KR101721572B1 - Biosensors for Glycosylated Hemoglobin using electrochemically active nano particles - Google Patents

Abstract

The present invention provides an electrochemical sensor for measuring the ratio of glycated hemoglobin from a shielding effect by reaction between boronic acid and glycated hemoglobin using gold electrodes to which various boronic acid derivatives are immobilized by using electrochemically active nanoparticles. The sensor according to the present invention can measure the concentration of glycated hemoglobin by a relatively simple process in which boric acid is fixed to an electrode by a method of forming a self-assembled film using a boronic acid derivative and then glycated hemoglobin is bound thereto. The sensor works well under basic conditions and there is a pH that exhibits optimal operating performance depending on the type of boronic acid derivative used for boronic acid fixation.

Description

[0001] The present invention relates to a biosensor for measuring hemoglobin using electrochemically active nanoparticles,

The present invention relates to an electrochemical sensor for measuring the ratio of glycated hemoglobin using a gold electrode on which various boronic acid derivatives are immobilized by using nanoparticles exhibiting electrochemically active activity, by a shielding effect by reaction between boronic acid and glycated hemoglobin.

Diabetes is a disease caused by inappropriate carbohydrate metabolism that does not properly use glucose absorbed in the body due to insufficient amount of insulin secretion or abnormal operation and excessive blood sugar in the blood can cause various complications. Type 1 diabetes is an insulin-dependent diabetes mellitus, and it is a type that loses its function of synthesizing or secreting insulin by the autoimmune reaction of interest cells. Type 2 diabetes is non-insulin dependent diabetes, which is caused by insulin resistance to the insulin or inappropriate insulin secretion. In addition, there is gestational diabetes that can occur during pregnancy.

There are many ways to diagnose diabetes. However, there are disadvantages in that blood glucose or blood sugar level is biologically changed due to various factors such as dietary and physical activity status, so it is necessary to collect blood glucose or glucose in fasting state. In order to compensate for this, an additional glycosylated hemoglobin test can be performed to detect long-term blood glucose control.

Glycosylated hemoglobin (hemoglobin A _1C , HbA _1C ) is a form of combining hemoglobin and glucose (glucose). When hemoglobin in red blood cells is exposed to a high blood glucose state for a long time, the amino group of the β- A glycosylation process occurs in which residues (glucose) bind in a non-enzymatic reaction, which is a very gradual and irreversible reaction (see FIG. 1).

Because the hemoglobin concentration differs from person to person, it is diagnosed as% HbA _1C , which is defined as the concentration of glycated hemoglobin in relation to the total hemoglobin concentration.

_{% HbA 1C = C HbA1c / C} Hb

% HbA _1C is proportional to the mean blood glucose level in the blood. The advantage of the HbA1c measurement is the average blood glucose level for 2-3 months, so it is easy to grasp the condition of the patient, is not influenced by relatively short-term deviation, and does not need fasting and glucose. In 1999, the International Diabetes Federation (IDF) presented the same reference to 6.5% of glycated hemoglobin.

Immunoassay (Metus, P.; Ruzzante, N., Bonvicini, P., Meneghetti, M .; Zaninotto, M .; Plebani, MJ Clin. Anal . 1999 , 13 , 5-8), ion-exchange chromatography (Eckerbom, S .; Bergqvist, Y .; Jeppsson, JO Ann. Clin. Biochem. 1994 , 31 , 355-360) , boronate affinity chromatography (boronate affinity chromatography) (Frantzen, F .; Grimsrud, K .; Heggli, DE; Faaren, AL;.. Lovli, T .; Sundrehagen, E. Clin Chem 1997, 43, 2390- 2396), electrophoresis (Jenkins, M .; Ratnaike, S. Clin. Chem. Lab. Med., 2003 , 41 , 747-754), fluorescence (Yang, W. ;.... Springsteen, G .; Deeter, S .; Wang, B. Bioorg Med Chem Lett 2003, 13, 1019-1022), surface plasmon resonance (surface plasmon resonance) (Lee, M .; Kim, TI Kim, KH; Choi, MS; Choi, HJ; Koh, K. Anal. Biochem. 2002 , 310 , 163-170). Most of these methods are based on chromatographic separation, and other methods require antibodies or commercially available boronic acid derivatives. In addition, there are drawbacks that require expensive equipment, difficulty in handling equipment, and high time consumption.

On the other hand, electrochemical methods can be measured at a relatively low cost, which is economical, simple in equipment, easy to miniaturize, and capable of obtaining accurate measurement values. As a specific example of the electrochemical analysis method for measuring glycated hemoglobin, impedance spectroscopy (Park, JY; Chang, BY; Nam, H. Park, SM Anal. Chem. 2008 , 80 , 8035-8044) The self-assembled monolayer was formed on the surface of the electrode using thiophene-3-boronic acid to make use of the bond between boronic acid and glycated hemoglobin. The higher the concentration of glycated hemoglobin, the higher the impedance of the electrode surface And the concentration of glycated hemoglobin is measured. As another example, potentiometry (Liu, H .; Crooks, RM Anal. Chem., 2013 , 85 , 1834-1839) discloses the use of phenylboronic acid and glycosylated hemoglobin and alizarin red S And uses a bond between the diol groups. ARS is used as an oxidation-reduction indicator. When binding with phenylboronic acid, it shifts the dislocation in the negative direction. When there is glycosylated hemoglobin, it competes with ARS to shift the dislocation in the positive direction. Is measured. In addition, amperometry (Kim, DM; Shim, YB Anal. Chem., 2013 , 85 , 6536-6543) has shown that aminophenylboronic acid is bound to glycated hemoglobin, The reduction of hydrogen peroxide is catalyzed to obtain an electrochemical signal.

Meanwhile, US Pat. No. 2010-0089774 discloses a technique for measuring glycated hemoglobin without labeling by fixing boronic acid directly on the electrode. In the electrode manufactured by mixing 4-phenyl-vinyl-boronic acid with carbon paste A technique of measuring the ratio of glycated hemoglobin by measuring a changing voltage is disclosed. However, when a boric acid is mixed with a carbon paste to prepare an electrode, it is difficult to prepare a carbon paste electrode when the amount of boronic acid is increased. Therefore, it is necessary to add a small amount of boronic acid. There is a problem. In addition, when a living body sample is measured with a carbon paste electrode, there is a problem that it is easily affected by coexisting substances.

The present invention provides a means for detecting the concentration of glycated hemoglobin by electrochemical analysis. In particular, it is an object of the present invention to provide an electrochemical sensor which is simple in preparation and has a high sensitivity and can be measured even without a professionally skilled measurer.

The self-assembled membrane of the present invention comprises a working electrode and a self-assembled membrane of a boronic acid derivative formed on the working electrode, wherein the self-assembled membrane is bound to a glycated hemoglobin and the electrochemical activity of the nanoparticle A biosensor for measuring the concentration of glycated hemoglobin from a chemical signal is provided.

Preferably, the nanoparticles have different accessibility to the working electrode depending on the glycated hemoglobin concentration.

Preferably, the nanoparticles cause oxidation or reduction by electrons.

Preferably, the working electrode is a gold (Au) electrode.

Preferably, the boronic acid derivative is a boronic acid having one substituent selected from the group consisting of thiol, thiophene and amine.

Preferably, the boronic acid derivative is T3BA (thiophene-3-boronic acid, Thiophene-3-boronic acid) , p -MPBA (p - mercapto phenylboronic acid, p -Mercaptophenylboronic acid), m -MPBA (m - mercapto-phenylboronic acid, m -Mercaptophenylboronic acid), m- APBA (m - aminophenyl boronic acid, m -Aminophenylboronic acid) and TPBA (4- (2H- tetrazol-5-yl) phenylboronic acid, 4- ( 2H-tetrazol-5-yl) phenylboronic acid).

Preferably, the nanoparticles are negatively charged silica nanoparticles.

Preferably, the nanoparticles are prepared by mixing tetraethylorthosilicate (TEOS) or tetramethylorthosilicate (TMOS) with silica nanoparticles synthesized by the Stober method or fumed silica nanoparticles with ferrocene .

Preferably, the size of the nanoparticles is at least 130 nm.

Preferably, the operating pH of the biosensor is in the range of 7.0 to 9.7.

Preferably, the method for obtaining an electrochemical signal is a cyclic voltammetry, a square wave voltammetry, a normal pulse voltammetry, or a differential pulse voltammetry.

Preferably, the electrode system used in the method for obtaining an electrochemical signal is a third electrode system composed of a working electrode, an auxiliary electrode and a reference electrode, or a second electrode system composed of a working electrode and a reference electrode.

The present invention introduces electrochemically active nanoparticles into the development of an electrochemical biosensor for the detection of glycated hemoglobin, thereby providing a label-free sensor that does not require a marker, It is possible to measure the measurement object as it is without the preprocessing process such as attaching the fluorescent substance or various functional molecules, and the system can be simplified and analyzed in a short time.

The sensor according to the present invention can measure the concentration of glycated hemoglobin by a relatively simple process in which a boric acid derivative is fixed to an electrode by a self-assembled film formation method and then glycated hemoglobin is bound thereto. In addition, the present invention provides a sensor that responds to glycated hemoglobin by using boronic acid derivatives that are relatively inexpensive and commercially available, compared with enzymes, antibodies, and aptamers. It is economical and efficient.

FIG. 1 shows a reaction in which glycosylated hemoglobin is produced from a bond of hemoglobin and glucose.
Fig. 2 shows the reaction between hemoglobin and hemoglobin.
Fig. 3 shows a preparation process of the working electrode in the sensor of the present invention.
4 is a conceptual diagram of the sensor of the present invention.
5 shows the principle of the sensor of the present invention.
6 shows the results of evaluating the performance of the sensor prepared in Examples 1 to 5 at pH 8.5.
FIG. 7 shows the results of evaluating the performance of the sensor prepared in Example 1 according to the pH.
FIG. 8 shows the results of evaluating the performance of the sensor prepared in Example 2 according to the pH.
FIG. 9 shows the results of evaluating the performance of the sensor prepared in Example 3 according to the pH.
Fig. 10 is a voltage-current chart obtained according to the concentration of glycated hemoglobin at the optimum operating pH of each of the sensors prepared in Examples 1 to 3. Fig.

The present invention relates to an electrochemical sensor for measuring the ratio of glycated hemoglobin using a gold electrode in which various boronic acids or boronic acid derivatives are immobilized by using electrochemically active nanoparticles and a shielding effect by reaction between boronic acid and glycated hemoglobin to provide.

The term " boronic acid derivative " is used as a means for fixing boronic acid on a working electrode, and hence the boronic acid or the boronic acid derivative may be described simultaneously or in the same sense. As described above, since the sensor of the present invention measures% HbA _1C , which is defined as the concentration of glycated hemoglobin with respect to the concentration of total hemoglobin, the 'concentration of glycated hemoglobin' is used in parallel with the term 'ratio of glycated hemoglobin' .

In the sensor, the accessibility of the nanoparticles having electrochemical activity to the working electrode changes depending on the concentration of the glycated hemoglobin that binds to the boronic acid or the boronic acid derivative fixed on the working electrode. Thus, the oxidation-reduction currents due to the nanoparticles are different, and the concentration of glycated hemoglobin is measured therefrom. Therefore, although the above-mentioned sensor utilizes the difference of the electrochemical signal due to the shielding effect according to the glycated hemoglobin concentration, it further controls the size of the nanoparticle having the electrochemical activity, By varying the accessibility of the nanoparticles to glycated hemoglobin, signal differences between glycated hemoglobin concentrations can be amplified.

Boronic acid (formula 1) is a boronic acid in which one alkyl or aryl group is substituted and is reacted with a boronic ester < RTI ID = 0.0 > (Formula 2) or boronate ester (formula 3). Accordingly, the present invention proposes a sensor for detecting glycated hemoglobin using boronic acid capable of recognizing monosaccharide having a diol group, glycated protein and amino acid and reacting to form an ester.

[Chemical Formula 1]

(2)

(3)

The reaction between boronic acid and diol is a pH-dependent reaction. At acidic conditions, the ester is broken as the oxygen and hydrogen ions of the boronic acid ester bind as follows.

In the neutral condition, the boronic acid ester is a stronger Lewis acid than the boronic acid, and thus the reverse reaction proceeds more actively than the reaction in the following equation.

Therefore, the following reaction can advantageously proceed under basic conditions.

delete

delete

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Therefore, in the present invention, the operating pH of the sensor is proposed as a basic condition. FIG. 2 shows the reaction of a glycated hemoglobin having a glucose group and a boronic acid under basic conditions. Specifically, it is confirmed that the boronic acid derivative provided in the present invention can distinguish between the concentrations of glycated hemoglobin in the pH range of 7.0 to 9.7, and exhibits better linearity and smaller standard deviation. Depending on the kind of the boronic acid derivative, there is a pH which shows the optimum operating performance.

In the sensor of the present invention, a self-assembled monolayer (hereinafter also referred to as a self-assembled monolayer) is formed on the electrode to fix the boronic acid on the working electrode. The working electrode is preferably a gold (Au) electrode, a disk electrode, an electrode by sputtering or a screen printing electrode. In order to form a self-assembled film of boronic acid, a boronic acid derivative capable of forming a gold electrode and a self-assembled monolayer including sulfur (S) or nitrogen (N) atoms in the R group is used. thiols, thiols, thiophenes, and amines having one substituent selected from the group consisting of thiol, thiophene, and amine. Preferably, the boronic acid derivative used in the present invention T3BA (thiophene-3-boronic acid, Thiophene-3-boronic acid) ( the formula 4), p -MPBA (p - mercapto phenylboronic acid, p -Mercaptophenylboronic acid) (Chemical formula 5), m -MPBA (m - mercapto-phenylboronic acid, m -Mercaptophenylboronic acid) (Chemical formula 6), m- APBA (m - aminophenyl boronic acid, m -Aminophenylboronic acid) (the formula 7) and TPBA (4- (2H-tetrazol-5-yl) phenylboronic acid, 4- (2H-Tetrazol-5-yl) phenylboronic acid).

[Chemical Formula 4]

[Chemical Formula 5]

[Chemical Formula 6]

(7)

[Chemical Formula 8]

FIG. 3 illustrates a preparation process of a working electrode used in a sensor according to an embodiment of the present invention. First, for the self-assembled film formation of boronic acid, boronic acid derivatives are dissolved in a solvent such as methanol and then cultured on an electrode. After the self-assembled film is formed, the electrode is washed using distilled water. Next, to combine the hemoglobin and the self-assembled membrane, glycated hemoglobin is diluted with a buffer solution, then incubated on an electrode, and the electrode is washed using buffer solution and distilled water.

In the present invention, the third electrode system or the working electrode formed by using the electrode having the boronic acid-glycated hemoglobin-binding material immobilized therein as the working electrode and the reference electrode and the auxiliary electrode added thereto, and the second electrode system Thereby constituting an electrochemical sensor. In the completed sensor, the oxidation-reduction current is obtained according to the ratio of glycated hemoglobin using nanoparticles having electrochemical activity. Nanoparticles having electrochemical activity can be divided into conductive nanoparticles serving as an oxidation-reduction medium for electrodes and nanoparticle outer surfaces or methods of introducing electrochemically active substances into nanoparticles.

The electrochemical signals can be obtained by cyclic voltammetry, square wave voltammetry, normal pulse voltammetry, or differential pulse voltammetry. have.

FIG. 4 is a conceptual view of a sensor according to the present invention, in which a boronic acid derivative is immobilized on a gold electrode, and an electron transfer between the electrode and the electrochemically active material is measured using the interaction between the glycated hemoglobin specifically binding thereto, It is trying to quantify hemoglobin.

FIG. 5 shows the principle of the above-mentioned sensor. In this case, as the ratio of HbA 1 bound to the boronic acid is higher, the nanoparticles are not easily oxidized-reduced due to the blocking effect of HbA 1c. The ratio of glycated hemoglobin can be determined indirectly by measuring the degree of signal decrease with the increase of the ratio of glycated hemoglobin due to the blocking effect.

Therefore, the calibration curve of the biosensor of the present invention has an inverse curve in which an electrochemical signal is increased because oxidation-reduction between the electrode and the nanoparticles becomes easier as the concentration of HbA 1c is lower. Since the boronic acid-saccharide hemoglobin binding material becomes negatively charged, the present invention uses electrochemically active nanoparticles having a negative charge to increase the repulsive force between the nanoparticles and the boronic acid-glycated hemoglobin bond material, It is advantageous to increase the signal difference to improve the discrimination between the concentrations.

Preferably, the nanoparticles used in the present invention are negatively chargeable silica nanoparticles. In one embodiment, tetraethylorthosilicate (TEOS) or tetramethylorthosilicate (TMOS) is synthesized by the Stober method The introduction of ferrocene into nanoparticles or fumed silica nanoparticles. Such nanoparticles are not specifically limited, but those synthesized according to the methods described in the examples of JP-A-10-1321082 can be used.

In addition, for the shielding effect by glycosylated hemoglobin, it is preferable to use nanoparticles having a size of 130 nm or more. When the size of the nanoparticles is too small, the electrochemically active material reaches the electrode regardless of the concentration of the glycated hemoglobin, and the electron transfer is not performed to obtain the signal difference due to the concentration. Therefore, the signal according to the glycated hemoglobin concentration is measured by using the nanoparticles having a certain size or more.

Hereinafter, the present invention will be described in more detail with reference to Examples. It is to be understood by those skilled in the art that these embodiments are for illustrating the present invention only and are not to be construed as limiting the scope of the present invention.

≪ Example 1 >

Preparation of sensor

A gold disc electrode (Model MF-2014) (n = 6) from BASi was used as the working electrode. Polishing was performed on microcloth (Buehler) pads from large particles to small particles in order of alumina powders of 0.05 μm and 1 μm in diameter. It was then sonicated under ethanol. And washed with 1 M sulfuric acid solution using cyclic voltammetry and then with distilled water.

In order to form a boronic acid self-assembled monolayer on the prepared working electrode, 10 mM boronic acid derivative T3BA (thiophene-3-boronic acid) was dissolved in methanol, Respectively. After the self-assembled film was formed, the working electrode was prepared by washing the electrode using distilled water.

In addition, a Ag / AgCl bike reference electrode (Model MF-2052) of CH Instrumets was used as a reference electrode and a platinum wire (Model MW-1033) of BASi was used as an auxiliary electrode.

≪ Examples 2 to 5 >

Example 1 in place of the boronic acid derivative T3BA -MPBA in p (p - mercapto phenylboronic acid, p -Mercaptophenylboronic acid), m -MPBA (m - mercapto-phenylboronic acid, m -Mercaptophenylboronic acid), m- using the - (amino-phenylboronic acid, m -Aminophenylboronic acid m) and TPBA (4- (2H- tetrazol-5-yl) phenylboronic acid, 4- (2H-tetrazol-5 -yl) phenylboronic acid) APBA The sensor was prepared in the same way except that.

≪ Evaluation Example 1 &

To evaluate the performance of the sensors prepared in the above examples, the working electrodes of Examples 1 to 5 were diluted 10-fold with a pH 8.5 buffer solution (10 mM 4-ethylmorpholine-HCl (20 mM NaCl, 50 mM KCl) HbA1c (liquichek diabetes control levels 1, 2, and 3 : % HbA _1C = 5.15%, 9.75%, and 13.75%, respectively) were incubated for 30 min on electrodes and then diluted with buffer and distilled water To clean the electrode.

The thus prepared working electrode, the prepared reference electrode and the auxiliary electrode were combined to form a three-electrode system. Then, a silica nanoparticle having electrochemical activity (using the one prepared from the method described in Examples 1 and 2 of Patent No. 10-1321082) (Concentration of 2 mg / mL, completely dispersed in a 10 mM 4-ethylmorpholine-HCl buffer solution (20 mM NaCl, 50 mM KCl, pH 8.5) using an ultrasonic mill) Square wave voltammetry (measured potential range: 0.0 to 0.7 V (vs. Ag / AgCl)) was performed using an electrochemical alayzer (Model 760D) from CH Instruments.

The results are shown in Fig. In the case of the sensors prepared from Examples 1 to 3, it can be seen that perfect signal discrimination occurred in all three concentrations of glycated hemoglobin.

≪ Evaluation Examples 2 to 4 &

For the sensors of Examples 1 to 3, the performance of the sensor was evaluated while changing the culture pH of the glycated hemoglobin. 10 mM 4-ethylmorpholine-HCl (20 mM NaCl, 50 mM KCl) (pH 7.0, 7.5, 8.0, 8.5) and 10 mM ethanolamine-HCl (20 mM NaCl, 50 mM KCl) (pH 9.2, 9.7) Were used.

The results are shown in Figs. 7 to 9 and Tables 1 to 3, respectively.

pH inclination R ² 7.0 0.0158 0.9198 7.5 - - 8.0 0.0211 0.9998 8.5 0.0191 0.9999 9.2 0.0271 0.9464

(When the R ² value is less than 0.9, the slope and the R ² value are represented by "-")

pH inclination R ² 7.0 - - 7.5 0.0184 0.9831 8.0 0.0202 0.9431 8.5 0.0335 0.9496 9.2 0.0455 0.9916 9.7 - -

(When the R ² value is less than 0.9, the slope and the R ² value are represented by "-")

pH inclination R ² 7.0 - - 7.5 0.0332 0.9069 8.0 0.0517 0.9991 8.5 0.0495 0.9353 9.2 - -

(When the R ² value is less than 0.9, the slope and the R ² value are represented by "-")

From the above results, the operating pH of each sensor showed different sensitivity depending on the type of boronic acid derivative used to form the self-assembled film. That is, in the sensor of Example 1, the sensor of Example 2 is in the buffer solution of pH 7.5 to 9.2, the sensor of Example 3 is in the buffer solution of pH 8.0 to 9.2, The signal decreased with increasing hemoglobin concentration.

On the other hand, the optimized operating pH conditions of the respective sensors obtained from the above results, that is, the voltage currents according to the ratio of glycated hemoglobin were obtained at pH 8.0 in Examples 1 and 3 and at the pH 9.2 in the sensor of Example 2. 10.

From the above results, it was found that the sensors using boronic acid derivatives T3BA, p- MPBA, and m- MPBA can distinguish between glycosylated hemoglobin concentrations under basic conditions and have better linearity and smaller standard deviation depending on the type of boronic acid derivative Indicating that the pH condition is present.

Claims (12)

A working electrode and a T3BA (thiophene-3-boronic acid), p- MPBA ( p -mercaptophenylboronic acid, p- Mercaptophenylboronic acid), m -MPBA (m - mercapto-phenylboronic acid, m -Mercaptophenylboronic acid), m- APBA (m - aminophenyl boronic acid, m -Aminophenylboronic acid) and TPBA (4- (2H- tetrazol -5 Wherein the self-assembled membrane is formed from a boronic acid derivative that is at least one selected from the group consisting of phenylboronic acid, 4- (2H-Tetrazol-5yl) phenylboronic acid, and at a working pH in the range of 7.0 to 9.7 A biosensor that binds to glycated hemoglobin and measures the concentration of glycated hemoglobin from an electrochemical signal generated by a negatively charged nanoparticle having a size of 130 nm or more having an electrochemical activity depending on the concentration of the glycated hemoglobin. The method of claim 1,
Wherein the nanoparticles have different accessibility to the working electrode depending on the concentration of glycated hemoglobin. The method of claim 1,
Wherein the nanoparticles cause oxidation or reduction by electrons. The method of claim 1,
Wherein the working electrode is a gold (Au) electrode. delete delete The method of claim 1,
Wherein the nanoparticles are negatively charged silica nanoparticles. The method of claim 1,
The nanoparticles are prepared by introducing tetraethylorthosilicate (TEOS) or tetramethylorthosilicate (TMOS) into silica nanoparticles synthesized by the Stober method or fumed silica nanoparticles with ferrocene The biosensor is characterized by. delete delete The method of claim 1,
The electrochemical signals can be obtained by cyclic voltammetry, square wave voltammetry, normal pulse voltammetry, or differential pulse voltammetry. Wherein the biosensor is a biosensor. The method of claim 1,
Wherein the electrode system used in the method for obtaining an electrochemical signal is a third electrode system composed of a working electrode, an auxiliary electrode and a reference electrode, or a second electrode system composed of a working electrode and a reference electrode.

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