Magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions and application thereof
阅读说明:本技术 用于灵敏检测痕量镍离子的磁诱导自组装电化学生物传感器及其应用 (Magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions and application thereof ) 是由 许月阳 刘瑞江 薛建明 朱法华 刘涛 王宏亮 杨帆 石丽娜 于 2021-06-15 设计创作,主要内容包括:本发明公开一种用于灵敏检测痕量镍离子的磁诱导自组装电化学生物传感器及其应用,属于电化学生物传感技术领域。该电化学生物传感器利用镍离子依赖性脱氧核酶作为生物识别元件,能够特异性识别镍离子,具有良好的选择性。基于α-Fe-3O-4/Fe-2O-3-Au纳米复合物作为电极衬底材料,具有良好的导电性,并可通过磁力诱导自组装稳定结合在电极表面。该电化学生物传感器可检测镍离子浓度的线性范围为100 pM-10 μM,检测限为55 pM。本发明构建的电化学生物传感器灵敏度高、特异性强、检测限低、制备简单、检测周期短。(The invention discloses a magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions and application thereof, belonging to the technical field of electrochemical biosensor. The electrochemical biosensor utilizes nickel ion-dependent deoxyribozyme as a biological recognition element, can specifically recognize nickel ions, and has good selectivity. Based on alpha-Fe 3 O 4 /Fe 2 O 3 The Au nano composite is used as an electrode substrate material, has good conductivity and can be stably combined on the surface of an electrode through magnetic force induced self-assembly. The linear range of the nickel ion concentration detectable by the electrochemical biosensor is 100pM-10 mu M, and the detection limit is 55 pM. The electrochemical biosensor constructed by the invention has the advantages of high sensitivity, strong specificity, low detection limit, simple preparation and short detection period.)
1. A magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions is characterized in that the construction process is as follows:
(1) the magnetic glassy carbon electrode adopts Al2O3Polishing the powder, and ultrasonically cleaning and drying the powder for later use;
(2) taking 5-10 mu L of alpha-Fe2O3/Fe3O4Dripping Au nano composite suspension liquid on the surface of the magnetic glassy carbon electrode, and forming a layer of uniform alpha-Fe on the surface of the electrode after the electrode is dried at room temperature2O3/Fe3O4-an Au film, ready for use;
(3) dripping 5-10 μ L of sulfhydryl modified DNA1 solution containing tris (2-carboxyethyl) phosphine on the electrode surface in step (2), and incubating at 37 deg.C for 1-8h to obtain MGCE/α -Fe2O3/Fe3O4-Au/DNA1 modified electrode, ready for use;
(4) dropwise adding 5-10 μ L of bovine serum albumin with volume fraction of 0.25% onto the electrode surface obtained in step (3), sealing non-specific sites on the electrode surface, and incubating at 4 deg.C for 30min to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode, ready for use;
(5) dropwise adding 5-10 μ L of methylene blue modified DNA2 solution onto the electrode surface of step (4), wherein the concentration of DNA2 is the same as that of DNA1 in step (3), and incubating at 37 deg.C to obtain MGCE/α -Fe2O3/Fe3O4And (4) modifying the electrode by Au/DNA1/BSA/DNA2 to obtain the electrochemical biosensor.
2. The magnetically-induced self-assembled electrochemical biosensor for sensitive detection of trace nickel ions according to claim 1, wherein the sequence of DNA1 in step (3) is:
5’-CnAnCGTCCATCTCTGCAGTCGGGTAGTTAAACCGACCTTCAGACATAGTGAGTAGCAAAAAAAAAAnAnA-SH-3’;
the sequence of the DNA2 in the step (5) is as follows:
5’-MB-AnCnTCACTAT/RA/GGAAGAGATGGACGnTnG-3’。
3. the magnetically induced self-assembled electrochemical biosensor for sensitive detection of trace nickel ions according to claim 2,characterized in that the alpha-Fe in the step (2)2O3/Fe3O4The concentration of the Au nano-composite suspension is 5-25 mg/mL.
4. The magnetically-induced self-assembled electrochemical biosensor for sensitive detection of trace nickel ions according to any one of claims 1-3, wherein the concentration of the thiol-modified DNA1 solution containing tris (2-carboxyethyl) phosphine in step (3) is 1-20 μ M.
5. The construction method of the magnetically induced self-assembled electrochemical biosensor for sensitive detection of trace nickel ions according to claim 4, wherein the incubation time in step (5) is 30-70 min.
6. The magnetically-induced self-assembled electrochemical biosensor for sensitive detection of nickel ions in trace amounts according to claim 5, wherein the α -Fe in step (2)2O3/Fe3O4The preparation method of the @ Au nano-composite comprises the following steps:
1) mixing Fe (NO)3)3·9H2O and C6H10O8Dissolving the mixture in quantitative double distilled water according to a molar ratio of 1:1.5, and magnetically stirring the mixture for 24 hours at room temperature to obtain a precursor solution which is uniformly dispersed; dehydrating the precursor solution at 60 ℃ by adopting a rotary evaporator to prepare sol; putting the sol into an oven, and drying to obtain fluffy porous dry gel; the dried gel is put into a programmed temperature control furnace and calcined for 2 hours at 450 ℃ to obtain the magnetic alpha-Fe2O3/Fe3O4A heterogeneous nanoparticle;
2) placing a three-neck flask containing 200mL of trisodium citrate solution with the concentration of 7.5mM on an oil bath, and heating to boil under the reflux condition; dispersing 1mL of alpha-Fe with the concentration of 10mg/mL after ultrasonic treatment2O3/Fe3O4Adding the heterogeneous nano-particle suspension liquid drop into a three-neck flask, and magnetically stirring for 5 min; 10mL of chloroauric acid solution with the concentration of 10mM is added into a three-necked flask, magnetic stirring is carried out to obtain wine red solution,centrifuging the solution, washing the precipitate, and vacuum drying to obtain alpha-Fe2O3/Fe3O4-an Au nanocomposite.
7. Use of a magnetically induced self-assembled electrochemical biosensor according to any one of claims 1 to 6 for sensitive detection of trace nickel ions.
8. Use of a magnetically induced self-assembled electrochemical biosensor for the sensitive detection of trace nickel ions according to claim 7, characterized in that upon detection: dropwise adding the solution to be detected on the surface of the electrode, and incubating for 30-80min at 37 ℃; the test was carried out using an electrochemical workstation and a three-electrode system, with a magnetic glassy carbon electrode as the working electrode, silver/silver chloride as the reference electrode, a platinum wire electrode as the counter electrode, and 5mM [ Fe (CN) ] containing 0.1M KCl6]3-/4-The solution is used as electrolyte, an electrochemical biosensor is constructed, and the electrochemical biosensor is tested in a range of-0.1-0.7V by a differential pulse voltammetry method.
9. The use of the magnetically-induced self-assembled electrochemical biosensor for the sensitive detection of trace nickel ions according to claim 8, wherein the solution to be detected is selected from a nickel nitrate solution, a nickel sulfate solution, a nickel bromide solution, or a nickel chloride solution.
10. The use of the magnetically induced self-assembled electrochemical biosensor for the sensitive detection of trace nickel ions according to claim 9, wherein the volume of the solution to be measured is 5-10 μ L.
Technical Field
The invention relates to a magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions and application thereof, belonging to the technical field of electrochemical biosensor.
Background
Nickel (II) (Ni)2+) Is an important trace element in biosynthesis, respiration and metabolism, but excessive Ni2+Can cause diseases such as cancer, neurasthenia, inflammation, and system disorder. At present Ni2+The traditional detection method comprises an adsorption method, a spectrophotometry method, a fluorescence spectrometry method, an inductively coupled plasma mass spectrometry method and the like, but the traditional detection method has the limitations of complex equipment, high operation cost, complex sample preparation, poor specificity and the like. Therefore, it is necessary to search for an effective, simple and highly sensitive Ni2+And (3) a detection method. The electrochemical biosensor has the advantages of high detection sensitivity, high specificity, good reproducibility, small required sample amount and short detection time, and becomes a research hotspot for detecting heavy metal ions in recent years.
Electrochemical detection of Ni2+The method can be realized by constructing a redox reaction electrochemical sensor and a deoxyribozyme electrochemical sensor, wherein the redox reaction analysis method is more complicated, and the performance of the redox reaction analysis method depends on electrode materials; the deoxyribozyme electrochemical sensor has good selectivity and stability, and is very suitable for detecting heavy metal ions in the environment. With the development of nanotechnology, nanomaterials are widely used to improve the sensitivity of electrochemical sensors. However, there is no strong force between the non-magnetic nano material and the electrode surface, which causes the substrate material to be easily separated from the electrode surface, and the current signal is unstableAnd (4) determining. The magnetic nano material can be stably and rapidly combined on the surface of the magnetic glassy carbon electrode through magnetic force induced self-assembly, and the electrode is simple to regenerate by removing the magnetic core, so that the magnetic glassy carbon electrode has good application potential.
Disclosure of Invention
To realize trace Ni2+The invention provides a method for sensitively detecting trace Ni2+The magnetically induced self-assembled electrochemical biosensor of (1).
The invention also provides the application of the electrochemical biosensor.
The specific technical scheme of the invention is as follows:
be used for sensitive detection trace Ni2+The magnetic induction self-assembly electrochemical biosensor has the following construction process:
(1) the magnetic glassy carbon electrode adopts Al2O3Polishing the powder, and ultrasonically cleaning and drying the powder for later use;
(2) taking 5-10 mu L of alpha-Fe2O3/Fe3O4Dripping Au nano composite suspension liquid on the surface of the magnetic glassy carbon electrode, and forming a layer of uniform alpha-Fe on the surface of the electrode after the electrode is dried at room temperature2O3/Fe3O4-an Au film, ready for use;
(3) dripping 5-10 μ L of sulfhydryl modified DNA1 solution containing tris (2-carboxyethyl) phosphine on the electrode surface in step (2), and incubating at 37 deg.C for 1-8h to obtain MGCE/α -Fe2O3/Fe3O4-Au/DNA1 modified electrode, ready for use;
(4) dropwise adding 5-10 μ L of bovine serum albumin with volume fraction of 0.25% onto the electrode surface obtained in step (3), sealing non-specific sites on the electrode surface, and incubating at 4 deg.C for 30min to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode, ready for use;
(5) dropwise adding 5-10 μ L of methylene blue modified DNA2 solution onto the electrode surface of step (4), wherein the concentration of DNA2 is the same as that of DNA1 in step (3), and incubating at 37 deg.C to obtain MGCE/α -Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode, namely electrochemical cellA biological sensor.
Further, 0.3 μm and 0.05 μm of Al were used for the magnetic glassy carbon electrode in this order2O3And (5) polishing the powder.
Further, the sequence of the DNA1 in the step (3) is as follows:
5’-CnAnCGTCCATCTCTGCAGTCGGGTAGTTAAACCGACCTTCAGACATAGTGAGTAGCAAAAAAAAAAnAnA-SH-3’;
the sequence of the DNA2 in the step (5) is as follows:
5’-MB-AnCnTCACTAT/RA/GGAAGAGATGGACGnTnG-3’。
further, the alpha-Fe in the step (2)2O3/Fe3O4The concentration of the Au nano-composite suspension is 5-25 mg/mL.
Further, the concentration of the thiol-modified DNA1 solution containing tris (2-carboxyethyl) phosphine in step (3) is 1 to 20. mu.M.
Further, the incubation time of the methylene blue modified DNA2 solution in the step (5) is 30-70 min.
Further, the alpha-Fe in the step (2)2O3/Fe3O4The preparation method of the @ Au nano-composite comprises the following steps:
1) mixing Fe (NO)3)3·9H2O and C6H10O8Dissolving the mixture in quantitative double distilled water according to a molar ratio of 1:1.5, and magnetically stirring the mixture for 24 hours at room temperature to obtain a precursor solution which is uniformly dispersed; dehydrating the precursor solution at 60 ℃ by adopting a rotary evaporator to prepare sol; putting the sol into an oven, and drying to obtain fluffy porous dry gel; the dried gel is put into a programmed temperature control furnace and calcined for 2 hours at 450 ℃ to obtain the magnetic alpha-Fe2O3/Fe3O4A heterogeneous nanoparticle;
2) placing a three-neck flask containing 200mL of trisodium citrate solution with the concentration of 7.5mM on an oil bath, and heating to boil under the reflux condition; dispersing 1mL of alpha-Fe with the concentration of 10mg/mL after ultrasonic treatment2O3/Fe3O4Adding the heterogeneous nano-particle suspension liquid drop into a three-neck flask, and magnetically stirring for 5 min; 10mL of 10mMAdding chloroauric acid solution into three-neck flask, magnetically stirring to obtain wine red solution, centrifuging the solution, washing precipitate, and vacuum drying to obtain alpha-Fe2O3/Fe3O4-an Au nanocomposite.
The method for sensitively detecting trace Ni2+The use of the magnetically induced self-assembled electrochemical biosensor of (1).
When in detection: dropwise adding the solution to be detected on the surface of the electrode, and incubating for 30-80min at 37 ℃; the test was carried out using an electrochemical workstation and a three-electrode system, with a magnetic glassy carbon electrode as the working electrode, silver/silver chloride as the reference electrode, a platinum wire electrode as the counter electrode, and 5mM [ Fe (CN) ] containing 0.1M KCl6]3-/4-The solution is used as electrolyte, an electrochemical biosensor is constructed, and the electrochemical biosensor is tested in a range of-0.1-0.7V by a differential pulse voltammetry method.
Further, the solution to be detected is selected from a nickel nitrate solution, a nickel sulfate solution, a nickel bromide solution or a nickel chloride solution.
Further, the volume of the solution to be detected is 5-10 muL.
During detection, an inorganic salt solution to be detected is dripped to the surface of the electrode, incubation is carried out at 37 ℃ for 30-80min, metal ions to be detected activate a catalytic core region of DNA1, DNA2 is broken, and DNA2 fragments with methylene blue leave the surface of the electrode, so that electrochemical signals are changed.
The invention selects nickel ion dependent deoxyribozyme (Ni)2+DNAzyme) as biorecognition element in Ni2+The catalyst shows good catalytic performance when being present. The dnazymes immobilized on the electrode surface should retain their intrinsic structure and biological activity and be loaded as much as possible to ensure their high sensitivity. Therefore, the substrate material of the electrochemical biosensor should have a large specific surface area, good biocompatibility, and excellent electrical conductivity. The invention prepares alpha-Fe2O3/Fe3O4-Au nanocomposites as electrode substrate material for signal amplification. alpha-Fe2O3/Fe3O4The Au nano-composite can stabilize the junction through a magnetic force induced self-assembly technologyCombined on the surface of a Magnetic Glassy Carbon Electrode (MGCE), and the MGCE can be quickly regenerated by removing the magnetic inner core of the electrode. And the gold nanoparticles have good conductivity, so that the electrochemical biosensor has high sensitivity. The electrochemical biosensor is trace Ni2+The assays of (a) provide a new sensitive detection method that can be applied to the determination of other metal ions by modifying the biorecognition element.
Compared with the prior art, the invention has the following beneficial effects:
1. the electrochemical biosensor of the invention utilizes nickel ion-dependent deoxyribozyme as a biological recognition element, can specifically recognize nickel ions, and has good selectivity. Based on alpha-Fe3O4/Fe2O3The Au nano composite is used as an electrode substrate material, has good conductivity and can be stably combined on the surface of an electrode through magnetic force induced self-assembly. The electrochemical biosensor can detect the nickel ion concentration in a linear range of 100pM-10 mu M and has a wider linear range. The detection limit was 55 pM. The electrochemical biosensor constructed by the invention has the advantages of high sensitivity, strong specificity, low detection limit, simple preparation and short detection period.
2. Due to alpha-Fe2O3/Fe3O4The @ Au nano-composite has magnetism, and can be used for preparing alpha-Fe through a magnetic force induced self-assembly technology2O3/Fe3O4The @ Au nanocomposite is stably and firmly decorated to the MGCE surface, and alpha-Fe can be rapidly removed by removing the magnetic core of the MGCE2O3/Fe3O4@ Au, the electrode regeneration is simple and rapid.
3. The invention connects sulfhydryl modified DNA1 to alpha-Fe through Au-S bond by self-assembly technology2O3/Fe3O4The @ Au nano-composite surface has the advantages of quick and simple operation and no need of using other materials.
4. The method has mild reaction conditions, is easy to control the process, and does not need to train operators; the requirement on required equipment is not high, the operation is simple, and the carrying is convenient; the DNA chain required by each detection is few, and the cost is low; the detection process is rapid and convenient, and the detection result can be obtained in a few minutes.
Drawings
FIG. 1 is a view of α -Fe prepared in preparation example2O3/Fe3O4A transmission electron micrograph of the @ Au nanocomposite, wherein the scale size in the figure is 50 nm;
FIG. 2 is a graph showing the results of the sensitive detection of Ni traces in example 12+The cyclic voltammetry diagram of the construction process of the magnetically induced self-assembled electrochemical biosensor;
FIG. 3 shows the results of the sensitive detection of Ni traces in example 12+The magnetic induction self-assembly electrochemical biosensor detects Ni2+,Ca2+,Cu2+,Fe3+,Pb2+,Zn2+The peak current of (a);
FIG. 4 shows the results of the sensitive detection of Ni traces in example 12+The magnetic induction self-assembly electrochemical biosensor can detect the concentration and linear range diagram.
Detailed Description
In order to make the objects, features and advantages of the present invention more comprehensible, the present invention is further described in conjunction with the following embodiments and accompanying drawings so that those skilled in the art may better understand the technical solutions of the present invention. It is obvious that the described embodiments are only a few embodiments of the invention, and that all other embodiments, which can be derived by a person skilled in the art without inventive step, such as embodiments relating to the basic principles of the invention, are intended to be covered by the scope of protection of the invention, except for the use of the invention without altering the claims.
The starting materials used in the examples below:
tris (2-carboxyethyl) phosphine, abbreviated as TCEP;
bovine serum albumin, abbreviated BSA;
TCEP and BSA were purchased from Shanghai Allantin Biotech Co., Ltd;
DNA1 and DNA2 were purchased from Biotechnology engineering (Shanghai) Inc., and are described in the sequence listing:
the sequence of DNA1 is:
5’-CnAnCGTCCATCTCTGCAGTCGGGTAGTTAAACCGACCTTCAGACATAGTGAGTAGCAAAAAAAAAAnAnA-SH-3’;
nucleotide sequences in DNA1 are as follows: 1, and the DNA1 is a DNA fragment.
The sequence of DNA2 is:
5’-MB-AnCnTCACTAT/RA/GGAAGAGATGGACGnTnG-3’,
wherein SH represents a mercapto group; MB represents methylene blue; n represents a phosphorothioate linkage modification. A/RA/denotes the insertion of an adenine ribonucleotide between the DNA fragment AnCnTCACTAT and the DNA fragment GGAAGAGATGGACGNTnG.
Preparation example: alpha-Fe2O3/Fe3O4Preparation of @ Au nanocomposite
1) 13.54g Fe (NO)3)3·9H2O and 10.45g C6H10O8Dissolving the precursor solution in 100mL of double distilled water, and magnetically stirring the solution for 24 hours at room temperature to obtain a precursor solution which is uniformly dispersed; dehydrating the precursor solution at 60 ℃ by adopting a rotary evaporator to prepare sol; putting the sol into an oven, and drying to obtain fluffy porous dry gel; the dried gel is put into a programmed temperature control furnace and calcined for 2 hours at 450 ℃ to obtain the magnetic alpha-Fe2O3/Fe3O4A heterogeneous nanoparticle;
2) placing a three-neck flask containing 200mL of trisodium citrate solution with the concentration of 7.5mM on an oil bath, and heating to boil under the reflux condition; dispersing 1mL of alpha-Fe with the concentration of 10mg/mL after ultrasonic treatment2O3/Fe3O4Adding the heterogeneous nano-particle suspension liquid drop into a three-neck flask, and magnetically stirring for 5 min; adding 10mL of chloroauric acid solution with the concentration of 10mM into a three-neck flask, magnetically stirring to obtain wine red solution, centrifuging the solution, washing precipitate, and vacuum drying to obtain alpha-Fe2O3/Fe3O4-an Au nanocomposite.
FIG. 1 shows α -Fe prepared under the conditions described in this example2O3/Fe3O4-transmission electron microscopy of Au nanocomposite; as can be seen from the electron micrograph, gold nanoparticles having an average grain size of 12nm were tightly bound to α -Fe2O3/Fe3O4A heterogeneous nanoparticle surface.
Example 1
The method is used for sensitively detecting the trace Ni2+The magnetic induction self-assembly electrochemical biosensor has the following construction process:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid at room temperature to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Adding 5 μ L BSA with volume fraction of 0.25% dropwise to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1 modifying electrode surface, blocking non-specific sites on electrode surface, preventing non-specific adsorption, incubating at 4 deg.C for 30min to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode, namely, the modified electrode is used for sensitively detecting trace Ni2+The magnetically induced self-assembled electrochemical biosensor of (1).
Test example 1:
the detection process of the modified electrode is as follows:
1) adding 8 μ L of Ni with a concentration of 10 μ M2+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2/Ni2+And modifying the electrode.
2) The test was carried out using an electrochemical workstation (purchased from Shanghai Chenghua instruments Co., Ltd., CHI660E) and a three-electrode system, MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2/Ni2+The modified electrode was used as a working electrode, silver/silver chloride as a reference electrode, and a platinum wire electrode as a counter electrode, using 5mM [ Fe (CN) ] containing 0.1M KCl6]3-/4-The solution was used as an electrolyte, and the peak current of DPV was measured to be 3.6. mu.A by Cyclic Voltammetry (CV), alternating impedance spectroscopy (EIS) and Differential Pulse Voltammetry (DPV). Shows that the electrochemical biosensor can be used for trace Ni2+Detection of (3).
Test example 2:
the cyclic voltammograms obtained by measuring the characteristics of the various electrodes are shown in FIG. 2. In the figure, cyclic voltammograms of various electrodes are shown in sequence from a to g;
the electrodes corresponding to a-g are as follows: bare MGCE, MGCE/alpha-Fe2O3/Fe3O4、MGCE/α-Fe2O3/Fe3O4-Au、MGCE/α-Fe2O3/Fe3O4-Au/DNA1、MGCE/α-Fe2O3/Fe3O4-Au/DNA1/BSA、MGCE/α-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2、MGCE/α-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2/Ni2+;
Wherein the bare MGCE electrode of a is a clean magnetic glassy carbon electrode;
wherein MGCE/α -Fe of b2O3/Fe3O4The preparation process of the modified electrode is as follows:
1) will prepare the alpha-Fe prepared in example2O3/Fe3O4The heteroplasmon nano-particles are dispersed in ultrapure water by ultrasonic wave to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Heterogeneous nano-particle suspension for later use;
2) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping heterogeneous nano-particle suspension on the surface of a cleaned Magnetic Glassy Carbon Electrode (MGCE), and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4And modifying the electrode.
Wherein c is MGCE/alpha-Fe prepared in step 3) of example 12O3/Fe3O4-an Au-modified electrode;
wherein d is MGCE/alpha-Fe prepared in step 5) of example 12O3/Fe3O4-Au/DNA1 modified electrodes;
wherein e is MGCE/alpha-Fe prepared in step 6) of example 12O3/Fe3O4-Au/DNA1/BSA modified electrode;
wherein f is MGCE/alpha-Fe prepared in step 8) of example 12O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode;
wherein g is MGCE/alpha-Fe prepared in step 1) of test example 12O3/Fe3O4-Au/DNA1/BSA/DNA2/Ni2+Modifying the electrode;
as a result of the test, it can be seen from FIG. 2 that the current response value of curve c is higher than that of curve b because the well-conductive gold nanoparticles are successfully modified to alpha-Fe2O3/Fe3O4Heterogenous nanoparticle surface, evidence of alpha-Fe2O3/Fe3O4Au is used as an electrode surface substrate material for amplifying current signals, so that the sensitivity of the electrochemical biosensor can be effectively improved;
the peak currents of curve d and curve e decrease in sequence due to poor conductivity and steric hindrance of DNA1 and BSA; from curve f, it is seen that after the DNA2 is modified to the electrode, since methylene blue is close to the surface of the electrode, the electron transfer capability is enhanced, and the current signal is increased;
curve g shows a reduced current response due to Ni2+After the dropwise addition onto the electrode, the catalytic core region of the DNA1 is activated, the DNA2 chain is broken, the DNA2 chain fragment with the methylene blue fragment is far away from the surface of the electrode, the electron transfer capacity is reduced, and the current signal is reduced.
Test example 3:
MGCE/alpha-Fe constructed as in example 12O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode as electrochemical biosensor, different kinds of metal ion solution were added dropwise to examine the selectivity of electrochemical sensor, test was performed using electrochemical workstation and three-electrode system, modified magnetic glassy carbon electrode as working electrode, silver/silver chloride as reference electrode, platinum wire electrode as counter electrode, 5mM [ Fe (CN) ] containing 0.1M KCl6]3-/4-The solution was used as an electrolyte and tested by Cyclic Voltammetry (CV), alternating impedance spectroscopy (EIS) and Differential Pulse Voltammetry (DPV).
Different metal ion modified electrodes are respectively obtained by the following methods:
1. adding 8. mu.L of Ni with the concentration of 1. mu.M2+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain Ni2+And modifying the electrode.
2. Adding 8 μ L of 100 μ M Ca2+The solution is dripped intoExample one modified electrode surface, incubated at 37 deg.C for 80min to obtain Ca2+And modifying the electrode.
3. Cu of 8. mu.L at a concentration of 100. mu.M2+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain Cu2+And modifying the electrode.
4. Adding 8 μ L of 100 μ M Fe3+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain Fe3+And modifying the electrode.
5. Adding 100 μ M Pb in 8 μ L2+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain Pb2+And modifying the electrode.
6. Adding 8 mu L of Zn with the concentration of 100 mu M2+Dropwise adding the solution to the surface of the modified electrode prepared in the first embodiment, and incubating at 37 ℃ for 80min to obtain Zn2+And modifying the electrode.
As seen from FIG. 3, Ca was compared with the control group without any metal ion added2+,Cu2+,Fe3+,Pb2+And Zn2+When present, the current signal does not change significantly. The reason is that the interfering metal ions cannot be Ni2+DNAzymes recognize that the catalytic core region of the deoxyribozyme is not activated. Only Ni2+Can be covered with Ni2+Specific recognition by DNAzyme, strand DNA2 is cleaved and a fragment of strand DNA2 with methylene blue leaves the electrode surface, resulting in a significant decrease in the current signal. Proving that the electrochemical biosensor is paired with Ni2+Has better selectivity.
Test example 4:
MGCE/alpha-Fe constructed as in example 12O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode as electrochemical biosensor, and Ni with different concentrations is dripped2+And (4) examining the linear range of the concentration which can be detected by the electrochemical sensor.
Ni2+When the concentration is 10 mu M, the DPV peak current is measured to be 3.6 mu A; when the concentration of nickel ions is 1 mu M, the DPV peak current is measured to be 9.1 mu A; the peak DPV current was measured to be 15 at a nickel ion concentration of 100 nM.0 muA; when the concentration of nickel ions is 10nM, the DPV peak current is measured to be 18.2 muA; when the concentration of nickel ions is 1nM, the DPV peak current is measured to be 25.5 muA; the peak current of DPV was found to be 31.3. mu.A at a nickel ion concentration of 100 pM.
As seen in FIG. 4, the current response is dependent on Ni2+The concentration is increased and reduced, the concentration range which can be detected by the electrochemical biosensor is 100pM-10 mu M, the detection line is 55pM calculated by linearly fitting data, the linear equation is I (mu A) ═ 5.5272lg C (M) -24.0097, and the correlation coefficient R is20.996. I represents current and C represents concentration.
Example 2
The method is used for sensitively detecting the trace Ni2+The magnetic induction self-assembly electrochemical biosensor has the following construction method:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then sequentially carrying out ultrasonic cleaning in ultrapure water, absolute ethyl alcohol and ultrapure water for 1min respectively, and drying to obtain a clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 5mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 5mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4Au modified electrode surface, incubated at 37 ℃ for 2h to obtain MGCE/α-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Adding 5 μ L BSA with volume fraction of 0.25% dropwise to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1 modifying electrode surface, blocking non-specific sites on electrode surface, preventing non-specific adsorption, incubating at 4 deg.C for 30min to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode.
In the detection, 8 mu L of Ni with the concentration of 10nM2+The solution was added dropwise to MGCE/α -Fe prepared in example 22O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min. The DPV peak current is measured to be 14.3 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. alpha-Fe2O3/Fe3O4Au as electrode substrate material for signal amplification strategies. The detected material has good conductivity, so that the electrochemical biosensor is used for Ni2+The detection has higher sensitivity, lower detection limit and wider linear range; and the magnetic material has magnetism, can be quickly and stably combined on the surface of the electrode through magnetic force induced self-assembly, and can realize quick regeneration of the electrode by removing the magnetic core of the electrode.
Example 3
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) was sequentially applied with 0.3 μm and 0.05 μm Al2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 25mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 25mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8 mu L of Ni with the concentration of 10nM2+The solution was added dropwise to MGCE/α -Fe prepared in example 32O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min.
The DPV peak current is measured to be 9.2 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. alpha-Fe2O3/Fe3O4Au as electrode substrate material for signal amplification strategies. The detected material has good conductivity, so that the electrochemical biosensor is used for Ni2+The detection has higher sensitivity, lower detection limit and wider linear range; and the magnetic material has magnetism, can be quickly and stably combined on the surface of the electrode through magnetic force induced self-assembly, and can realize quick regeneration of the electrode by removing the magnetic core of the electrode.
Example 4
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl), and mixing to obtain thiol-modified DNA1 solution with the concentration of 1 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 1. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 muL of methylene blue modified DNA2 solution with the concentration of 1 muM in 7) into MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with the concentration of 10. mu.M is added2+The solution was added dropwise to MGCE/α -Fe prepared in example 42O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min.
The DPV peak current is measured to be 27.2 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. DNA1 is sterically hindered, poorly conductive, and negatively charged, blocking [ Fe (CN)6]3-/4-Reaching the electrode surface resulting in a reduced current signal.
Example 5
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-an Au-modified electrode.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing to prepare thiol-modified DNA1 solution with the concentration of 20 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 20. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of 20 μ M methylene blue modified DNA2 solution in 7) to MGCE/α -Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with the concentration of 10. mu.M is added2+The solution was added dropwise to MGCE/α -Fe prepared in example 52O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min.
The DPV peak current is measured to be 3.5 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. DNA1 is sterically hindered, poorly conductive, and negatively charged, blocking [ Fe (CN)6]3-/4-Reaching the electrode surface resulting in a reduced current signal.
Example 6
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-an Au-modified electrode.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4Au modified electrode surface, incubation at 37 ℃2h to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 30min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with a concentration of 100pM was added2+The solution was added dropwise to MGCE/α -Fe prepared in example 62O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min.
The DPV peak current is measured to be 12.7 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. DNA2 was dripped onto the electrode surface and base-complementary paired with DNA1, due to the proximity of methylene blue to the electrode surface, electron transfer capacity was enhanced and current signal was increased.
Example 7
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4-Au nanocomposite ultrasoundDispersing in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-an Au-modified electrode.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating at 37 ℃ for 70min to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with a concentration of 100pM was added2+The solution was added dropwise to MGCE/α -Fe prepared in example 72O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 80 min.
The DPV peak current is measured to be 30.5 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. DNA2 was dripped onto the electrode surface and base-complementary paired with DNA1, due to the proximity of methylene blue to the electrode surface, electron transfer capacity was enhanced and current signal was increased.
Example 8
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Adding dropwise 5 μ L of BSA with volume fraction of 0.25% to the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, incubating at 4 deg.C for 30 ℃min to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with the concentration of 1. mu.M is added2+The solution was added dropwise to MGCE/α -Fe prepared in example 82O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 30 min.
The DPV peak current is measured to be 25.1 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. Dropwise adding Ni2+After the solution, the catalytic core region of DNA1 strand is activated, resulting in the cleavage of DNA2 strand and the fragment of DNA2 strand with methylene blue leaves the electrode surface, resulting in a decrease in current signal.
Example 9
The method is used for sensitively detecting the trace Ni2+The construction method of the magnetic induction self-assembly electrochemical biosensor comprises the following steps:
1) magnetic Glassy Carbon Electrode (MGCE) is prepared by using 0.3 μm and 0.05 μm Al in sequence2O3Polishing the powder to a mirror surface, then ultrasonically cleaning the powder in ultrapure water, absolute ethyl alcohol and ultrapure water in sequence, and drying the powder to obtain clean MGCE for later use;
2) will prepare the alpha-Fe prepared in example2O3/Fe3O4the-Au nano compound is ultrasonically dispersed in ultrapure water to prepare alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4-an Au nanocomposite suspension for use;
3) adding 8 mu L of alpha-Fe with the concentration of 20mg/mL2O3/Fe3O4Dripping the-Au nano-composite suspension liquid on the surface of the cleaned MGCE, and drying the liquid to obtain MGCE/alpha-Fe2O3/Fe3O4-Au modified electrode for use.
4) Adding equal volume of TCEP with the concentration of 10mM and thiol-modified DNA1 mother solution with the concentration of 100 μ M into Tris-HCl buffer solution (50mM, pH 7.4, 100mM NaCl) and mixing uniformly to prepare thiol-modified DNA1 solution with the concentration of 10 μ M for later use;
5) dripping 8 mu L of sulfhydryl modified DNA1 solution containing TCEP in 4) to MGCE/alpha-Fe2O3/Fe3O4-Au modifies the electrode surface, incubate for 2h at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4Au/DNA1 modified electrode, ready for use.
6) Dropwise adding 5 μ L of BSA with volume fraction of 0.25% onto the electrode surface, blocking non-specific sites on the electrode surface to prevent non-specific adsorption, and incubating at 4 deg.C for 30min to obtain MGCE/α -Fe2O3/Fe3O4Au/DNA1/BSA modified electrode, ready for use.
7) Diluting 100. mu.M of methylene blue modified DNA2 stock solution with Tris-HCl buffer (50mM, pH 7.4, 100mM NaCl) to obtain 10. mu.M of methylene blue modified DNA2 solution for use;
8) dripping 8 μ L of methylene blue modified DNA2 solution with the concentration of 10 μ M in 7) to MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA modified electrode surface, incubating for 60min at 37 ℃ to obtain MGCE/alpha-Fe2O3/Fe3O4-Au/DNA1/BSA/DNA2 modified electrode for use.
In the detection, 8. mu.L of Ni with the concentration of 1. mu.M is added2+The solution was added dropwise to MGCE/α -Fe prepared in example 92O3/Fe3O4Au/DNA1/BSA/DNA2 modified electrode surface and incubated at 37 ℃ for 70 min.
The DPV peak current is measured to be 9.9 muA by adopting a Differential Pulse Voltammetry (DPV) within the range of-0.1-0.7V. Dropwise adding Ni2+After solution, the catalytic core region of DNA1 strand is activated, resulting in cleavage of DNA2 strand with a subunitDNA2 strand fragments of methyl blue left the electrode surface, resulting in a decrease in the current signal.
Example 1, example 2, and example 3 were compared, and Ni was detected at a concentration of 10nM2+In example 1, alpha-Fe2O3/Fe3O4The maximum current value was 18.2. mu.A at a concentration of 20mg/mL of Au nanocomposite;
in example 2, α -Fe2O3/Fe3O4alpha-Fe at 5mg/mL of Au nanocomposite2O3/Fe3O4The Au nano-composite is too small in quantity and poor in conductivity, so that the current signal is reduced and is 14.3 muA;
in example 3, α -Fe2O3/Fe3O4alpha-Fe at a concentration of 25mg/mL of Au nanocomposite2O3/Fe3O4The amount of Au nano-composite is too large, the steric hindrance is large, and the current signal is reduced to 9.2 muA. Thus, alpha-Fe2O3/Fe3O4The Au nanocomplex concentration was 20mg/mL as the optimum concentration.
In examples 1, 4 and 5, Ni was detected at a concentration of 10. mu.M2+When the concentration of thiol-modified DNA1 was increased, the DPV current response was decreased due to the increase in the amount of DNA1 and the increase in steric hindrance, and due to the presence of a negatively charged DNA1 phosphate backbone and [ Fe (CN) ]6]3-/4-The electrostatic repulsion between the probes increases. When the concentration of the DNA1 solution reached 10. mu.M, the current value tended to level off, the concentration of the DNA1 solution continued to increase, and the current value was substantially constant, at which time the amount of DNA1 on the electrode surface reached a saturated state. Therefore, 10. mu.M was used as the optimum concentration.
In examples 1, 6 and 7, Ni was detected at a concentration of 100pM2+When the incubation time of the DNA2 is prolonged, the DPV current signal is increased and then tends to be stable, the DNA2 is dripped on the surface of the electrode and is subjected to base complementary pairing with the DNA1, and the methylene blue is close to the surface of the electrode, so that the electron transfer capacity is enhanced, and the current signal is increased; saturation was reached when the incubation of DNA2 reached 60 min. Thus, it is possible to provideThe DNA2 incubation time was 60min as the optimum time.
In examples 1, 8 and 9, Ni was detected at a concentration of 1. mu.M2+In time, the current signal gradually decreases with the increase of the shearing time, and becomes stable at 80 min. Dropwise adding Ni2+After the solution, the catalytic core region of DNA1 strand is activated, resulting in the cleavage of DNA2 strand and the fragment of DNA2 strand with methylene blue leaves the electrode surface, resulting in a decrease in current signal. When the shearing time is 30min, the shearing is not complete, and the current signal is large. Therefore, a shear time of 80min was selected as the optimum time.
SEQUENCE LISTING
<110> national energy group scientific and technological research institute Co., Ltd
Jiangsu university
<120> magnetic induction self-assembly electrochemical biosensor for sensitively detecting trace nickel ions and application thereof
<130> 20210611
<160> 1
<170> PatentIn version 3.3
<210> 1
<211> 71
<212> DNA
<213> artificial
<220>
<223> DNA1
<220>
<221> misc_feature
<222> (1)..(71)
<223> n = phosphorothioate bond
<400> 1
cnancgtcca tctctgcagt cgggtagtta aaccgacctt cagacatagt gagtagcaaa 60
aaaaaaanan a 71
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