CN113310958A - Preparation method of hierarchical porous metal organic framework chiral sensing probe, probe obtained by preparation method and application of probe - Google Patents

Abstract

The invention relates to a preparation method of a hierarchical porous metal organic framework chiral sensing probe, which comprises the steps of providing a hierarchical porous metal organic framework microsphere with a regular pore channel structure; fixing amino acid oxidase on the hierarchical porous metal organic framework microspheres to obtain hierarchical porous metal organic framework microspheres fixed with the enzyme, wherein the amino acid oxidase is loaded in pore channels of the hierarchical porous metal organic framework microspheres through adsorption; and (3) fixing the fluorescent molecules on the hierarchical porous metal organic framework microspheres fixed with the enzyme to obtain the hierarchical porous metal organic framework chiral sensing probe, wherein the fluorescent molecules are loaded in the pore channels of the hierarchical porous metal organic framework microspheres through adsorption. The invention also provides a hierarchical porous metal organic framework chiral sensing probe obtained by the preparation method and application thereof. The invention can identify and analyze the content of amino acid with high sensitivity and high specificity by fixing different amino acid oxidase as a chiral identification center.

Description

Preparation method of hierarchical porous metal organic framework chiral sensing probe, probe obtained by preparation method and application of probe

Technical Field

The invention relates to enzyme immobilization and analytical chemistry, in particular to a preparation method of a hierarchical porous metal organic framework chiral sensing probe, the probe obtained by the method and application of the probe.

Background

Amino acids are among the most predominant and important chiral compounds in nature (Angew. chem. int. Ed.2017,56, 7276-. L-amino acids and D-amino acids are not mutually exclusive and typically coexist in non-racemic mixtures. In mammals and humans, amino acids are usually present in free form or in the form of proteins. In general, most amino acids in organisms and nature exist in L form, while the abundant presence of D form usually indicates negative symptoms, senescence or disease (ACS appl. The production and racemization of Amino Acids are of great value in life sciences (Amino Acids 2012,42, 1553-1582). Amino acid enantiomers are also widely used as chiral sources of asymmetry. The total amount of amino acids in the central nervous system, as well as the ratio of enantiomers, often exhibit different biological functions, playing a crucial role in human physiology and pathology, and the expression levels of specific chiral amino acids in biological systems are often associated with early stages of many diseases, such as chronic kidney disease, alzheimer's disease and cancer (j.am.chem.soc.2016,138, 12099-12111). Therefore, the method has important significance for rapidly and accurately carrying out chiral analysis on the amino acid. To date, there are various methods for selective recognition and detection of amino acid enantiomers, including chromatography, capillary electrophoresis, fluorescence, circular dichroism, and the like (biosens. bioelectronic. 2020,151, 111971). However, conventional chromatography, capillary electrophoresis, and the like for enantiomer identification and separation are effective for chiral detection of amino acids, but the test is expensive, the procedures and steps required for the test are cumbersome, and the detection time is long. The fluorescent sensor can avoid the defects and can quickly, effectively, simply and conveniently detect the chiral amino acid. The method is suitable for high-throughput screening and real-time imaging of amino acid enantiomers in biological samples. However, the design of chiral binding/reaction sites is a key and enormous challenge for enantioselective recognition of fluorescent probes.

To achieve a stereochemical interaction between a substrate and a probe molecule requires a complex and precise chemical synthesis process. Meanwhile, fluorescent probes rarely simultaneously enantioselectively and chemoselectively recognize specific amino acids and may be interfered by other similar biochemical molecules. Therefore, the development of a general fluorescence sensing strategy suitable for broad-spectrum detection of chiral amino acids, whether enantioselectivity or chemoselectivity, is of great significance.

Disclosure of Invention

In order to realize enantioselective and chemoselective recognition of amino acid by a fluorescent probe, the invention provides a preparation method of a hierarchical porous metal organic framework chiral sensing probe, the probe obtained by the preparation method and application of the probe.

The preparation method of the hierarchical porous metal organic framework chiral sensing probe comprises the following steps: s1, providing a hierarchical porous metal organic framework microsphere (HPUiO-66) which has a regular pore channel structure; s2, fixing Amino Acid Oxidase (AAO) on the hierarchical porous metal organic framework microsphere (HPUiO-66) to obtain the hierarchical porous metal organic framework microsphere (AAO @ HPUiO-66) with the immobilized enzyme, wherein the Amino Acid Oxidase (AAO) is loaded in the pore canal of the hierarchical porous metal organic framework microsphere (HPUiO-66) through adsorption; s3, fixing a fluorescent molecule (PF) on the hierarchical porous metal organic framework microsphere (AAO @ HPUiO-66) immobilized with enzyme to obtain the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66), wherein the fluorescent molecule (PF) is loaded in the pore channel of the hierarchical porous metal organic framework microsphere (HPUiO-66) through adsorption.

Preferably, the Amino Acid Oxidase (AAO) is an amino acid oxidase having a chiral recognition function. More preferably, the Amino Acid Oxidase (AAO) is at least one selected from the group consisting of L-amino acid oxidase, L-glutamate oxidase and L-tryptophan oxidase.

Preferably, the fluorescent molecule (PF) is of H₂O₂A responsive fluorescent molecule. More preferably, the fluorescent molecule (PF) is 3-Oxo-3',6' -bis (4,4,5, 5-tetramethyl-1, 3, 2-dioxaborolan-2-yl) -3H-spiro [ isobenzofuran-1, 9' -ton]-6-carboxylic acid.

Preferably, the step S1 includes: s11, using Block copolymer PEO₁₀₆PPO₇₀PEO₁₀₆(F127) Providing a Metal Organic Framework (MOFs) precursor solution for a template agent; s12, generating a hierarchical porous metal organic framework precursor (HPUiO-66-as) through solvothermal generation; s13, by activatingAnd (4) carrying out template formation and template removal to obtain the large-aperture hierarchical porous metal organic framework microsphere (HPUiO-66). More preferably, the pore size of the hierarchical porous metal organic framework microsphere (HPUiO-66) is 8-10 nm. In a preferred embodiment, the pore size of the hierarchical porous metal organic framework microsphere (HPUiO-66) is 9.2 nm. More preferably, the block copolymer F127 is dissolved in deionized water under stirring, sodium perchlorate and acetic acid are added, and ultrasonic dissolution is carried out; then adding ammonium ceric nitrate and terephthalic acid, and stirring and dispersing; stirring and reacting for 20min at 60 ℃; and obtaining the hierarchical porous metal organic framework microsphere (HPUiO-66) after centrifugal separation, washing, activation and drying. Specifically, 150mg of F127 was dissolved in 9mL of deionized water, followed by 750mg of NaClO₄·H₂O and 450 mu L of acetic acid are ultrasonically dispersed in the F127 solution; subsequently, 249mg of terephthalic acid and 274mg of cerium ammonium nitrate were dispersed in the above solution with stirring; then, the mixed liquid is stirred and reacted for 20 minutes at the temperature of 60 ℃; centrifuging the mixture to obtain a solid product; and then washing the material with deionized water, N-dimethylformamide and absolute ethyl alcohol, soaking the material in the absolute ethyl alcohol at 60 ℃ for 48 hours, continuously replacing the ethyl alcohol during the soaking, completely removing F127 in pore channels of the material, and finally obtaining the hierarchical porous metal organic framework microsphere (HPUiO-66) with the size of 600 nm-1000 nm after washing and drying. The invention uses the block copolymer F127 as a template and uses

The Hofmeister salt-soluble mediated effect synthesizes the hierarchical porous metal organic framework microsphere (HPUiO-66) with large aperture of about 9nm, and the synthesis steps are simple and the preparation period is short.

Preferably, the step S2 includes: dissolving Amino Acid Oxidase (AAO) with a chiral catalytic function in deionized water, adding hierarchical porous metal organic framework microspheres (HPUiO-66), stirring for 4h at 25 ℃, and collecting the hierarchical porous metal organic framework microspheres (AAO @ HPUiO-66) immobilized with the enzyme by centrifugation.

Preferably, the step S3 includes: dissolving a fluorescent molecule (PF) in deionized water, adding hierarchical porous metal organic framework microspheres (AAO @ HPUiO-66) immobilized with enzyme, stirring for 30min at 25 ℃ in a dark place, and collecting hierarchical porous metal organic framework chiral sensing probes (AAO & PF @ HPUiO-66) by centrifugation.

In the invention, Amino Acid Oxidase (AAO) is natural enzyme, fluorescent molecule (PF) is fluorescent micromolecule, and the amino acid oxidase and the fluorescent micromolecule are sequentially fixed in mesoporous channels of hierarchical porous metal organic framework microspheres (HPUiO-66) by a mild after-loading method to prepare a series of fluorescent probes with high specific sensing performance. Specifically, at room temperature, Amino Acid Oxidase (AAO) and fluorescent molecule (PF) are sequentially fixed in hierarchical mesopores of hierarchical porous metal organic framework microspheres (HPUiO-66) in a post-adsorption mode to synthesize a hierarchical porous metal organic framework chiral sensing probe (AAO)&PF @ HPUiO-66), Amino Acid Oxidase (AAO) loading was 151mg g^-1The immobilized amount of fluorescent molecule (PF) was 374mg g^-1The preparation process has mild conditions and simple and convenient operation.

The invention also provides a hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66) obtained by the preparation method, wherein Amino Acid Oxidase (AAO) and fluorescent molecule (PF) are coupled on a carrier of a hierarchical porous metal organic framework microsphere (HPUiO-66).

The invention also provides application of the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66), which has chiral sensing response on amino acid. Accordingly, the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66) is used for identifying chiral amino acid through a cascade response system constructed by Amino Acid Oxidase (AAO) and fluorescent molecule (PF).

Preferably, the amino acid is phenylalanine, leucine, methionine, tryptophan, histidine, isoleucine, tyrosine, and/or cysteine.

Preferably, the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66) exhibits enhanced fluorescence for the L-enantiomer of an amino acid, but no response to the D-enantiomer of the amino acid.

Preferably, the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66) is dispersed in HEPES buffer solution to form a probe solution, an amino acid solution is added into the probe solution for incubation, and the fluorescence intensity is measured by a fluorescence spectrometer.

Preferably, in the concentration range of 0-100 mu M of the amino acid solution, the amino acid is subjected to linear analysis by using a hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66). Accordingly, the hierarchical porous metal organic framework chiral sensing probe (AAO & PF @ HPUiO-66) can be used for quantitative analysis of chiral amino acids.

Preferably, the lower limit of detection of the amino acid solution is 0.38. mu.M to 0.44. mu.M.

According to the invention, the enzyme and the fluorescent molecules are sequentially loaded into the hierarchical porous metal organic framework in a post-fixing mode, the exoskeleton made of the firm metal organic framework material protects the protein structure of the enzyme, the stability of the enzyme is improved, and the hierarchical porous structure also enables the fluorescent molecules to be separately fixed on metal nodes, so that aggregation and quenching of the fluorescent molecules are avoided; its larger pore size and high porosity are favorable to quick diffusion and reaction of matter, and in the course of detection it utilizes cascade reaction, i.e. oxidation deamination reaction between L-amino acid oxidase and L-amino acid to produce H₂O₂Followed by H₂O₂The chiral amino acid is subjected to ring-opening reaction with a fluorescent molecule PF to generate strong fluorescence, and a fluorescence spectrophotometer is used for detection, so that the aim of chiral amino acid detection is fulfilled. The preparation method has high ductility, realizes chiral recognition and quantitative analysis of different amino acids by loading different natural amino acid oxidases, provides a simple and effective way for designing enantioselective and chemoselective fluorescence sensors, and has important significance for realizing rapid and accurate chiral recognition and quantitative analysis of amino acids. According to the invention, different amino acid oxidases are fixed as chiral recognition centers, so that the chiral amino acid can be recognized and content analyzed with high sensitivity and high specificity. The method has the advantages of convenient synthesis method, mild preparation conditions, convenient instrument operation, low technical requirement, high analysis sensitivity, strong specificity and excellent anti-interference capability. The hierarchical porous metal organic framework chiral sensing probe can be used for detecting 8 amino groups in HEPES (high efficiency particulate ES) buffer solutionThe L-enantiomer of acid, namely phenylalanine, leucine, methionine, tryptophan, histidine, isoleucine, tyrosine and cysteine is specifically and selectively identified, the L-amino acid can be linearly measured in a low concentration range of less than 100 mu M, and the L-enantiomer has the advantages of low detection limit (0.38 mu M-0.44 mu M), high sensitivity, strong specificity and excellent anti-interference capability; and the detection instrument is simple, the operation is convenient, and the technical requirement is low. The strategy provided by the invention has universal applicability, and can simply replace L-amino acid oxidase with L-glutamate oxidase, thereby realizing selective recognition and content analysis of free L-glutamate in the aqueous phase. And also has high specificity, low detection limit and strong anti-interference capability.

Drawings

FIG. 1 is a process flow diagram of a method for preparing a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 2 is a nuclear magnetic resonance hydrogen spectrum of a fluorescent molecule (PF) of a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 3 is a graph of adsorption kinetics of a hierarchical porous metal organic framework chiral sensing probe when loaded with L-amino acid oxidase L-AAO and a fluorescent molecule PF according to the present invention;

FIG. 4 is an XRD pattern of a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 5 is a scanning electron microscope image of a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 6 is a nitrogen adsorption diagram and its pore size distribution diagram of a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 7 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe to phenylalanine according to the present invention;

FIG. 8 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe to leucine according to the present invention;

FIG. 9 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe to methionine according to the present invention;

FIG. 10 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe according to the present invention to tryptophan;

FIG. 11 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe to histidine according to the present invention;

FIG. 12 is two enantiomeric kinetic response profiles of a hierarchical porous metal organic framework chiral sensing probe for isoleucine according to the present invention;

FIG. 13 is a graph of two enantiomeric dynamic response of a hierarchical porous metal organic framework chiral sensing probe to tyrosine, according to the present invention;

FIG. 14 is two enantiomeric kinetic response spectra of a hierarchical porous metal organic framework chiral sensing probe according to the present invention for cysteine;

FIG. 15 is a fluorescence titration spectrum of a hierarchical porous metal organic framework chiral sensing probe according to the present invention for the L-enantiomer of phenylalanine;

FIG. 16 is a fluorescence titration spectrum of a hierarchical porous metal organic framework chiral sensing probe according to the present invention for the L-enantiomer of leucine;

FIG. 17 is a fluorescence titration spectrum of a hierarchical porous metal organic framework chiral sensing probe according to the present invention for the L-enantiomer of methionine;

FIG. 18 is a fluorescence titration spectrum of L-enantiomer of tryptophan with a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 19 is a fluorescence titration spectrum of L-enantiomer of histidine with a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 20 is a fluorescence titration spectrum of a hierarchical porous metal organic framework chiral sensing probe for the L-enantiomer of isoleucine according to the present invention;

FIG. 21 is a fluorescence titration spectrum of a hierarchical porous metal organic framework chiral sensing probe according to the present invention for the L-enantiomer of tyrosine;

FIG. 22 is a fluorescence titration spectrum of L-enantiomer of cysteine with a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 23 is an anti-interference, selective detection result image of a hierarchical porous metal organic framework chiral sensing probe according to the present invention;

FIG. 24 is a graph showing fluorescence kinetics curves of two enantiomeric responses of a hierarchical porous metal organic framework chiral sensing probe to glutamic acid, a fluorescence titration spectrum for L-glutamic acid, and a selective detection result image for L-glutamic acid according to the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1, the preparation method of the hierarchical porous metal organic framework chiral sensing probe according to the present invention comprises the steps of: providing MOFs precursor solution; generating a hierarchical porous UiO-66 precursor (HPUiO-66-as) by solvothermal generation; obtaining graded porous UiO-66 nano particles (HPUiO-66) by activating and removing a template; immobilizing L-amino acid oxidase (L-AAO) onto the hierarchical porous UiO-66 nanoparticles (HPUiO-66) to obtain an enzyme-immobilized hierarchical porous metal organic framework (L-AAO @ HPUiO-66), wherein the L-amino acid oxidase (L-AAO) is loaded in the pores of the hierarchical porous UiO-66 nanoparticles (HPUiO-66) by adsorption; and (2) fixing a fluorescent molecule (PF) on a hierarchical porous metal organic framework (L-AAO @ HPUiO-66) immobilized with enzyme to obtain a hierarchical porous metal organic framework chiral sensing probe (L-AAO & PF @ HPUiO-66), wherein the fluorescent molecule (PF) is loaded in a pore channel of a hierarchical porous UiO-66 nanoparticle (HPUiO-66) through adsorption.

Example 1

1.1 Synthesis of fluorescent molecules (PF)

1,2, 4-benzenetricarboxylic acid having a mass of 3.15g and 3-bromophenol having a mass of 5.19g, and methanesulfonic acid having a volume amount of 15mL were added to a three-necked flask. And heated at 135 deg.c under reflux for 72 hours, after cooling naturally, the mixture was added to 120mL of ice deionized water, and stirred to give a green solid, and then the resulting solid was collected by vacuum filtration. And a mixed reagent of pyridine and acetic anhydride (v/v ═ 1:3) washed several times and recrystallized 3 times at 100 ℃ with a mixed reagent of acetic anhydride and pyridine (v/v ═ 2:1) and then with a concentration of 1mol L^-1The hydrochloric acid washing several times, finally, at 85 degrees C through vacuum drying for 12h get white solid powder.

400mg of bis (pinacol) diboron, 200mg of the above solid powder, 98.9mg of Pd (dppf) Cl₂And anhydrous potassium acetate having a mass of 510mg were charged into a dry three-necked flask, and the system was evacuated and then charged with nitrogen again. This process is repeated at least three times. Then, anhydrous, degassed N, N-dimethylformamide was added in a volume amount of 5 mL. The mixed solution was then stirred at room temperature for 5 minutes and then heated at 85 ℃ under reflux for 3 hours. After the reaction was finished and cooled naturally, the solvent was removed by rotary evaporation, and the crude product was purified by passing through a silica gel column equilibrated with dichloromethane, and subjected to gradient washing with a mixed solvent of dichloromethane and methanol, then a minimum amount of anhydrous ether was added dropwise to precipitate a light brown solid, and washed several times with anhydrous ether, and finally dried in vacuo at 40 ℃ for 12 hours to obtain a bone white Powder (PF).

The nmr hydrogen spectrum of fig. 2 demonstrates the successful synthesis of PF.

1.2 Synthesis of hierarchical porous UiO-66 nanoparticles

F127, 150mg in mass, was dissolved in 9mL of deionized water at room temperature, followed by NaClO, 750mg in mass₄·H₂O and acetic acid in a volume of 450. mu.L were ultrasonically dispersed in the F127 solution described above. Subsequently, terephthalic acid having a mass of 249mg and cerium ammonium nitrate having a mass of 274mg were dispersed in the above solution with stirring. Then, the mixed liquid was stirred at 60 ℃ to react for 20 minutes. The mixture was centrifuged to give a solid product. And then washing the material with deionized water, N-dimethylformamide and absolute ethyl alcohol, soaking the material in the absolute ethyl alcohol at 60 ℃ for 48h, continuously replacing the ethyl alcohol during the soaking, completely removing F127 in pore channels of the material, and finally obtaining the hierarchical porous metal organic framework material (HPUiO-66) with the size of 700 nm-800 nm after washing and drying.

1.3 immobilization of L-amino acid oxidase (L-AAO) to obtain immobilized L-amino acid oxidaseHierarchical porous Metal organic frameworks (L-AAO @) of enzymes HPUiO-66)

L-amino acid oxidase having a mass of 2.5mg was dissolved in 2.5mL of deionized water, and then HPUiO-66 nanoparticles having a mass of 2.5mg were dispersed in the above enzyme solution. And stirred at 25 ℃ for 4 hours. The enzyme-immobilized HPUiO-66 material (L-AAO @ HPUiO-66) was collected by centrifugation and washed several times with deionized water to remove the enzyme adsorbed on the surface of HPUiO-66.

1.4 immobilization of fluorescent molecule (PF) to obtain hierarchical porous Metal organic framework chiral sensing Probe (L-AAO)&PF@ HPUiO-66)

The fluorescent molecule PF with a mass of 5mg was dissolved in 5mL of deionized water, and then L-AAO @ HPUiO-66 nanoparticles with a mass of 2.5mg were dispersed in the above solution. And stirred at 25 ℃ for 30min in the dark. The HPUiO-66 material (L-AAO & PF @ HPUiO-66) immobilized with enzyme and fluorescent molecule was collected by centrifugation and washed several times with deionized water to remove PF adsorbed on the surface.

FIG. 3 is a graph showing the adsorption kinetics of L-amino acid oxidase L-AAO and fluorescent molecule PF. FIG. 4 is an XRD pattern of HPUiO-66 and L-AAO & PF @ HPUiO-66, and it can be seen that both hierarchical porous metal organic framework material HPUiO-66 and hierarchical porous metal organic framework chiral probe material L-AAO & PF @ HPUiO-66 maintain characteristic peaks and high crystallinity of UiO-66 crystal; FIG. 5 is a scanning electron microscope image of HPUiO-66(A) and L-AAO & PF @ HPUiO-66(B), which shows that HPUiO-66 and L-AAO & PF @ HPUiO-66 both have regular channel structures and the particle size is 700 nm-800 nm. FIG. 6 is a nitrogen adsorption-desorption curve and pore size distribution for HPUiO-66 and L-AAO & PF @ HPUiO-66. It can be seen that the specific surface area, porosity and pore size of the L-AAO & PF @ HPUiO-66 are greatly reduced compared with the HPUiO-66. It was confirmed that L-AAO and PF were loaded into the channels of HPUiO-66, rather than adsorbed on the surface. The cell structure parameters for HPUiO-66 and L-AAO & PF @ HPUiO-66 are given in Table 1 below.

TABLE 1

Sample (I)	Pore size (nm)	Pore volume (cm)3/g)	Specific surface area (m)2/g)
				HPUiO-66	9.2	0.626	1217.3
L-AAO&PF@HPUiO-66	6.7	0.142	262.0

1.5 hierarchical porous metal organic framework chiral sensing probe (L-AAO)&PF @ HPUiO-66) chirality of amino acids Identification

The mass is 5mg of L-AAO&PF @ HPUiO-66 Probe Material dispersed in 50mL HEPES buffer (20mM, pH 7.4) to form 100mg L^-1The probe solution of (4), 100. mu.L of an L/D-amino acid solution (2mM L)^-1) The resulting mixture was added to 1.9mL of the above probe solution, and the reaction was incubated at 37 ℃ under exclusion of light. Then, the fluorescence intensity of the mixture at λ 520nm was detected at fixed time intervals. The L-AAO can be seen from the images of FIGS. 7-14&The PF @ hpuo-66 probe has a chiral sensory response to 8 amino acids (phenylalanine, leucine, methionine, tryptophan, histidine, isoleucine, tyrosine, cysteine). Shows an increase in fluorescence for the L-enantiomer, but not for the corresponding D-enantiomerAnd (6) responding.

1.6 hierarchical porous metal organic framework chiral sensing probe (L-AAO)&PF @ HPUiO-66) content of amino acids Analysis of

The mass is 5mg of L-AAO&PF @ HPUiO-66 Probe Material dispersed in 50mL HEPES buffer (20mM, pH 7.4) to form 100mg L^-1The probe solution of (1) was added to 1.9mL of the above probe solution with 100 μ L of L-amino acid solutions of different concentrations, the reaction was incubated at 37 ℃ in the absence of light until equilibrium was reached, and the fluorescence intensity of the above reaction mixture at λ 520nm was measured by a fluorescence spectrometer. As can be seen from the images of FIGS. 15-22, when the L-enantiomers of the above 8 amino acids are added, the fluorescence intensity of the probe solution is regularly enhanced with the increase of the concentration of the L-amino acid, and the probe can perform linear analysis on the L-amino acid within the concentration range of 0-100. mu.M, with a correlation coefficient as high as 0.99 and a lower detection limit LOD (0.38. mu.M-0.44. mu.M). Table 2 below gives a summary of the fluorescence detection characteristics of the probes for the above 8L-amino acids.

TABLE 2

1.7 hierarchical porous Metal organic framework chiral sensing Probe (L-AAO)&PF @ HPUiO-66) in interfering ion neutralization Fluorescence sensing detection of amino acids in the presence of compounds

Will interfere with the substance (Na)⁺，K⁺，Mg²⁺，Al³⁺，Br^-，Cl^-，HCO₃ ^-，NO₂ ^-Glucose (GLU), Glutathione (GSH), Cholesterol (CHOL)) were dissolved in the probe solution at a concentration of 100. mu.M, and the probe solution was subjected to fluorescence measurement before and after addition of 100. mu. L L-phenylalanine (100. mu.M). The fluorescence intensity at λ 520nm was obtained. In FIG. 23, A shows that the above-mentioned interfering substance has a negligible effect on the fluorescence characteristics of the probe itself, and B shows that the interfering substance is present in the mixed solution to be detected and is present in the L-amino acidThe detection result has no influence.

1.8 hierarchical porous metal organic framework chiral sensing probe (L-AAO)&PF @ HPUiO-66) in a simulated physiologic ring Fluorescence sensing detection of environmental amino acids

Under simulated physiological conditions, i.e. L-phenylalanine and D-phenylalanine, and L-AAO&The PF @ HPUiO-66 probe material is dissolved in Simulated Body Fluid (SBF), wherein the SBF solution is prepared by the following steps: mixing NaCl and NaHCO₃，KCl，K₂HPO₄，MgCl₂，CaCl₂，Na₂SO₄Dissolving in deionized water, and adding inorganic ions (mM: Na)⁺ 142，K ⁺ 5，Mg²⁺ 1.5，Ca²⁺2.5，Cl^- 149，

18，

) Corresponding to human plasma concentration, using tris- (hydroxymethyl) aminomethane [ (CH) at 37 deg.C₂OH)₃CNH₂]And hydrochloric acid (HCl) to adjust the buffered pH of the liquid to 7.4. And according to1.6 points Hierarchical porous metal organic framework chiral sensing probe (L-AAO)&PF @ HPUiO-66) analysis of amino acid contentThe test process of (1) is to perform selective sensing of L-phenylalanine in mixed solutions of L-phenylalanine and D-phenylalanine with different concentrations and perform four groups of parallel experiments simultaneously to obtain the average concentration. The results in Table 3 below demonstrate L-AAO&The PF @ HPUiO-66 probe simulates the sensing capability of L-phenylalanine under physiological conditions.

TABLE 3

Sample (I)	Additive concentration (μ M)	Determination of the concentration (. mu.M). + -. sigma	Recovery (%)
				L-Phe/D-Phe	5/100	5.2±0.3	104±5
L-Phe/D-Phe	20/100	19.6±0.6	98±3
				L-Phe/D-Phe	40/100	41.6±0.5	104±1
L-Phe/D-Phe	60/100	60.4±1.0	101±2

Example 2

With reference to example 11.2-1.4Changing the fixed amino acid oxidase, and fixing the L-glutamate oxidase (L-GOX) into the hierarchical mesoporous metal organic framework microspheres to obtain the L-GOX&PF @ HPUiO-66 probe material.

See example 1 for1.5The L/D-amino acid is changed into L/D-glutamic acid. FIG. 24A shows L-GOX&The PF @ HPUiO-66 probe has chiral sensing ability for L-glutamic acid.

See example 1 for1.6Changing L-AAO&PF @ HPUiO-66 probe materialThe material is L-GOX&PF @ HPUiO-66 probe material; changing the L-amino acid into L-glutamic acid. L-GOX can be seen in FIGS. 24B and 24C&The PF @ HPUiO-66 probe can be used for carrying out linear analysis on L-glutamic acid within 0-100 mu M.

A solution of 19 chiral enantiomeric amino acids (100. mu.M) in 100. mu.L was added to 1.9mL of L-GOX&PF @ HPUiO-66 Probe solution (100mg L)^-1) In (1). The reaction mixture was incubated at 37 ℃ with exclusion of light until equilibrium, and the fluorescence intensity of the reaction mixture at λ 520nm was measured by fluorescence spectroscopy. FIG. 24D shows that the probe has high selectivity for L-glutamic acid and no response to other L-amino acids and D-amino acids.

See example 1 for1.8And the L-phenylalanine and the D-phenylalanine are changed into L-phenylalanine, L-leucine, L-methionine, L-tryptophan, L-histidine, L-isoleucine, L-tyrosine, L-cysteine and D-glutamic acid. The results in Table 4 below demonstrate L-GOX&The PF @ HPUiO-66 probe simulates the sensing capability of L-glutamic acid under physiological conditions.

TABLE 4

The invention is achieved by a block copolymer F127 template and

the hierarchical porous metal organic framework material is synthesized by the Hofmeister salinization anion function. And loading different types of amino acid oxidase and fluorescent molecules into the pore channels of the hierarchical porous metal organic framework material in a post-adsorption mode, thereby realizing the chiral recognition and content analysis of the amino acid. The method has universal applicability, and provides a new method and thought for biomolecule fluorescence sensing.

The above embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and various changes may be made in the above embodiments of the present invention. All simple and equivalent changes and modifications made according to the claims and the content of the specification of the present application fall within the scope of the claims of the present patent application. The invention has not been described in detail in order to avoid obscuring the invention.

Claims (12)

1. A preparation method of a hierarchical porous metal organic framework chiral sensing probe is characterized by comprising the following steps:

s1, providing a hierarchical porous metal organic framework microsphere with a regular pore channel structure;

s2, fixing amino acid oxidase on the hierarchical porous metal organic framework microsphere to obtain the hierarchical porous metal organic framework microsphere with the enzyme fixed, wherein the amino acid oxidase is loaded in a pore channel of the hierarchical porous metal organic framework microsphere through adsorption;

s3, fixing the fluorescent molecules on the hierarchical porous metal organic framework microspheres fixed with the enzyme to obtain the hierarchical porous metal organic framework chiral sensing probe, wherein the fluorescent molecules are loaded in the pore channels of the hierarchical porous metal organic framework microspheres through adsorption.

2. The method according to claim 1, wherein the amino acid oxidase is at least one selected from the group consisting of L-amino acid oxidase, L-glutamate oxidase, and L-tryptophan oxidase.

3. The method of claim 1, wherein the fluorescent molecule is 3-Oxo-3',6' -bis (4,4,5, 5-tetramethyl-1, 3, 2-dioxaborolan-2-yl) -3H-spiro [ isobenzofuran-1, 9' -xanthene ] -6-carboxylic acid.

4. The method for preparing a composite material according to claim 1, wherein the step S1 includes:

s11, using Block copolymer PEO₁₀₆PPO₇₀PEO₁₀₆Providing a metal organic framework precursor solution for a template agent;

s12, generating a hierarchical porous metal organic framework precursor through solvothermal;

and S13, obtaining the hierarchical porous metal organic framework microspheres with large pore diameters by activating and removing templates.

5. The preparation method according to claim 4, wherein the pore size of the hierarchical porous metal organic framework microsphere is 8-10 nm.

6. The chiral sensing probe with the hierarchical porous metal organic framework, which is obtained by the preparation method according to any one of claims 1 to 5, is characterized in that amino acid oxidase and fluorescent molecules are coupled on a carrier of microspheres with the hierarchical porous metal organic framework.

7. The use of the hierarchical porous metal organic framework chiral sensing probe according to claim 6, wherein the hierarchical porous metal organic framework chiral sensing probe has a chiral sensing response to an amino acid.

8. The use according to claim 7, wherein the amino acid is phenylalanine, leucine, methionine, tryptophan, histidine, isoleucine, tyrosine, and/or cysteine.

9. The use of claim 7, wherein the hierarchical porous metal organic framework chiral sensor probe exhibits an increase in fluorescence for the L-enantiomer of an amino acid and no response to the D-enantiomer of the amino acid.

10. The use according to claim 7, wherein the hierarchical porous metal organic framework chiral sensing probe is dispersed in HEPES buffer solution to form a probe solution, an amino acid solution is added into the probe solution for incubation, and the fluorescence intensity is measured by a fluorescence spectrometer.

11. The use according to claim 10, wherein the amino acid is subjected to linear analysis using a hierarchical porous metal organic framework chiral sensor probe at a concentration range of 0-100 μ M in the amino acid solution.

12. Use according to claim 10, wherein the lower limit of detection of the amino acid solution is between 0.38 μ M and 0.44 μ M.

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