hct blood. As is apparent from FIG. 6, it can be seen that the difference in current value due to the difference in hematocrit increases as the measurement time becomes shorter. In particular, when the measurement time is about 5 seconds, it is greatly affected by hematocrit. For this reason, it is very difficult to reduce the time by the measurement method of Patent Document 1 because the measurement error due to hematocrit becomes remarkable.

  In the conventional measurement method disclosed in Patent Document 2, the ratio of the maximum current value in the first excitation or the current value after the maximum value to the current value at an arbitrary time point in the second excitation is more greatly affected by the physical properties of the sample. Used as a parameter. Since the first excitation is in the early stage of dissolution, the solubility of the reagent layer in blood and the diffusion rate of dissolved species become rate limiting, and it is easy to obtain a current value depending on hematocrit. The current value tends to vary due to the difference between the two. Furthermore, an easily oxidizable substance contained in blood is easily detected as a current value at the time of the first excitation, and the current value of the first excitation is likely to cause an error due to individual differences in blood oxidizable substances. Further, in order to use the maximum value of the first excitation current or a current after the maximum value for correction, a certain amount of application time is required. However, if an electric potential is applied for a long time in the initial stage (first excitation), the reducing electron carrier is oxidized excessively. Therefore, if the waiting time is lengthened and the reducing electron carrier is not accumulated again, the second excitation period There is a possibility that the substrate dependence of the response value detected by the method will deteriorate. Therefore, in the measurement method of Patent Document 2, it is very difficult to perform measurement with reduced variation and to shorten the measurement time.

  In order to solve the above conventional problems, the substrate concentration measuring method of the present invention includes a counter electrode formed on at least a part of an insulating substrate, an electrode part including a measuring electrode, and at least an enzyme on or around the electrode part. A biosensor having a reagent layer containing an electron carrier and a measuring device having a connection terminal and a driving power source for applying a potential to each electrode of the electrode unit, and applying a potential to the electrode unit by the driving power source This is a measurement method for detecting a current output and quantifying a substrate contained in blood, and includes three or more intermittent voltage application steps.

  The intermittent voltage application step includes at least a voltage application step for blood pretreatment, a voltage application step for data correction, and a voltage application step for oxidizing a reduced electron carrier generated after a certain period of time. May be included.

  Further, in the voltage application process, a voltage application process for data correction is performed after the voltage application process for blood pretreatment, and the voltage application process for the data correction is generated after a certain time has elapsed. A voltage application step for oxidizing the reduced electron carrier may be performed.

  Further, the ratio between the peak current value obtained from the voltage application step for data correction and the peak current value obtained from the voltage application step for oxidizing the reduced electron carrier generated after the lapse of the predetermined time. The parameter depending on the hematocrit may be calculated based on the above, and the base mass may be corrected by the parameter.

  Further, the hematocrit may be corrected using a discriminant function using the parameter as a discriminant coefficient.

  Further, the applied voltage in the voltage application step for blood pretreatment and the voltage application step for data correction is more than the applied voltage in the voltage application step for oxidizing the reduced electron carrier generated after a lapse of a certain time. It may be a measuring method characterized by being large.

  The voltage application time in the voltage application step for blood pretreatment may be 0.2 second to 2 seconds.

  The open circuit time immediately before the voltage application process for data correction may be 0.2 seconds to 1 second.

  The voltage application time in the voltage application process for data correction may be 0.2 second to 2 seconds.

  Further, the measurement method may be characterized in that the open circuit time immediately before the voltage application step for oxidizing the reduced electron carrier generated after the lapse of the predetermined time is 1 second to 6 seconds.

    According to the substrate concentration measuring method of the present invention, the counter electrode formed on at least a part of the insulating substrate, the electrode part including the measurement electrode, the reagent layer including at least the enzyme and the electron carrier on or around the electrode part A measuring device having a connection terminal for applying a potential to each electrode of the electrode unit and a drive power supply, and detecting a current output by applying the potential to the electrode unit by the drive power source A method for measuring a substrate contained in blood, wherein a voltage application step for blood pretreatment, a voltage application step for data correction, and a reduced electron carrier generated after a certain period of time are oxidized. Including a voltage application step for the peak current value obtained from the voltage application step for the correction, and a voltage application step for oxidizing the reduced electron carrier generated after the lapse of the predetermined time. Calculating a parameter that depends on the hematocrit based on the ratio of the peak current value that is, by correcting the amount of substrate by the parameter, it is possible to provide a good method for measuring the measurement accuracy.

  Embodiments of the substrate concentration measuring method of the present invention will be described below in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 shows a profile diagram of a substrate concentration measurement method in the first embodiment of the present invention.

  In the profile in FIG. 1, the time when it is detected that blood is supplied is T0. The profile of FIG. 1 includes five steps, T0 to T1 being the first step (voltage application step for blood pretreatment), T1 to T2 being the second step (open circuit), and T2 to T3 being the third step. Step (voltage application step for data correction), T3 to T4 for the fourth step (open circuit), T4 to T5 for the fifth step (voltage application for oxidizing the reduced electron carrier generated after a certain period of time Process).

  In the first step for blood pretreatment, the reduced electron carrier generated as a result of the enzyme reaction in the initial stage of dissolution is oxidized, and at the same time, an oxidizable substance contained in the blood is added in the first voltage application step. It is oxidized in a certain first step.

  Next, by making the second step an open circuit, the reduced electron mediator generated by the enzyme reaction is accumulated.

  In the third step for data correction, the application is started without sufficiently having the open circuit time of the second step, so that the reduced electron mediator cannot be sufficiently accumulated especially as the blood becomes high Hct, The peak current i2 is a value greatly affected by hematocrit.

  In the present invention, in addition to the third step used for data correction, the first step is provided as a blood pretreatment, thereby eliminating the variation due to the difference in blood supply speed and procedure and the influence of reducing substances in the blood. In the third step, parameters that are only affected by hematocrit can be obtained. Furthermore, the presence of the first step makes it possible to simultaneously obtain a final response value in which the influence of easily oxidizable substances in blood is reduced.

  Next, in the fourth step, the circuit is opened again, and the reduced electron carrier is accumulated again. At this time, a sufficient amount of reduced electron carrier is accumulated even in high-Hct blood by taking a certain time or more.

  The peak current i4 obtained when the potential V3 is applied in the fifth step is a value that is apparently less influenced by hematocrit. Thereafter, the current value of i5 indicating the current value having the highest dependence on the substrate concentration is measured. Let i5 be the final response value. Then, in order to reduce the influence of the hematocrit on the final response value, the i4 / i2 parameter is calculated using i2 obtained in the third step for data correction, and the response value i5 is based on this parameter. Add a predetermined correction.

  In this measurement method, the open circuit time T1 to T2 before the voltage application step for data correction varies depending on the ability of the enzyme used, but is preferably 0.2 seconds to 1 second. Further, the time T0 to T1 of the voltage application process for blood pretreatment and the time T2 to T3 of the voltage application process for data correction vary depending on the ability of the enzyme to be used, but are preferably 0.2 seconds to 2 seconds. Further, the applied voltage in the voltage application step for blood pretreatment and the voltage application step for data correction is more than the applied voltage in the voltage application step for oxidizing the reduced electron carrier generated after a lapse of a certain time. Larger is preferred. Furthermore, the voltage V2 is preferably 0.1V to 0.8V. Moreover, it is preferable that the open circuit time just before the voltage application process for oxidizing the reduced electron carrier produced | generated after progress for a fixed time is 1 second-6 seconds.

  Further, accuracy is further improved by performing voltage application for data correction several times and using a plurality of current values obtained by voltage application for data correction several times for correction. In this case, a different voltage may be applied.

  Further, the current value obtained in the voltage application step for the data correction and the voltage application step for oxidizing the reduced electron carrier generated after a predetermined time has passed can be obtained by the method as described in Patent Document 2 above. Thus, the hematocrit may be corrected using a discriminant function as a discriminant coefficient.

  In the voltage application process for data correction, the current value at any point can be used as long as a value that is greatly affected by hematocrit is obtained, but the effect is significant in order to perform correction with less error. It is preferable to use an easy peak current.

  More specific embodiments of the present invention will be described in detail with reference to the drawings. A biosensor having the following configuration was used as an example of the sensor.

  FIG. 2A is an exploded perspective view of the biosensor, and FIG. 2B is a diagram illustrating the configuration of the electrode portion viewed from the top surface of the biosensor. Reference numeral 19 denotes an insulating substrate (hereinafter referred to as “substrate”) made of polyethylene terephthalate or the like, and a conductor layer made of palladium is formed on the surface of the substrate 19 by sputtering. Reference numeral 26 denotes an insulating substrate having an air hole 27 in the center, and is disposed integrally with the substrate 19 with a spacer 24 having a notch 25 interposed between the substrate 19 and the spacer 19.

  On the substrate 19, a conductive layer is divided by a plurality of slits to form a counter electrode 21, a measurement electrode 20, and a detection electrode 22.

  The spacer 24 is disposed so as to cover the counter electrode 21, the measurement electrode 20, and the detection electrode 22 on the substrate 19, and a specimen supply path 25a is formed. A reagent layer 23 is formed by applying a reagent containing glucose dehydrogenase as an enzyme and potassium ferricyanide as an electron carrier on the counter electrode 21, the measurement electrode 20, and the detection electrode 22 exposed from the notch 25 of the spacer 24. .

  The reagent layer containing the enzyme and the electron carrier is dissolved in the blood sucked into the specimen supply channel, and an enzyme reaction proceeds with glucose, which is a substrate in the blood, to reduce the electron carrier and reduce the reduced electron. A transmitter is generated. The reduced electron carrier is electrochemically oxidized, and the glucose concentration in the blood is measured from the current value obtained at this time. In such a series of reactions, the counter electrode 21, the measurement electrode 20, and the detection electrode 22 read the current value associated with the electrochemical change.

  FIG. 3 shows parameters calculated in this measurement method using blood with Hct of 25% (low Hct), 45%, and 65% (high Hct). The first step (voltage application for blood pretreatment) is 0.5 seconds when 0.5 V is applied, the second step (open circuit) is 0.5 seconds, and the third step (application for data correction) is 0. .5V applied for 0.5 seconds, 4th step (open circuit) for 1.5 seconds, 5th step (voltage applied to oxidize reduced electron carrier generated after a certain period of time) applied 0.2V It is 2 seconds. Then, i4 / i2 calculated by measuring the current value i2 0.1 seconds after the voltage application start in the third step and the current value i4 0.1 seconds after the voltage application start in the fifth step is shown in FIG. Parameter. The horizontal axis represents the final response value i5 after 2 seconds from the start of voltage application in the fifth step, and the vertical axis represents i4 / i2. The difficulty in discriminating the hematocrit value is that the same current value may be obtained for blood with a low substrate concentration of low Hct and blood with a high substrate concentration of high Hct and i5. By using the parameters of FIG. 5, it is clear that even if i5 shows the same current value, it can be classified for each hematocrit.

  Table 1 below shows correction values for the numerical values of the parameters obtained in FIG.

According to this table, the correction value is multiplied by the final response value i5.

  FIG. 4 is a diagram showing the influence of hematocrit when measurement is performed using the measurement method of the present invention and the conventional method. In the conventional measurement method, 0.5 V is applied as the first application for 6 seconds, the standby time is 6 seconds, 0.2 V is applied as the second application for 3 seconds, and the total measurement time is 15 seconds. The case is shown where the total measurement time of 5 V for 2 seconds, the standby time of 2 seconds, and the second application of 0.2 V for 1 second is shortened to 5 seconds. The conventional measurement method shortens the time from 15 seconds to 5 seconds, so that the Hct25% low Hct blood has a relatively high measurement result compared to the reference Hct45%, and the Hct65% high Hct blood has a relatively low value. Become.

  By using this measurement method, it is possible to reduce the variation in hematocrit even though the total measurement time is equal.

  The biosensor measurement method according to the present invention includes a counter electrode formed on at least a part of an insulating substrate, an electrode part including the measurement electrode, and a reagent layer including at least an enzyme and an electron carrier on or around the electrode part. And a measuring device having a connection terminal and a driving power source for applying a potential to each electrode of the electrode unit, and detecting a current output by applying a potential to the electrode unit by the driving power source. A measurement method for quantifying a substrate contained in blood, in which a voltage application step for blood pretreatment, a voltage application step for data correction, and a reduced electron carrier generated after a certain period of time are oxidized A voltage application step for oxidizing the reduced electron mediator generated after elapse of the predetermined time, and a peak current value obtained from the voltage application step for the correction Based on the ratio to the peak current value obtained, the hematocrit-dependent parameter is calculated, and the base mass is corrected by the parameter, thereby improving the measurement accuracy of the biosensor that quantifies the substrate concentration contained in the blood. It is useful as a simple measuring method.

The figure which shows the profile of the measuring method of this invention Exploded perspective view of a biosensor according to the present invention The figure which shows the relationship between the parameter calculated from the measuring method of this invention, and measurement sensitivity The figure which shows the influence of Hct at the time of measuring using the measuring method of this invention, and the conventional method Figure showing the profile of a conventional measurement method The figure which shows the relationship between Hct, measurement time, and measurement sensitivity

Explanation of symbols

1 t0 Time when blood is supplied in the conventional measurement method 2 t1 Time when the first application period ends in the conventional measurement method and the open circuit starts 3 t2 Time when the second application period starts in the conventional measurement method 4 t3 Time to read the current value as the final response value in the conventional measurement method 5 v1 Voltage in the first application period in the conventional measurement method 6 v2 Voltage in the second application period in the conventional measurement method 7 T0 In the measurement method of the present invention Time when blood is supplied 8 T1 The voltage application step for blood pretreatment in the measurement method of the present invention is completed.
Time 9 T2 The voltage application process for data correction in the measurement method of the present invention starts.
Time 10 T3 The voltage application process for data correction in the measurement method of the present invention is completed.
Time 11 T4 Time when the voltage application step for oxidizing the reduced electron carrier generated after a lapse of a certain time in the measurement method of the present invention starts 12 T5 Time for reading the current value as the final response value in the measurement method of the present invention 13 V1 Applied voltage for blood pretreatment in the measurement method of the present invention 14 V2 Applied voltage for data correction in the measurement method of the present invention 15 V3 Reduced electron carrier generated after a certain period of time in the measurement method of the present invention
Applied voltage for oxidizing 16 i2 obtained in the voltage application step for blood pretreatment in the measurement method of the present invention
Peak current 17 i4 Reduced electron carrier generated after a certain period of time in the measurement method of the present invention
Peak current obtained in the voltage application process for oxidizing 18 i5 Final response value in the measurement method of the present invention 19 Insulating substrate 20 Measurement electrode 21 Counter electrode 22 Detection electrode 23 Reagent layer 24 Spacer 25 Notch 25a Specimen supply path 26 Insulating board 27 Air hole

Claims (10)

A biosensor having a counter electrode formed on at least a part of an insulating substrate, an electrode part including a measurement electrode, a reagent layer including at least an enzyme and an electron carrier on or around the electrode part, and each electrode of the electrode part Measurement using a measuring device having a connection terminal and a driving power supply for applying a potential to the electrode, detecting a current output by applying a potential to the electrode portion by the driving power supply, and quantifying a substrate contained in blood A method for measuring a substrate concentration, comprising three or more intermittent voltage application steps. The intermittent voltage application step includes at least a voltage application step for blood pretreatment, a voltage application step for data correction, and a voltage application step for oxidizing a reduced electron carrier generated after a predetermined time has elapsed. The method for measuring a substrate concentration according to claim 1, wherein: In the voltage application step, after the voltage application step for blood pretreatment, a voltage application step for data correction is performed, and after the voltage application step for data correction, a reduced type generated after a lapse of a certain time The method for measuring a substrate concentration according to claim 2, wherein a voltage application step for oxidizing the electron carrier is performed. Based on the ratio between the peak current value obtained from the voltage application step for data correction and the peak current value obtained from the voltage application step for oxidizing the reduced electron carrier generated after the lapse of the predetermined time. 4. The method for measuring a substrate concentration according to claim 2, wherein a parameter dependent on hematocrit is calculated and the base mass is corrected by the parameter. The method for measuring a substrate concentration according to claim 4, wherein hematocrit is corrected using a discriminant function having the parameter as a discriminant coefficient. The applied voltage in the voltage application step for blood pretreatment and the voltage application step for data correction is greater than the applied voltage in the voltage application step for oxidizing the reduced electron carrier generated after a lapse of a certain time. The method for measuring a substrate concentration according to claim 1, wherein: The method for measuring a substrate concentration according to claim 1, wherein a voltage application time in the voltage application step for the blood pretreatment is 0.2 second to 2 seconds. 8. The substrate concentration measuring method according to claim 1, wherein an open circuit time immediately before the voltage application step for data correction is 0.2 second to 1 second. The method for measuring a substrate concentration according to claim 1, wherein the voltage application time in the voltage application step for data correction is 0.2 second to 2 seconds. 10. The method for measuring a substrate concentration according to claim 1, wherein the open circuit time immediately before the voltage application step for oxidizing the reduced electron carrier generated after the lapse of the predetermined time is 1 second to 6 seconds. .

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