阅读说明：本技术 大环分子及其制备方法与应用 (Macrocyclic molecules, methods of preparation and uses thereof ) 是由 蒋伟 王小平 于 2021-08-18 设计创作，主要内容包括：本发明提供了一种大环分子,其结构如通式I、Ⅱ、Ⅲ或Ⅳ所示,其中,R每次出现,独立地选自：被至少一个X取代或未取代的具有2至10个C原子的直链烷基,或被至少一个X取代或未取代的具有2至10个C原子的支链或环状的烷基；X每次出现,独立地选自炔基、酯基、羧基、吡啶盐、铵盐或羧酸盐基团。该大环分子在水中对亲水性分子的识别随其在酸/碱环境而发生改变。(The invention provides a macrocyclic molecule, the structure of which is shown as general formula I, II, III or IV, wherein, R is independently selected from the following at each occurrence: a straight chain alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X, or a branched or cyclic alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X; x is independently selected for each occurrence from an alkynyl, ester, carboxyl, pyridinium, ammonium, or carboxylate group. The recognition of the hydrophilic molecule by the macrocyclic molecule in water changes with its acid/base environment.)

1. A macrocyclic molecule having the structure of formula I, ii, iii or iv:

wherein, for each occurrence, R is independently selected from: a straight chain alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X, or a branched or cyclic alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X; x is independently selected for each occurrence from an alkynyl, ester, carboxyl, pyridinium, ammonium, or carboxylate group.

2. The macrocyclic molecule of claim 1, wherein said carboxylate group is a sodium carboxylate group, a potassium carboxylate group, or a lithium carboxylate group.

3. The macrocyclic molecule of claim 1, wherein R isEach occurrence is independently selected from any one of the following groups: -CH₂CH₂CH₂CH₃、-CH₂CO₂CH₂CH₃、-CH₂C ≡ CH and-CH₂CO₂Na。

4. A method of preparing a macrocyclic molecule according to any of claims 1 to 3, comprising the steps of:

carrying out an aldehyde-amine condensation reaction on the compound A and the compound B, and carrying out a reduction reaction on a product obtained after the aldehyde-amine condensation reaction to prepare an intermediate product C;

carrying out condensation cyclization reaction on the intermediate product C;

the compound A has a structure shown as a formula V-1:

the compound B has a structure shown as a formula V-2:

the intermediate product C has a structure shown in a formula V-3:

wherein R is₁Each occurrence is independently selected from: is at least one X₁Substituted or unsubstituted straight-chain alkyl radicals having 2 to 10C atoms, or by at least one X₁A substituted or unsubstituted, branched or cyclic alkyl group having 2 to 10C atoms; x₁Each occurrence is independently selected from an alkynyl group or an ester group.

5. The method for preparing a macrocyclic molecule according to claim 4, wherein the reducing agent used in the reduction reaction is sodium borohydride, borane, sodium triacetyl borohydride or sodium cyanoborohydride.

6. The method of claim 4, wherein the aldehyde-amine condensation reaction is carried out for a period of time ranging from 12 hours to 48 hours.

7. Process for the preparation of a macrocyclic molecule according to claim 4, characterized in that said preparation of Compound A comprises the following steps: carrying out oxidation reaction on the compound D; and/or

The preparation of the compound B comprises the following steps: carrying out an aldehyde amine condensation reaction, a reduction reaction and a Boc protection removal reaction on the compound D and tert-butyl carbamate in sequence;

wherein the compound D has a structure shown in a formula VI-1:

8. the process for the preparation of a macrocyclic molecule according to claim 7, wherein the preparation of compound D comprises the steps of:

the compoundAnd compoundsCarrying out condensation reaction to prepare an intermediate product E, wherein the intermediate product E has a structure shown in a formula VI-2:

reacting the intermediate E with a compoundThe formylation reaction and the oxidation reaction are sequentially carried out.

9. A process for the preparation of a macrocyclic molecule according to any of claims 4 to 8, wherein X is₁The method is an ester group, and comprises the following steps after the intermediate product C is subjected to condensation cyclization reaction:

and (3) performing hydrolysis reaction on the product of the condensation cyclization reaction and alkali at the temperature of between 20 and 30 ℃ to convert ester groups into carboxylate.

10. A macrocyclic molecule according to any of claims 1 to 3 or obtainable by a process according to any of claims 4 to 9 for use in bifunctional molecular recognition.

Technical Field

The invention relates to the technical field of organic synthesis, in particular to a macrocyclic molecule and a preparation method and application thereof.

Background

In a living body, the stimulation of a biological receptor by the external environment usually causes the function of the biological receptor to change, which is a common phenomenon and also forms the basis of a life phenomenon. Most biological receptors have their recognition function "turned on" or "turned off" by an external stimulus. However, there are some special biological receptors that can recognize different object molecules before and after being stimulated by external stimulus, rather than turning on or off their recognition functions, and this specific bifunctional molecular recognition property is very important for many complex life phenomena such as gene expression, protein transport and hormone regulation. In the cellular environment of the body, pH changes are one of the key factors that trigger bifunctional recognition of biological receptors. Therefore, the research on the acid/base stimulation response type bifunctional molecule recognition in the water phase not only is helpful for understanding the complex life process, but also provides a new technical means for constructing complex molecular machines, multifunctional assemblies and the like in the water phase.

Most of the traditional synthetic main bodies which respond to external environment stimuli such as pH, illumination, temperature, oxidation reduction and the like still take the identification function of turning on or turning off as the main part when responding to the external stimuli, and can not meet the application requirement of the bifunctional molecular recognition.

The traditional substance for realizing the dual-function molecular recognition by utilizing an artificial receptor is cucurbituril, the cucurbituril can be alternately bonded with n-hexylamine or n-hexyltrimethylammonium along with the alternate stimulation of an acid/alkali environment, the basis for realizing the dual-function molecular recognition is that the acid/alkali neutralization reaction leads to the protonation and deprotonation of the n-hexylamine, the cucurbituril and the n-hexylamine are bonded more strongly in the environment with the pH of less than 7, and conversely, the cucurbituril and the n-hexyltrimethylammonium are bonded more strongly in the environment with the pH of more than 13, so that the dual-function molecular recognition function is realized. However, even if the recognition performance of the synthetic host is changed little by external stimulation compared to the biological receptor, and the bifunctional recognition process caused by the stimulation of the biological receptor cannot be reflected, the inability of the host to be stimulus-regulated means that the range of choices for the subject is greatly limited.

Disclosure of Invention

In this regard, the present invention provides a macrocyclic molecule whose recognition of hydrophilic molecules in water changes with their acid/base environment, i.e., is capable of recognizing different types of guest molecules in different acid/base environments.

The invention is realized by the following technical scheme.

A macrocyclic molecule having the structure of formula I, II, III or IV:

wherein, for each occurrence, R is independently selected from: a straight chain alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X, or a branched or cyclic alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X; x is independently selected for each occurrence from an alkynyl, ester, carboxyl, pyridinium, ammonium, or carboxylate group.

In one embodiment, the carboxylate group is a sodium carboxylate group, a potassium carboxylate group, or a lithium carboxylate group.

In one embodiment, each occurrence of R is independently selected from any one of the following groups: -CH₂CH₂CH₂CH₃、-CH₂CO₂CH₂CH₃、-CH₂C ≡ CH and-CH₂CO₂Na。

The invention also provides a method for preparing the macrocyclic molecule, which comprises the following steps:

carrying out an aldehyde-amine condensation reaction on the compound A and the compound B, and carrying out a reduction reaction on a product obtained after the aldehyde-amine condensation reaction to prepare an intermediate product C;

carrying out condensation cyclization reaction on the intermediate product C;

the compound A has a structure shown as a formula V-1:

the compound B has a structure shown as a formula V-2:

the intermediate product C has a structure shown in a formula V-3:

wherein R is₁Each occurrence is independently selected from: is at least one X₁Substituted or unsubstituted straight-chain alkyl radicals having 2 to 10C atoms, or by at least one X₁Substituted or unsubstituted with 2 to 10C atomsA branched or cyclic alkyl group; x₁Each occurrence is independently selected from an alkynyl group or an ester group.

In one embodiment, the reducing agent used in the reduction reaction is sodium borohydride, borane, sodium triacetyl borohydride, or sodium cyanoborohydride.

In one embodiment, the time for the aldehyde amine condensation reaction is 12h to 48 h.

In one embodiment, the preparation of compound a comprises the steps of: carrying out oxidation reaction on the compound D; and/or

The preparation of the compound B comprises the following steps: carrying out an aldehyde amine condensation reaction, a reduction reaction and a Boc protection removal reaction on the compound D and tert-butyl carbamate in sequence;

wherein the compound D has a structure shown in a formula VI-1:

in one embodiment, the preparation of compound D comprises the steps of:

the compoundAnd compoundsCarrying out condensation reaction to prepare an intermediate product E, wherein the intermediate product E has a structure shown in a formula VI-2:

reacting the intermediate E with a compoundThe formylation reaction and the oxidation reaction are sequentially carried out.

In one embodiment, X₁The method is an ester group, and comprises the following steps after the intermediate product C is subjected to condensation cyclization reaction:

and (3) performing hydrolysis reaction on the product of the condensation cyclization reaction and alkali at the temperature of between 20 and 30 ℃ to convert ester groups into carboxylate.

The invention also provides the use of a macrocyclic molecule as described above for the identification of bifunctional molecules.

Compared with the prior art, the macrocyclic molecule of the invention has the following beneficial effects:

the structural cavities of the macrocyclic molecules are internally provided with secondary amine, and have the characteristics of being protonated and deprotonated, wherein the cavities are provided with bonding sites of hydrogen bonds and are hydrophobic cavities, a relatively nonpolar environment is provided for the interaction of the hydrogen bonds, and the competition of water molecules can be avoided. In addition, the macrocyclic molecules of the invention also have the characteristic of chiral recognition.

Furthermore, the macrocyclic compound can be prepared simultaneously by a one-pot method, and the preparation method is simple and easy to implement and has high yield.

Detailed Description

In order that the invention may be more fully understood, preferred embodiments of the invention will now be described with reference to the accompanying examples. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention provides a macrocyclic molecule, the structure of which is shown as general formula I, II, III or IV:

wherein, for each occurrence, R is independently selected from: a straight chain alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X, or a branched or cyclic alkyl group having 2 to 10C atoms substituted or unsubstituted with at least one X; x is independently selected for each occurrence from an alkynyl, ester, carboxyl, pyridinium, ammonium, or carboxylate group.

In the present invention, formula I and formula II are a pair of chiral macrocyclic molecules, and formula III and formula IV are a pair of chiral macrocyclic molecules; the structural cavities of the formula I, the formula II, the formula III and the formula IV are all internally provided with secondary amine which has the characteristics of being protonated and deprotonated; the large rings provided by the invention are all provided with a cavity structure, the cavities are provided with hydrogen bond binding sites (amide and secondary amine), and the hydrophobic cavities provide a relatively nonpolar environment for the interaction of hydrogen bonds, so that the competition of water molecules can be avoided, and in addition, the secondary amine can be switched between a hydrogen bond acceptor and a hydrogen bond donor along with the change of the pH value of the environment; therefore, the macrocycle provided by the invention can perform molecular recognition by utilizing hydrogen bonds and hydrophobic effects, and environmental pH change can cause great change of cavity electronic characteristics and non-covalent bond interaction modes, so that the molecular recognition property of the cavity is changed.

The macrocyclic molecules provided by the invention are spatial three-dimensional ring structures, and in order to show the chemical structures of the macrocyclic molecules more clearly, one of the macrocyclic molecular structures is drawn as a planar structure for brief understanding:

in a particular example, R, for each occurrence, is independently selected from: a straight chain alkyl group having 2 to 5C atoms substituted or unsubstituted with at least one X, or a branched or cyclic alkyl group having 2 to 5C atoms substituted or unsubstituted with at least one X.

In a particular example, the carboxylate group is a sodium carboxylate group, a potassium carboxylate group, or a lithium carboxylate group.

In a particular example, R, for each occurrence, is independently selected from any one of the following groups: -CH₂CH₂CH₂CH₃、-CH₂CO₂CH₂CH₃、-CH₂C ≡ CH and-CH₂CO₂Na。

The invention also provides a preparation method of the macrocyclic molecule, which comprises the following steps:

carrying out an aldehyde-amine condensation reaction on the compound A and the compound B, and carrying out a reduction reaction on a product obtained after the aldehyde-amine condensation reaction to prepare an intermediate product C;

carrying out condensation cyclization reaction on the intermediate product C;

compound A has the structure shown in formula V-1:

compound B has the structure shown in formula V-2:

intermediate C has the structure of formula V-3:

wherein R is₁Each occurrence is independently selected from: is at least one X₁Substituted or unsubstituted withStraight-chain alkyl of 2 to 10C atoms, or substituted by at least one X₁A substituted or unsubstituted, branched or cyclic alkyl group having 2 to 10C atoms; x₁Each occurrence is independently selected from an alkynyl group or an ester group.

In a specific example, the molar ratio of the compound A to the compound B is (0.8-1.2): 1. More specifically, the molar ratio of compound a to compound B is 1: 1.

In a specific example, the solvent used in the aldehyde-amine condensation reaction is at least one of dichloromethane and ethanol; more preferably, the solvent used in the aldehyde-amine condensation reaction is a mixture of dichloromethane and ethanol; more preferably, the solvent used in the aldol condensation reaction is a mixture of dichloromethane and ethanol in a volume ratio of 2: 1.

In a specific example, the time for the aldol condensation reaction is 12h to 48 h. More specifically, the aldol condensation reaction time was 24 h.

In a specific example, the reducing agent used in the reduction reaction is sodium borohydride, borane, sodium triacetyl borohydride, or sodium cyanoborohydride. More specifically, the reducing agent used in the reduction reaction is NaBH₄。

In a specific example, the molar ratio of the reducing agent to the compound A in the reduction reaction is (2-3): 1. More specifically, the molar ratio of the reducing agent to compound a in the reduction reaction was 2.5: 1.

In one specific example, subjecting intermediate C to a condensation cyclization reaction comprises the steps of:

benzotriazol-1-yl-oxytripyrrolidinophosphonium hexafluorophosphate and diisopropylethylamine are dissolved in a solvent, and then the intermediate product C dissolved in the solvent is added.

In a specific example, the time of the condensation cyclization reaction is 14h to 18 h.

In one particular example, the condensing agent employed in the condensation cyclization reaction is benzotriazol-1-yl-oxy-oxytripyrrolidinophosphonium hexafluorophosphate.

In a specific example, the molar ratio of the amount of the condensing agent added to the compound A in the condensation-cyclization reaction is (1-1.5): 1. More specifically, the molar ratio of the amount of the condensing agent added to the compound a in the condensation-cyclization reaction is 1.2: 1.

In a specific example, the initiator used in the condensation cyclization reaction is diisopropylethylamine.

In a specific example, the molar ratio of the added amount of the initiator to the compound A in the condensation cyclization reaction is (1-2): 1. More specifically, the molar ratio of the amount of the initiator added to the compound A in the condensation-cyclization reaction is 1.5: 1.

In one specific example, the preparation of compound a comprises the steps of: carrying out oxidation reaction on the compound D; and/or

The preparation of compound B comprises the following steps: carrying out an aldehyde amine condensation reaction, a reduction reaction and a Boc protection removal reaction on the compound D and tert-butyl carbamate in sequence;

wherein, the compound D has a structure shown in a formula VI-1:

in one specific example, the preparation of compound D comprises the steps of:

the compoundAnd compoundsCarrying out condensation reaction to prepare an intermediate product E, wherein the intermediate product E has a structure shown in a formula VI-2:

intermediate E is reacted with a compoundThe formylation reaction and the oxidation reaction are sequentially carried out.

In one specific example, intermediate C is subjected to a condensation cyclization reaction and the product is isolated after completion. More specifically, the separation method is recrystallization or high performance liquid chromatography.

In one specific example, X₁For the ester group, the method also comprises the following steps after the intermediate product C is subjected to cyclization reaction:

and (3) performing hydrolysis reaction on the product of the condensation cyclization reaction and alkali at the temperature of between 20 and 30 ℃ to convert ester groups into carboxylate.

In one particular example, the base is sodium hydroxide.

The invention also provides the application of the macrocyclic molecule in the identification of bifunctional molecules.

The macrocyclic molecules of the present invention and methods for their preparation are described in further detail below with reference to specific examples. The starting materials used in the following examples are all commercially available products unless otherwise specified.

Example 1

This example provides a macrocyclic molecule and a method of making the same, the macrocyclic molecule having any of the following structures:

the preparation method comprises the following steps:

(1) compound A (S)₄) The preparation process is as follows:

intermediate compound S₁The synthesis of (2): after anhydrous NaH (24g,563mmol) was added to a solution of 2, 6-dihydroxynaphthalene (100g,625mmol) in DMF (800mL) and stirred for 1 hour, ethyl bromoacetate (63mL,594mmol) was slowly added to the reaction solution through a constant pressure dropping funnel; stirring at room temperature for 12 hr, pouring the reaction solution into 3L ice water, adding small amount of dilute hydrochloric acid to adjust pH to about 7, stirring to obtain a large amount of insoluble solidAnd (4) precipitating. Filtering, washing the filter residue with a large amount of water, dissolving the filter residue in 4L methanol, stirring, filtering, adding anhydrous sodium sulfate into the obtained filtrate, drying overnight, filtering, evaporating the obtained filtrate, adding about 90mL dichloromethane, and filtering to obtain white solid S₁。

Intermediate compound S₂The synthesis of (2): compound S₁(58g,235mmol) in dry dichloromethane (CH)₂Cl₂600Ml) and trifluoroacetic acid (TFA,300mL), and malonic acetal (19.3mL,102.8mmol) was slowly added dropwise to the reaction solution through an isopiestic dropping funnel, followed by reaction at room temperature under argon atmosphere for 12 hours. After the reaction is finished, pouring the reaction solution into 2L of ice water, adding 1M NaOH solution into the ice water, and adjusting the pH value to 7-8; then extracted three times with dichloromethane (500 mL. times.3), the organic phases were combined and dried over anhydrous sodium sulfate, filtered and the solvent was removed under reduced pressure to give S as a white solid₂。

Intermediate compound S₃The synthesis of (2): under ice bath, compound S is added₂(21.0g,39.7mmol) was dissolved in anhydrous dichloromethane (600mL), 1-dichloromethyl ether (14.4mL,158.9mmol) was added slowly in portions, titanium tetrachloride (16.0mL,160.0mmol) was slowly dropped into the reaction solution through a constant pressure dropping funnel, the reaction solution was stirred for 1 hour in an ice bath, warmed to room temperature and stirred for 4 hours, then poured into ice water, and 1M NaOH solution was added thereto to adjust the pH to about 8. Then, extraction with dichloromethane (300 mL. times.3) combined the organic phases and dried by addition of anhydrous sodium sulfate, filtered, the solvent removed under reduced pressure, 100mL of acetone added and sonicated for about 10 minutes, filtered to give S3 as a bright yellow solid.

S₄The synthesis of (2): under ice bath, compound S is added₃(2.0g,3.4mmol) and sulfamic acid (1.0g,10.3mmol) were dissolved in a mixed solvent of water (100mL), tetrahydrofuran (200mL) and acetone (300mL), and sodium chlorite (1.2g,13.7mmol) dissolved in water (30mL) was slowly added to the reaction solution through a constant pressure dropping funnel, followed by reaction at room temperature for 6 hours; adding ice water mixture into the reaction solution after the reaction is finished, obtaining a crude product from the filtrate, and then separating by column chromatography (SiO)₂,CH₂Cl₂100:1-10:1) to obtain a yellow solidCompound S₄。

(2) Compound B (S)₅) The preparation process is as follows:

S₅the synthesis of (2): reacting a compound S₃(2.0g,3.4mmol) and tert-butyl carbamate (7.0g,6.0 mmol) are dissolved in a mixed solvent of acetonitrile (100mL) and dichloromethane (300mL), triethylsilane (7.0g,60mL) and trifluoroacetic acid (5.0mL) are added to the reaction by syringe under the protection of argon, and the reaction is carried out at room temperature for 6 hours; after completion of the reaction, the solvent was removed under reduced pressure, and then trifluoroacetic acid (50mL) and dry dichloromethane (150mL) were added and the reaction was continued for 6 hours under argon. After the reaction is finished, removing the solvent by decompression, and washing with water and dichloromethane in sequence to obtain the target product S₅。

(3) Macrocyclic molecules (A)₁、A₂、B₁、B₂) The preparation process is as follows:

reacting a compound S₅(4.07g,5.0mmol) was dissolved in absolute ethanol (500mL) and heated to 50 ℃ under argon. S dissolved in water (30mL) was added via a constant pressure dropping funnel₄(3.0g,5.0mmol) was slowly added to the reaction solution, reacted at 50 ℃ for 12 hours, and then NaBH was added₄(0.20g,5.0mmol) was stirred for 30 minutes. Removing the solvent under reduced pressure to obtain a product containing S₆The residue of (2) is ready for use.

Benzotriazol-1-yl-oxytripyrrolidinophosphonium hexafluorophosphate (PyBOP,5.2g,10.0mmol) and diisopropylethylamine (DIEA,10mL) were dissolved in dimethylformamide (DMF,500 mL). Dissolving the compound S in 50mL of anhydrous dimethylformamide under the protection of argon₆The residue was slowly added dropwise to the reaction solution by means of a syringe pump (addition time was more than 6 hours). After the addition, the reaction was stirred for 16 hours. After the reaction is completed, by rotatingThe solvent was removed by evaporator, the residue was poured into ice-water mixture (4L), filtered, the filter cake was washed with methanol and purified by column chromatography (MeOH/CH)₂Cl₂1/1000-5/1000, v/v) to obtain the initial product (A)₁And A₂，B₁And B₂Mixtures of (a), separated by washing with solvents (dichloromethane and acetone) to give cis-racemic mixtures (a), respectively₁And A₂) And trans-racemic mixture (B)₁And B₂)。

Characterization of the product:

respectively performing nuclear magnetic hydrogen spectrum, nuclear magnetic carbon spectrum and mass spectrum characterization on the obtained product, wherein the data results are as follows:

cis-racemic mixture (A)₁And A₂) The data of (2) characterize:

¹H NMR(500MHz,Acetone-d₆,298K)δ[ppm]＝8.68(d,J＝9.4Hz,1H),8.63 (d,J＝9.4Hz,1H),8.57(d,J＝9.4Hz,1H),8.54(d,J＝9.4Hz,1H),8.12(d,J＝9.2 Hz,1H),8.09(d,J＝9.2Hz,1H),7.93(d,J＝9.2Hz,1H),7.92(d,J＝9.2Hz,1H), 7.81(s,1H),7.65(s,1H),7.35–7.27(m,3H),7.20(d,J＝9.2Hz,1H),7.19(d,J＝ 9.2Hz,1H),7.15(d,J＝9.4Hz,1H),7.09(d,J＝9.2Hz,2H),6.62(d,J＝9.8Hz, 1H),6.28(s,1H),6.27(s,1H),5.54–5.48(m,2H),5.41(dd,J＝13.9,10.0Hz,1H), 5.30–5.13(m,4H),5.04(d,J＝16.9Hz,1H),5.01–4.89(m,2H),4.89–4.71(m, 6H),4.30–3.89(m,8H),2.67–2.43(m,4H),1.28–1.20(m,6H),1.17(t,J＝7.1 Hz,3H),1.06(t,J＝7.1Hz,3H)；

¹³C NMR(126MHz,Acetone-d₆,298K)δ[ppm]＝170.52,170.45,169.91, 165.69,153.68,153.46,151.29,150.94,150.52,150.10,149.90,129.60,129.44, 129.40,128.33,128.15,128.09,128.04,127.95,127.31,127.18,125.94,125.75, 124.63,123.59,123.55,122.65,122.46,121.34,120.97,120.89,120.62,120.52, 120.31,120.16,115.74,115.68,115.53,114.38,114.27,113.96,92.29,92.18,67.61, 66.89,66.78,66.35,62.31,62.23,62.05,61.78,44.23,44.15,44.06,33.67,26.47, 26.38,23.09,23.02,14.61,14.59,14.54,14.45；

ESI-TOF-HRMS:m/z calcd for[M]⁺C₆₆H₆₁N₂O₁₇,1153.3965；found 1153.3981 (error＝+1.4ppm).

trans racemic mixture (B)₁And B₂) The data of (2) characterize:

¹H NMR(500MHz,CD₂Cl₂,298K)δ[ppm]＝8.45(d,J＝9.5Hz,1H),8.39(d, J＝9.5Hz,1H),8.33(d,J＝9.1Hz,1H),8.31(d,J＝9.1Hz,1H),7.72(d,J＝9.2Hz, 1H),7.69(d,J＝9.2Hz,1H),7.65(d,J＝9.2Hz,1H),7.57(d,J＝9.1Hz,1H),7.20 (s,2H),7.18–7.07(m,4H),7.06–6.99(m,3H),6.94(d,J＝9.1Hz,1H),6.24(s, 1H),6.22(s,1H),5.57(dd,J＝13.8,7.0Hz,1H),5.45(d,J＝6.3Hz,1H),5.30(s, 1H),5.27(s,1H),5.09–4.99(s,0H),4.91–4.64(m,10H),4.52(dd,J＝13.7,2.0 Hz,1H),4.31–4.18(m,2H),4.14–4.04(m,1H),4.03–3.91(m,1H),3.51–3.31 (m,2H),3.10–3.02(m,1H),3.01–2.93(m,1H),2.68–2.60(m,2H),2.54–2.46 (m,2H),1.29(t,J＝7.1Hz,3H),1.09(t,J＝7.1Hz,3H),0.95(t,J＝7.1Hz,3H), 0.90(t,J＝7.1Hz,3H)；

¹³C NMR(126MHz,DMSO-d₆,298K)δ[ppm]＝170.13,169.95,169.70, 169.37,165.49,153.23,153.20,151.55,149.86,149.62,149.23,149.08,149.01, 128.60,128.55,128.24,127.35,127.21,127.18,127.08,127.04,126.82,126.71, 126.47,125.65,124.43,123.50,123.35,123.25,122.14,120.43,120.40,120.38, 120.25,119.82,119.72,119.46,119.32,115.03,114.82,114.64,114.51,114.40,91.17, 91.14,66.95,66.75,66.24,65.77,61.37,61.28,61.26,61.20,43.19,42.57,33.59, 25.61,25.46,21.68,14.54,14.47,14.45；

ESI-TOF-HRMS:m/z calcd for[M]⁺C₆₆H₆₁N₂O₁₇,1153.3965；found 1153.3971 (error＝+0.5ppm).

example 2

This example provides a macrocyclic molecule and a method of making the same, the macrocyclic molecule having any of the following structures:

the preparation method comprises the following steps:

(1) compound C (C)₁And C₂) The synthesis of (2): sodium hydroxide solution (5.0mL,6.0N) was added to dissolve product A (A) from example 1₁And A₂) (100mg,0.086mmol) in a mixed solution of methanol (5mL) and tetrahydrofuran (5mL) was allowed to react overnight at room temperature, after completion of the reaction, 10% hydrochloric acid (5mL) was added, the precipitate was filtered, the filter cake was dissolved in aqueous sodium hydroxide (20mg/mL,0.688mL) and stirred for a few minutes, the solvent was removed by evaporation, and dried to give racemic compound C (white solid).

(2) Compound D (D)₁And D₂) The synthesis of (2): sodium hydroxide solution (5.0mL,6.0N) was added to dissolve product B from example 1 (B)₁And B₂) (100mg,0.086mmol) in a mixed solution of methanol (5mL) and tetrahydrofuran (5mL) was reacted at room temperature overnight, after completion of the reaction, 10% hydrochloric acid (5mL) was added, the precipitate was filtered, the filter cake was dissolved in an aqueous solution of sodium hydroxide (20mg/mL,0.688mL) and stirred for a few minutes, the solvent was distilled off, and dried to give racemic compound D (white solid).

Characterization of the product:

respectively performing nuclear magnetic hydrogen spectrum, nuclear magnetic carbon spectrum and mass spectrum characterization on the obtained product, wherein the data results are as follows:

compound C (C)₁And C₂) The data of (2) characterize:

¹H NMR(500MHz,D₂O,298K)δ[ppm]＝8.47(d,J＝9.5Hz,1H),8.44(d,J＝ 9.6Hz,1H),8.41(d,J＝9.6Hz,1H),8.33(d,J＝9.5Hz,1H),7.90(d,J＝9.2Hz, 1H),7.69(d,J＝9.2Hz,1H),7.23(d,J＝9.1Hz,1H),7.19(d,J＝9.1Hz,1H),7.14 (d,J＝9.3Hz,1H),7.08–7.01(m,3H),6.99–6.89(m,3H),6.78(d,J＝9.1Hz, 1H),6.27(s,1H),6.23(s,1H),5.42(s,1H),5.39(s,1H),5.05(d,J＝14.2Hz,1H), 4.84–4.81(m,2H),4.48–4.35(m,9H),4.26–4.07(m,2H),2.60(d,J＝13.4Hz, 2H),2.47(d,J＝13.5Hz,2H)；

¹³C NMR(126MHz,D₂O,298K)δ[ppm]＝177.07,176.97,176.76,169.08, 152.63,152.44,152.08,150.22,148.86,148.67,147.90,128.40,128.00,126.37, 126.12,125.30,125.01,124.94,123.33,123.31,123.19,122.33,121.10,120.37, 120.18,120.09,119.89,119.76,119.62,119.34,118.98,118.77,118.00,114.19, 113.84,113.79,113.60,91.91,91.85,67.92,67.82,67.55,67.51,41.51,41.24,34.05, 25.10,22.05,22.00；

ESI-TOF-HRMS:m/z calcd for[M-4Na+3H]^-C₅₈H₄₃N₂O₁₇,1039.2567；found 1039.2547(error＝-1.9ppm).

compound D (D)₁And D₂) The data of (2) characterize:

¹H NMR(500MHz,D₂O,298K)δ[ppm]＝8.47(d,J＝9.5Hz,2H),8.42(d,J＝ 9.5Hz,2H),7.68(d,J＝9.3Hz,1H),7.64(d,J＝9.3Hz,1H),7.59(d,J＝9.3Hz, 1H),7.24(d,J＝9.3Hz,1H),7.13–6.95(m,8H),6.24(s,2H),5.44(s,1H),5.44(s, 1H),5.43(s,1H),5.10(d,J＝14.0Hz,1H),4.68–4.58(m,4H),4.56–4.20(m,9H), 2.63–2.51(m,4H)；

¹³C NMR(126MHz,D₂O,298K)δ[ppm]＝176.91,176.61,176.59,169.98, 152.39,152.23,150.44,148.53,148.43,147.94,128.61,128.24,128.22,126.69, 126.42,125.74,125.55,125.40,125.09,123.33,122.79,122.46,122.32,120.03, 119.95,119.80,119.76,119.56,119.43,119.28,119.04,116.96,114.17,113.75, 113.57,113.34,91.95,67.91,67.41,67.22,42.14,34.75,24.94,24.76,21.97；

ESI-TOF-HRMS:m/z calcd for[M-4Na+5H]^-C₅₈H₄₃N₂O₁₇,1041.2713；found 1041.2728(error＝+3.4ppm).

effect verification test 1

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G1, the structural formula of G1 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 1 and the nuclear magnetic titration conditions as follows:

the model of the nuclear magnetic titration instrument is as follows: bruker Avance 500NMR spectrometer; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 1

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 1, the recognition of G1 by the subject is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 30 and 8 respectively, which indicates that the pH environment has a large influence on the recognition performance.

Effect test 2

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G2, the structural formula of G2 is shown below:

the binding constants were determined by isothermal titration calorimetry in 50mM phosphate buffer, pH 7.4 and 12, respectively, with test data as shown in Table 2 and isothermal titration calorimetry conditions as follows:

the type of the warm titration calorimeter is as follows: malvern MicroCal VP-ITC; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 2

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 2, the recognition of G2 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 35 and 25 respectively, which indicates that the pH environment has a large influence on the recognition performance.

Effect test III

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G3, the structural formula of G3 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 3 and the nuclear magnetic titration conditions as follows:

the NMR spectrometer model was Bruker Avance 500NMR spectrometer: solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 3

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 3, the recognition of G3 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 33 and 61 respectively, which indicates that the pH environment has a large influence on the recognition performance.

Effect test four

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G4, the structural formula of G4 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy or isothermal titration calorimetry in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 4 and the nuclear magnetic titration conditions as follows:

model of nuclear magnetic titration apparatus: bruker Avance 500NMR spectrometer, warm titration calorimeter model: malvern MicroCal VP-ITC; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 4

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 4, the recognition of G4 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 159 and 191 respectively, which indicates that the pH environment has a great influence on the recognition performance.

Effect verification test five

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G5, the structural formula of G5 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 5 and the nuclear magnetic titration conditions as follows:

model of nuclear magnetic titration apparatus: bruker Avance 500NMR spectrometer; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 5

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 5, the recognition of G5 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 295, which indicates that the pH environment has a great influence on the recognition performance.

Effect verification test six

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G6, the structural formula of G6 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 6 and the nuclear magnetic titration conditions as follows:

model of nuclear magnetic titration apparatus: bruker Avance 500NMR spectrometer; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 6

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 6, the recognition of G6 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 10 and 16 respectively, which indicates that the pH environment has a large influence on the recognition performance.

Effect verification test seven

Racemic Compound C (C) prepared in example 2₁And C₂) And D (D)₁And D₂) For the recognition of G7, the structural formula of G7 is shown below:

the binding constants were determined by nuclear magnetic hydrogen spectroscopy in 50mM phosphate buffer, pH 7.4 and 12, respectively, with the test data shown in Table 7 and the nuclear magnetic titration conditions as follows:

model of nuclear magnetic titration apparatus: bruker Avance 500NMR spectrometer; solvent: 50mM phosphate buffer pH 7.4 and 12; temperature: bulk concentration at 25 ℃: 0.2 mmol; guest concentration: 10 mmol.

TABLE 7

Wherein Ratio is the Ratio of bonding constants of the same host and the guest under different pH conditions.

As can be seen from the data in Table 7, the recognition of G7 by the compound is greatly different in 50mM phosphate buffers with pH 7.4 and 12, and the bonding constant ratio can reach 6 and 20 respectively, which indicates that the pH environment has a large influence on the recognition performance.

From the above data, it can be seen that the recognition of the above listed guests by macrocyclic molecules with secondary amines in their cavities is greatly different in both 50mM phosphate buffer, pH 7.4 and 12; for the guest G1-G4, the bonding in the buffer solution with the pH value of 7.4 is stronger than that in the buffer solution with the pH value of 12, and the ratio can reach hundreds of times; the opposite is true for the guests G5-G7. These characteristics indicate that the macrocyclic molecules C and D with cavities having secondary amines have bifunctional recognition properties.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, so as to understand the technical solutions of the present invention specifically and in detail, but not to be understood as the limitation of the protection scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. It should be understood that the technical solutions provided by the present invention, which are obtained by logical analysis, reasoning or limited experiments, are within the scope of the appended claims. Therefore, the protection scope of the patent of the invention is subject to the content of the appended claims, and the description can be used for explaining the content of the claims.