阅读说明：本技术 一种基于TdT信号放大技术的试纸条及其制备方法 (Test strip based on TdT signal amplification technology and preparation method thereof ) 是由 颜娟 �田润 朱福琳 于 2019-06-28 设计创作，主要内容包括：本发明属于食品安全检测领域,具体涉及一种基于TdT信号放大技术的试纸条及其制备方法,试纸条的结合释放垫上包覆树枝状纳米金复合物,树枝状纳米金复合物包括纳米金-夹心适配体1-PolyN1复合物和纳米金-PolyN2复合物；反应膜包被夹心适配体2的检测限,包被与PolyN2互补的序列探针的质控线。制备包括：结合释放垫浸泡吸收含有树枝状纳米金复合物的缓冲液,干燥；含有标记链霉亲和素-生物素的夹心适配体2的溶液与含有标记链霉亲合素-生物素的与PolyN2互补的序列探针的溶液经划膜仪分别包被于反应膜上；沿层析方向将样品垫、结合释放垫、反应膜和吸收垫依次固定于背衬上。该试纸条放大检测信号,提高检测灵敏度。(The invention belongs to the field of food safety detection, and particularly relates to a test strip based on a TdT signal amplification technology and a preparation method thereof, wherein a dendritic nanogold compound is coated on a binding release pad of the test strip, and the dendritic nanogold compound comprises a nanogold-sandwich aptamer 1-PolyN1 compound and a nanogold-PolyN 2 compound; the reaction membrane coated the detection limit of sandwich aptamer2, and the quality control line of sequence probes complementary to PolyN 2. The preparation method comprises the following steps: soaking and absorbing the buffer solution containing the dendritic nano-gold compound by combining with a release pad, and drying; coating a solution containing the streptavidin-biotin-labeled sandwich aptamer2 and a solution containing a streptavidin-biotin-labeled sequence probe complementary to PolyN2 on reaction membranes respectively by a membrane scribing instrument; the sample pad, the conjugate release pad, the reaction membrane and the absorbent pad are fixed to the backing in this order in the direction of chromatography. The test strip amplifies the detection signal and improves the detection sensitivity.)

1. A test strip based on a TdT signal amplification technology is characterized in that a sample pad, a combined release pad, a reaction membrane and an absorption pad are sequentially fixed on a back backing bottom plate along a chromatography direction, and the parts of two adjacent sample pads are overlapped;

the combination release pad is coated with a dendritic nanogold compound, the dendritic nanogold compound comprises a nanogold-sandwich aptamer 1-PolyN1 compound and a nanogold-PolyN 2 compound, sandwich aptamer1 modified with a PolyN1 amplification sequence in the nanogold-sandwich aptamer 1-PolyN1 compound is radially distributed by taking nanogold particles as the center, a PolyN2 sequence in the nanogold-PolyN 2 compound is radially distributed by taking the nanogold particles as the center, and the nanogold-sandwich aptamer 1-PolyN1 compound and the nanogold-PolyN 2 compound are fixed through complementary hybridization;

PolyN1 and PolyN2 are complementary sequences, N1 is A or T;

a detection line and a quality control line are sequentially arranged on the reaction membrane along the chromatography direction, the detection line is coated with the sandwich aptamer2, and the quality control line is coated with a sequence probe complementary with the PolyN 2;

sandwich aptamer1 and sandwich aptamer2 are DNA sequences capable of capturing a target detection object.

2. The test strip of claim 1, wherein the gold nanoparticles have a particle size of 10-20 nm, the PolyN1 has a length of 100-300 bases, and the PolyN2 and the sequence probe complementary to PolyN2 have a length of 8-15 bases.

3. The method for preparing the test strip based on the TdT signal amplification technology in claim 1 or 2, which is characterized by comprising the following steps:

a. soaking the release pad to absorb the buffer solution containing the dendritic nano-gold compound, and drying to obtain the release pad coated with the dendritic nano-gold compound;

b. respectively coating the solution of the sandwich aptamer2 containing the labeled streptavidin-biotin and the solution of the sequence probe which contains the labeled streptavidin-biotin and is complementary with the PolyN2 on a reaction membrane by a membrane scribing instrument to form a detection line and a quality control line which are sequentially distributed at intervals along the chromatography direction, thus obtaining the reaction membrane of the labeled detection line and the quality control line;

c. and fixing the sample pad, the combination pad coated with the dendritic nano-gold composite, the reaction membrane of the marking detection line and the quality control line and the absorption pad on the backing in sequence along the chromatography direction, wherein the front part and the back part of the reaction membrane are overlapped.

4. The preparation method according to claim 3, wherein the step a, the step of preparing the dendritic nanogold composite comprises: and (3) hybridizing the nanogold-sandwich aptamer 1-PolyN1 compound and the nanogold-PolyN 2 compound in a hybridization system at 90 ℃ for 2min to obtain the dendritic nanogold compound.

5. The method of claim 4, wherein the nanogold-sandwich aptamer 1-PolyN1 complex is prepared by the steps of: under the mediation of TdT enzyme, the nano-gold-sandwich aptamer1 compound and dN1TP are put in a reaction buffer solution and amplified for 2h at 37 ℃, and then the nano-gold-sandwich aptamer 1-PolyN1 compound is obtained.

6. The method of claim 5, wherein the step of preparing the nanogold-sandwich aptamer1 complex comprises: uniformly mixing the sandwich aptamer1 with the colloidal gold, and reacting at 20-28 ℃ for 12-16 h; adding a PB buffer solution, and oscillating for 0.5-1 h at room temperature; then adding a PB buffer solution containing sodium chloride and pH7.4 in batches, and reacting for 12-16 h at the temperature of 20-28 ℃; and centrifugally washing with deionized water for 3-4 times to obtain the nanogold-sandwich aptamer1 compound.

7. The method according to claim 6, wherein the step of preparing the colloidal gold comprises: and adding sodium citrate into the chloroauric acid solution heated to boiling for reaction, stopping heating after the reaction is finished, and stirring overnight to obtain the colloidal gold.

8. The method according to claim 3, wherein the step b of preparing the solution containing the streptavidin-biotin-labeled sandwich aptamer2 comprises: and uniformly mixing the sandwich aptamer2 stock solution and streptavidin, and incubating at 4 ℃ for 12-16 h.

9. The method according to claim 3, wherein the step of preparing the solution containing the streptavidin-biotin-labeled sequence probe complementary to PolyN2 in step b comprises: and uniformly mixing the sequence probe stock solution complementary to the polyN2 and streptavidin, and incubating for 12-16 h at 4 ℃.

10. A detection method based on TdT signal amplification technology, characterized in that the test strip of claim 1 or 2 is used to detect a sample solution to be detected.

Technical Field

The invention belongs to the field of food safety detection, and particularly relates to a test strip based on a TdT signal amplification technology and a preparation method thereof.

Background

At present, the detection methods for enrofloxacin mainly comprise a microbiological method, a four-plate method, a photo-biosensor determination method, a high performance liquid chromatography, a thin house chromatography, a liquid chromatography-mass spectrometry combined method, a supercritical fluid extraction method, a high performance capillary electrophoresis method, surface plasmon resonance, an immunoassay method and the like. However, these methods have disadvantages in that the apparatus is expensive, the operation is complicated, and the preliminary treatment of the sample is troublesome and not instantaneous. Wherein the high performance liquid chromatography is a national standard method, and the detection limit can reach the mu g/kg level. However, the method is troublesome in pretreatment, needs professional personnel for operation, is high in cost, needs long measuring time and is not suitable for field detection.

The current test paper strip is more suitable for on-site instant detection. The chromatography technology has the advantages of high speed, strong matrix interference resistance, simple operation and the like, is a preferred method for instant detection, and is a hotspot of innovative research in related fields of food safety, medicine and health, environmental protection and the like. The test strip can realize analysis and detection without professional skills and expensive and complicated instruments and equipment. The kit is widely used for rapid detection of targets such as hormones, pathogenic microorganisms (viruses, bacteria, parasites and the like), tumor markers, prohibited drugs, veterinary drugs, pesticides, biotoxins, drugs and the like. The immunochromatographic test strip rapid detection technology is a mature technology which is very suitable for real-time and on-site detection, has a universal detection mode, complete equipment and process, short research and development time, quick product marketing and is easy for large-scale batch production.

Although the current test strip has wide application prospect and can detect the highest detection limit of national standard, the detection signal is not very obvious, and the test strips on the market are mostly antibody immunochromatography test strips, so the cost is high, the pollution is easy, and the false positive is high.

The colloidal gold chromatography test strip can avoid the defects just in time, does not need a professional instrument, only needs to be inserted for comparison, has quick low cost and simple operation, can meet the detection of most food samples, and is suitable for screening a large number of samples.

The conventional colloidal gold test strip has low sensitivity, is difficult to realize the rapid analysis of a target object, and simultaneously, along with the perfection of a supervision system and the enhancement of detection strength, the content of the target detection object in food is less and less, so that higher requirements are provided for the sensitivity of the test strip.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the test strip based on the TdT signal amplification technology, which amplifies the detection signal, obviously improves the detection sensitivity, is simple and convenient to operate, is easy to control and realizes quick detection and analysis.

The invention also provides a preparation method of the test strip based on the TdT signal amplification technology, which is simple and easy to operate, does not need professional instruments and is low in cost.

The technical scheme of the invention is that a test strip based on a TdT signal amplification technology comprises a backing bottom plate, a sample pad, a combined release pad, a reaction membrane and an absorption pad which are sequentially fixed on the backing bottom plate along a chromatography direction, and the two adjacent sample pads are partially overlapped; the combination release pad is coated with a dendritic nanogold compound, the dendritic nanogold compound comprises a nanogold-sandwich aptamer 1-PolyN1 compound and a nanogold-PolyN 2 compound, sandwich aptamer1 modified with a PolyN1 amplification sequence in the nanogold-sandwich aptamer 1-PolyN1 compound is radially distributed by taking nanogold particles as the center, a PolyN2 sequence in the nanogold-PolyN 2 compound is radially distributed by taking the nanogold particles as the center, and the nanogold-sandwich aptamer 1-PolyN1 compound and the nanogold-PolyN 2 compound are fixed through complementary hybridization; PolyN1 and PolyN2 are complementary sequences, N1 is A or T; a detection line and a quality control line are sequentially arranged on the reaction membrane along the chromatography direction, the detection line is coated with the sandwich aptamer2, and the quality control line is coated with a sequence probe complementary with the PolyN 2; sandwich aptamer1 and sandwich aptamer2 are DNA sequences capable of capturing a target detection object.

The length of the overlapped part between the sample pad and the combined release pad is 1-2 mm, and the sample pad is arranged above the combined release pad; the length of the overlapping part between the combined release pad and the reaction membrane is 1-2 mm, and the combined release pad is arranged above the reaction membrane; the length of the overlapped part between the reaction film and the absorption pad is 1-3 mm, and the absorption pad is arranged above the reaction film.

The particle size of the gold nanoparticles is 10-20 nm, preferably 15 nm; PolyN1 is 100 to 300 bases long, and PolyN2 and a sequence probe complementary to PolyN2 are 8 to 15 bases long.

Based on the affinity effect of streptavidin-biotin, the sandwich aptamer2 is coated on the reaction membrane to form a detection line, the 3' end of the sandwich aptamer2 is modified with biotin to combine with streptavidin, and the streptavidin is connected with the reaction membrane; the sequence probe complementary to the PolyN2 was coated on the reaction membrane to form a quality control line, and 3' -end-modified biotin of the sequence probe complementary to PolyN2 was bound to streptavidin, which was then linked to the reaction membrane.

When detecting enrofloxacin, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAACCCATCAGGGGGGTAGGCTAACACGGTTCGGC-3', modifying Sulfydryl (SH) at the 5 'end and modifying a PolyT amplification sequence at the 3' end;

the gene sequence of sandwich aptamer2 is: 5'-TCTCTGAGCCCGGGTTATTTCAGGGGGA-3', Biotin (Biotin) was modified at the 3' end.

When detecting potassium ions, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAAAAAGGTTGGT-3', modifying Sulfydryl (SH) at the 5 'end and modifying a PolyT amplification sequence at the 3' end; the gene sequence of sandwich aptamer2 is: 5' -GTGGTTGG-Biotin-3 ', 3' -end modified Biotin (Biotin).

When kanamycin is detected, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAAAAATGGGGGTTGAG-3', modifying Sulfydryl (SH) at the 5 'end and modifying a PolyT amplification sequence at the 3' end; the gene sequence of sandwich aptamer2 is 5'-GCTAAGCCGA-3', and Biotin (Biotin) is modified at the 3' end.

When N1 is T base, the sequence of PolyN2 is: 5'-AAAAAAAAAA-3', modifying Sulfydryl (SH) at the 5' end; sequence probes complementary to PolyN2 were: 5'-TTTTTTTTTT-3', Biotin (Biotin) was modified at the 3' end.

When N1 is A base, the sequence of PolyN2 is: 5'-TTTTTTTTTT-3', modifying Sulfydryl (SH) at the 5' end; sequence probes complementary to PolyN2 were: 5'-AAAAAAAAAA-3', Biotin (Biotin) was modified at the 3' end.

The preparation method of the test strip based on the TDT signal amplification technology comprises the following steps:

a. soaking the release pad to absorb the buffer solution containing the dendritic nano-gold compound, and drying to obtain the combined release pad coated with the dendritic nano-gold compound;

b. respectively coating the solution of the sandwich aptamer2 containing the labeled streptavidin-biotin and the solution of the sequence probe which contains the labeled streptavidin-biotin and is complementary with the PolyN2 on a reaction membrane by a membrane scribing instrument to form a detection line and a quality control line which are sequentially distributed at intervals along the chromatography direction, thus obtaining the reaction membrane of the labeled detection line and the quality control line;

c. and fixing the sample pad, the combination release pad coated with the dendritic nano-gold composite, the reaction membrane for the marking detection line and the quality control line and the absorption pad on the backing in sequence along the chromatography direction, wherein the front part and the back part of the reaction membrane are overlapped.

Step a, the preparation of the dendritic nano-gold compound comprises the following steps: and (3) hybridizing the nanogold-sandwich aptamer 1-PolyN1 compound and the nanogold-PolyN 2 compound in a hybridization system at 90 ℃ for 2min to obtain the dendritic nanogold compound. In a hybridization system, the concentration of the nanogold-sandwich aptamer 1-PolyN1 complex is 1-3 nM, preferably 2 nM; the molar concentration ratio of the nanogold-sandwich aptamer 1-polyN1 complex to the nanogold-polyN 2 complex is 1: 2-4, preferably 1: 2.5. the hybridization system included deionized water, dN1TP, reaction buffer and TdT. N1 is A or T.

The amplified polyN1 sequence of the nanogold-sandwich aptamer 1-PolyN1 complex is complementarily hybridized and combined with the PolyN2 sequence of the nanogold-PolyN 2 complex, and the nanogold-PolyN 2 complex is fixedly combined on the nanogold-sandwich aptamer 1-PolyN1 complex.

The preparation method of the nanogold-sandwich aptamer 1-PolyN1 complex comprises the following steps: under the mediation of TdT enzyme, the nano-gold-sandwich aptamer1 compound and dN1TP are put in a reaction buffer solution and amplified for 2h at 37 ℃, and then the nano-gold-sandwich aptamer 1-PolyN1 compound is obtained. N1 is A or T, the number of amplified N1 bases is 100-300 bases, preferably 200-260 bp.

The amplification heat preservation mode is metal bath or water bath.

In the reaction buffer solution, the concentration of the nanogold-sandwich aptamer1 complex is 3-6 nM, and 4nM is preferable.

The preparation method of the nanogold-sandwich aptamer1 complex comprises the following steps: uniformly mixing the sandwich aptamer1 with the colloidal gold, and reacting at 20-28 ℃ for 12-16 h; adding a PB buffer solution, and oscillating for 0.5-1 h at room temperature; then adding a PB buffer solution containing sodium chloride and pH7.4 in batches, and reacting for 12-16 h at the temperature of 20-28 ℃; and centrifugally washing with deionized water for 3-4 times to obtain the nanogold-sandwich aptamer1 compound.

When detecting enrofloxacin, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAACCCATCAGGGGGGTAGGCTAACACGGTTCGGC-3', modifying Sulfydryl (SH) at the 5' end;

when detecting potassium ions, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAAAAAGGTTGGT-3', modifying Sulfydryl (SH) at the 5' end;

when kanamycin is detected, the gene sequence of the sandwich aptamer1 is as follows: 5'-AAAAAAAAAATGGGGGTTGAG-3', modifying Sulfydryl (SH) at the 5' end.

In the uniform mixing system of the sandwich aptamer1 and the colloidal gold, the concentration of the sandwich aptamer1 is 90-100 mM. The particle size of the gold nanoparticles in the colloidal gold is 10-20 nm, preferably 15 nm.

Preferably 25 ℃ for 12 h. The heat preservation mode is metal bath or water bath.

The concentration of PB in the system added with the PB buffer solution and uniformly shaken is the same as that of PB in the subsequently added PB buffer solution containing sodium chloride and pH7.4, and the concentration of PB in the system is 0.01M. The added PB buffer solution plays a role in buffering, and the salinity tolerance of the colloidal gold is increased.

Adding a system formed by PB buffer solution containing sodium chloride and with the pH value of 7.4, wherein the concentration of the sodium chloride is 0.14-0.16M, and preferably 0.15M; the concentration of PB is 9-11 mM, preferably 9.5-10.5 mM. And the PB buffer solution containing sodium chloride is an aging solution with pH of 7.4, so that the DNA adsorbed on the gold nanoparticles stands (the aging solution has the effect of reducing electrostatic repulsion between the DNA and the nanogold, so that the DNA on the nanogold stands, the incubation quantity of the DNA on the nanogold is increased, and after standing, subsequent amplification and hybridization can be carried out smoothly, and the subsequent amplification and hybridization can be carried out smoothly. The slow addition of the sodium chloride containing PB buffer at ph7.4 in portions allowed the ion concentration to be slowly increased in the solution to avoid agglomeration of the colloidal gold.

The conditions of each deionized water centrifugal washing are as follows: centrifuging at 12000rpm for 20min at 4 deg.C to avoid agglomeration of colloidal gold.

Step b, the preparation step of the solution containing the streptavidin-biotin labeled sandwich aptamer2 comprises: and uniformly mixing the sandwich aptamer2 stock solution and streptavidin, and incubating at 4 ℃ for 12-16 h. The concentration of the sandwich aptamer2 is 65-75 mu M, preferably 66-67 mu M; the molar ratio of the sandwich aptamer2 to the streptavidin is 5-7: 1, preferably 6-6.5: 1.

when detecting enrofloxacin, the gene sequence of the sandwich aptamer2 is as follows: 5'-TCTCTGAGCCCGGGTTATTTCAGGGGGA-3', Biotin (Biotin) modified at the 3' end;

when detecting potassium ions, the gene sequence of the sandwich aptamer2 is as follows: 5' -GTGGTTGG-Biotin-3 ', 3' -end modified Biotin (Biotin);

when kanamycin is detected, the gene sequence of the sandwich aptamer2 is 5'-GCTAAGCCGA-3', and Biotin (Biotin) is modified at the 3' end.

Step b, the preparation of a solution containing streptavidin-biotin labeled sequence probes complementary to PolyN2 comprises: and uniformly mixing the sequence probe stock solution complementary with the PolyN2 and streptavidin, and incubating for 12-16 h at 4 ℃. The concentration of the sequence probe complementary to the PolyN2 is 65-75 mu M, preferably 66-67 mu M; the molar ratio of the sequence probe complementary to the PolyN2 to the streptavidin is 5-7: 1, preferably 6-6.5: 1.

when N1 is T base, the sequence probe complementary to PolyN2 is: 5'-TTTTTTTTTT-3', Biotin (Biotin) was modified at the 3' end.

When N1 is A base, the sequence probe complementary to PolyN2 is: 5'-AAAAAAAAAA-3', Biotin (Biotin) was modified at the 3' end.

The preparation method of the nanogold-PolyN 2 compound comprises the following steps: mixing PolyN2 and colloidal gold uniformly, and reacting for 12-16 h at 20-28 ℃; adding a PB buffer solution, and oscillating for 0.5-1 h at room temperature; then adding a PB buffer solution containing sodium chloride and pH7.4 in batches, and reacting for 12-16 h at the temperature of 20-28 ℃; and centrifugally washing with deionized water for 3-4 times to obtain the nanogold-sandwich aptamer1 compound.

When N1 is T base, the sequence of PolyN2 is: 5'-AAAAAAAAAA-3', modifying Sulfydryl (SH) at the 5' end.

When N1 is A base, the sequence of PolyN2 is: 5'-TTTTTTTTTT-3', modifying Sulfydryl (SH) at the 5' end.

In the uniform mixing system of the PolyN2 and the colloidal gold, the concentration of the PolyN2 is 90-100 mM. The particle size of the gold nanoparticles in the colloidal gold is 10-20 nm, preferably 15 nm.

Preferably 25 ℃ for 12 h. The heat preservation mode is metal bath or water bath.

The preparation method of the colloidal gold comprises the following steps: and adding sodium citrate into the chloroauric acid solution heated to boiling for reaction, stopping heating after the reaction is finished, and stirring overnight to obtain the colloidal gold. Specifically, a sodium citrate solution is added to a chloroauric acid solution heated to boiling. The prepared colloidal gold is refrigerated at 4 ℃. Preferably, the stirring is vigorous and then overnight.

In the reaction system, the concentration of the chloroauric acid is 0.09-0.15 g/L, preferably 0.095-0.1 g/L, and more preferably 0.096-0.097 g/L; the mass ratio of the chloroauric acid to the sodium citrate is 1: 2.5-5, preferably 1: 3.5. the reaction time is 15-30 min, preferably 20 min.

The heating mode is oil bath, water bath or metal bath.

The particle size of the nano gold particles is 10-20 nm, preferably 15 nm.

C, the length of the overlapped part between the sample pad and the combined release pad is 1-2 mm, and the sample pad is arranged above the combined release pad; the length of the overlapping part between the combined release pad and the reaction membrane is 1-2 mm, and the combined release pad is arranged above the reaction membrane; the length of the overlapped part between the reaction film and the absorption pad is 1-3 mm, and the absorption pad is arranged above the reaction film.

The sample pad of the test strip based on the TdT signal amplification technology is placed in a sample solution to be detected, such as a stock solution or an extracting solution of a sample to be detected, or the stock solution or the extracting solution of the sample to be detected is dripped on the sample pad of the test strip based on the TdT signal amplification technology, so that the chromatographic detection of the sample to be detected based on the aptamer is performed, the operation is simple and convenient, the anti-interference capability is high, the specificity is good, the sensitivity is high, and the qualitative and/or quantitative determination can be completed quickly and accurately in real time; professional instruments are not needed, and the preparation and detection cost is low; the method meets the detection of samples in most fields of food, medicine, environment and the like, and has wide application range.

The detection method based on the TdT signal amplification technology utilizes the test strip based on the TdT signal amplification technology prepared by the invention to detect the sample liquid to be detected. Specifically, the sample pad of the test strip based on the TdT signal amplification technology prepared by the present invention is placed in a sample solution to be tested, such as a stock solution or an extract solution of a sample to be tested, or the stock solution or the extract solution of the sample to be tested is dropped on the sample pad of the test strip based on the TdT signal amplification technology prepared by the present invention.

Compared with the prior art, the invention has the advantages that: aiming at the problem that the signal of the existing gold-labeled test strip cannot meet the market detection requirement easily, the invention provides the test strip based on the TdT signal amplification technology and the preparation method thereof, through the aptamer1 and the aptamer2 which can specifically identify a sample to be detected, the sandwich method principle is adopted, the aptamer1 is incubated with nanogold through a gold-sulfur bond, a product obtained after amplification of TdT enzyme is subjected to complementary hybridization with Au-poly N to prepare a dendritic nanogold compound, the dendritic nanogold compound is used as a signal amplification probe to replace a conventional Au-aptamer1 probe, the detection signal is amplified, the detection sensitivity of the test strip is obviously improved, high-sensitivity detection is realized, and the test strip has the characteristics of simplicity, rapidness, easy result identification and the like.

According to the test strip based on the TdT signal amplification technology, amplification can be carried out at 37 ℃ by the action principle of terminal transferase (TdT), amplification is carried out without other large-scale instruments, an aptamer obtained after aptamer terminal amplification is hybridized with polyA connected with nanogold, and then signal amplification is realized on the test strip. Compared with the prior art, the detection signal is more obvious.

Drawings

Fig. 1 is a schematic structural diagram of the dendritic nanogold composite of the invention.

Fig. 2 is a schematic diagram of a test strip structure based on a TdT signal amplification technology.

FIG. 3 is a diagram showing the test structure of the test strip based on the TdT signal amplification technique of the present invention, which shows the results of the negative and the invalid tests of the control example and the test strip of the present invention.

FIG. 4 is a standard curve diagram of the test strip for detecting enrofloxacin based on the TdT signal amplification technology in example 1. The X axis is the logarithm of the concentration of the enrofloxacin standard solution, and the Y axis is the visual intensity of the T line.

FIG. 5 is a standard curve diagram of a standard solution for detecting enrofloxacin by using a test strip of unamplified nano gold complex (Au-aptamer 1). The X axis is the logarithm of the concentration of the enrofloxacin standard solution, and the Y axis is the visual intensity of the T line.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.