CN112010879B

CN112010879B - Zn functional complex and preparation method and application thereof

Info

Publication number: CN112010879B
Application number: CN202010968395.XA
Authority: CN
Inventors: 吴晓琴; 胡莹颖; 魏学红
Original assignee: Shanxi University
Current assignee: Shanxi University
Priority date: 2020-09-15
Filing date: 2020-09-15
Publication date: 2021-07-02
Anticipated expiration: 2040-09-15
Also published as: CN112010879A

Abstract

The invention provides a two-dimensional Zn functional complex and a preparation method thereofMethods and uses. The molecular formula of the complex is as follows: [ Zn ]₃(L^‑)₂(HBTC^2‑)₂]n, wherein L^‑6-aminonicotinic acid, HBTC, for dehydrogenation^2‑For removing two hydrogen ions of trimesic acid. The preparation method of the complex comprises the following steps: dissolving zinc nitrate hexahydrate, 6-aminonicotinic acid and trimesic acid in a mixed solution of distilled water and acetonitrile in a volume ratio of 1-3: 2-4 according to a molar ratio of 2-4: 3-5: 1-3; and (3) placing the mixture in an oven at the temperature of 130-150 ℃ for reacting for 65-80 hours, naturally cooling, and filtering to obtain a white crystalline solid. The preparation method of the complex is simple. The complex has an obvious characteristic peak between emission wavelengths of 340-360, has high fluorescence intensity, and can be used for detecting L-tyrosine.

Description

Zn functional complex and preparation method and application thereof

Technical Field

The invention relates to a preparation method of a Zn functional complex and application of the complex in L-tyrosine fluorescence detection.

Background

Amino acids are basic substances constituting proteins required for human and animal nutrition, and are organic compounds containing basic amino groups and acidic carboxyl groups. Wherein Tyrosine (Tyr) is an aromatic alpha-amino acid containing phenolic hydroxyl, is an essential amino acid for human body and is a ketogenic amino acid; it is a catalytic substrate of tyrosinase monophenol enzyme function, and is a main raw material for finally forming superior melanin and pheomelanin, so that tyrosine can help leucoderma patients to relieve symptoms, and can also treat poliomyelitis, sexual nuclear encephalitis, hyperthyroidism and other symptoms. Therefore, the detection and analysis of tyrosine have been the hot spots of research in the fields of feed, food, medicine, agriculture and environmental monitoring.

The functional complex is an organic-inorganic hybrid material formed by an organic ligand and metal ions or metal clusters through coordination bonds. Due to the unique porous structure and the various coordination modes, the material has wide attention in the application of energy, catalysis, adsorption, energy storage and other fields.

Disclosure of Invention

Based on the background, the invention aims to provide a Zn functional complex, a preparation method thereof and application of the complex in L-tyrosine fluorescence detection.

The invention provides a Zn functional complex, which has the chemical formula as follows: [ Zn ]₃(L^-)₂(HBTC^2-)₂]n, wherein L^-6-aminonicotinic acid, HBTC, for dehydrogenation^2-Trimesic acid ions for removing two hydrogens; the structural formula is as follows:

the invention provides a preparation method of a Zn functional complex, which comprises the following steps:

dissolving zinc nitrate hexahydrate, 6-aminonicotinic acid and trimesic acid in a mixed solution of distilled water and acetonitrile in a volume ratio of 1-3: 2-4 according to a molar ratio of 2-4: 3-5: 1-3; and (3) placing the mixture in an oven at 130-150 ℃ for reacting for 65-80 hours, naturally cooling and filtering to obtain white crystalline solid, namely the target product.

The molar ratio of the zinc nitrate hexahydrate, the 6-amino nicotinic acid and the trimesic acid is preferably 3:4: 2.

The volume ratio of the distilled water to the acetonitrile is preferably 2: 3.

The Zn functional complex can be applied to the fluorescence detection of L-tyrosine.

A fluorescence detection method of Zn functional complex to L-tyrosine comprises the following steps:

uniformly dispersing the Zn functional complex in a methanol solution to obtain a stable turbid liquid, putting 1.8-2.2 ml of the stable turbid liquid in a cuvette, and putting the cuvette in a fluorescence spectrophotometer to detect the L-tyrosine.

Compared with the prior art, the invention has the beneficial effects that: the functional complex [ Zn ] is prepared for the first time₃(L^-) ₂(HBTC^2-) ₂]n, carrying out structural characterization on the protein simultaneously, and applying the protein to the detection of the L-tyrosine. The complex is simple in preparation method, rapid, visual and reliable in detection of L-tyrosine, has an obvious characteristic peak with an emission wavelength of 340-360 nm, and is high in fluorescence intensity and good in detection effect.

Drawings

FIG. 1 is a diagram showing a coordination structure of a Zn functional complex.

FIG. 2 is a graph of powder X-ray diffraction pattern of a Zn functional complex compared to single crystal simulation data.

FIG. 3 is a fluorescence diagram of a fluorescence detection solution for Zn functional complex for detecting L-tyrosine.

Detailed Description

Example 1: zn functional complex [ Zn)₃(L^-)₂(HBTC^2-)₂]_nSynthesis and characterization of

[Zn₃(L^-)₂(HBTC^2-)₂]And n is synthesized:

dissolving 22.31mg of zinc nitrate hexahydrate, 13.81mg of 6-aminonicotinic acid and 10.51mg of trimesic acid in a mixed solution of 2mL of distilled water and 3mL of acetonitrile, placing the mixed solution in a polytetrafluoroethylene bottle, plugging the polytetrafluoroethylene bottle into a reaction kettle, placing the reaction kettle in an oven at 140 ℃ for reacting for 65 hours, and naturally cooling to obtain a white crystalline solid, namely the Zn functional complex.

Characterization of the properties of the Zn functional complex:

(1) measurement of Single Crystal Structure

The crystal structure is determined by Supernova X-ray single crystal diffractometer and Mo Kalpha ray monochromatized by graphite

Is a source of incident radiation, in

Diffraction points are collected in a scanning mode, unit cell parameters are obtained through least square method correction, a crystal structure is obtained through direct solution of a difference Fourier electron density diagram by using a SHELXL-97 method, and Lorentz and polarization effect correction are carried out. All H atoms were synthesized by difference Fourier and determined by ideal position calculations. The crystal determination data are shown in table 1.

TABLE 1[ Zn ]₃(L^-)₂(HBTC^2-)₂]_nCrystallographic data of

FIG. 1 is a diagram showing the coordination structure of the functional complex. The compound contains three Zn (II) ions and two L ions in the molecule^-(dehydro-6-aminonicotinic acid) and two HBTC^2-(trimesic acid ion with both hydrogens removed). Wherein Zn1 and Zn3 have the same coordination mode and are both four-coordination structures, and 3O atoms in the coordination atoms are respectively from two different HBTC^2-Ions and an L^-Ions; the ligand N originates from another L^-Ions. Zn2 is a hexa-coordinated structure with 6O coordinated atoms from four different HBTC^2-Ions and two different Ls^-Ions. Form a { Zn₃N₂O₁₀The nodes passing through the ligand L along the a-axis direction^-And b-axis direction passes through ligand HBTC^2-Extending to form a three-dimensional net structure. Four L in FIG. 1^-Ligand and four HBTC^2-The ligands are all shared with other building blocks.

(2) Powder X-ray diffraction measurement

Powder X-ray diffraction data were collected on a Rigaku D/Max-2500 diffractometer at an operating voltage of 40kV and a current of 100mA, using graphite monochromated copper target X-rays as the source of incident radiation during the test. Density data collection continuous scans were performed in the range of 5 to 50 using a 2 θ/deg. scan pattern, with a scan speed of 3 of 8/sec and a span of 0.02/pass. Experimental data fitting the program Cerius2 was used and the software Mercury 3.9 was used for powder X-ray diffraction spectrum simulation transformation of single crystal structures. FIG. 2 is a powder X-ray diffraction pattern of the Cu functional complex compared to a simulated single crystal data.

EXAMPLE 2 detection of L-tyrosine by Zn functional complexes

1mg of the Zn functional complex prepared in example 1 was weighed and added to 20mL of methanol solution under ultrasonic conditions to obtain a white suspension. And (3) taking 2ml of the suspension in a clean cuvette, measuring the fluorescence intensity once every 2min at the excitation wavelength of 265nm, and obtaining a fluorescence detection solution when the fluorescence intensity is stable. This fluorescence detection solution was used as a mother solution, 10. mu.L of 1 mmol/L-tyrosine was added thereto, and the fluorescence intensity was detected. Has a distinct characteristic peak between the emission wavelengths of 350nm and high fluorescence intensity. The functional complex has good response to L-tyrosine, and is shown in figure 3.

Claims

1. A Zn functional complex characterized by the chemical formula: [ Zn ]₃(L^-)₂(HBTC^2-)₂]n, wherein L^-6-aminonicotinic acid, HBTC, for dehydrogenation^2-Trimesic acid ions for removing two hydrogens;

crystallographic data of the complex: crystal system: monoclinic; space group:P-1; unit cell parameters: a = 7.9473(9) A, b = 9.4439(11) A, c = 11.2652(14) A,α = 94.781(4)°，b = 96.496(4)°，γ = 107.421(4)°。

2. a method of preparing a Zn functional complex according to claim 1, comprising the steps of:

dissolving zinc nitrate hexahydrate, 6-aminonicotinic acid and trimesic acid in a mixed solution of distilled water and acetonitrile in a volume ratio of 1-3: 2-4 according to a molar ratio of 2-4: 3-5: 1-3; and (3) placing the mixture in an oven at 130-150 ℃ for reacting for 65-80 hours, and naturally cooling to obtain white crystalline solid, namely the target product.

3. A method of preparing a functional complex of Zn as claimed in claim 2, wherein the molar ratio of zinc nitrate hexahydrate, 6-aminonicotinic acid and trimesic acid is 3:4: 2.

4. The method of claim 2, wherein the volume ratio of distilled water to acetonitrile is 2: 3.

5. Use of a Zn functional complex as claimed in claim 1 in the preparation of a reagent for the detection of L-tyrosine.

6. A method for detecting L-tyrosine, comprising the steps of: uniformly dispersing the Zn functional complex of claim 1 in a methanol solution to obtain a test mother solution, placing 1.8-2.2 mL of the test mother solution in a cuvette, adding an L-tyrosine solution, uniformly mixing, measuring the fluorescence intensity, and having an obvious enhancement characteristic peak at an emission wavelength of 350 nm.