阅读说明：本技术 疏水化多糖及其制备方法与应用 (Hydrophobic polysaccharide and preparation method and application thereof ) 是由 不公告发明人 于 2021-07-01 设计创作，主要内容包括：本发明提供一种疏水化多糖及其制备方法与应用。所述疏水化多糖的结构通式为G-P-O；其中,G为多糖或二糖,P为氨基酸与二酸缩合而成的两端带有羧基的连接分子,O为胆固醇；G和P之间通过酯键与多糖或二糖上的羟基连接,P和O之间通过酯键连接。本发明的疏水化多糖具有免疫调节性能,可与柴胡提取物共同发挥免疫调节作用。本发明疏水化多糖合成所用原料,皆安全、无毒,可用于食品、药品领域。疏水化多糖无毒,可在自然界全分解,无毒性。本发明的疏水化多糖修饰物,属于新型的高效药物递送载体,所制备的药液,药理活性高,强于现有的药物递送系统,微量药液就起显著药理作用,由于属于免疫调节性药物,具有一次治愈不复发的特性。(The invention provides a hydrophobization polysaccharide and a preparation method and application thereof. The general structural formula of the hydrophobized polysaccharide is G-P-O; wherein G is polysaccharide or disaccharide, P is a connecting molecule with carboxyl at two ends formed by condensing amino acid and diacid, and O is cholesterol; g and P are connected with hydroxyl on the polysaccharide or disaccharide through ester bonds, and P and O are connected through ester bonds. The hydrophobic polysaccharide has immunoregulation performance, and can play a role in immunoregulation together with the bupleurum extract. The raw materials for synthesizing the hydrophobic polysaccharide are safe and nontoxic, and can be used in the fields of food and medicines. The hydrophobic polysaccharide is nontoxic, can be completely decomposed in nature, and has no toxicity. The hydrophobic polysaccharide modifier belongs to a novel high-efficiency drug delivery carrier, the prepared liquid medicine has high pharmacological activity, is stronger than the existing drug delivery system, and has obvious pharmacological action when being a trace amount of liquid medicine, and has the characteristic of one-time cure without relapse due to belonging to an immunoregulatory drug.)

1. Hydrophobized polysaccharides, characterized by the general structural formula: G-P-O;

wherein G is polysaccharide or disaccharide, P is a connecting molecule with carboxyl at two ends formed by condensing amino acid and diacid, and O is cholesterol; g and P are connected with hydroxyl on the polysaccharide or disaccharide through ester bonds, and P and O are connected through ester bonds.

2. The hydrophobized polysaccharide according to claim 1, wherein the polysaccharide is a water-soluble polysaccharide selected from the group consisting of hyaluronic acid, chondroitin sulfate, dermatan sulfate, heparin, water-soluble starch, water-soluble inulin, water-soluble chitosan, water-soluble dextran, water-soluble pullulan, water-soluble mannose, water-soluble algal polysaccharide, water-soluble starch, water-soluble hydroxyethyldextran, water-soluble fructan, water-soluble xyloglucan, water-soluble cellulose; and physiologically active polyhydroxy compounds (e.g., sialic acid); and/or

The disaccharide is selected from sucrose, fructose or lactose; and/or

The amino acid is at least one of glycine, glutamic acid, L-lysine, L-cysteine, DL-alanine, DL-methionine, L-ornithine, gamma-aminobutyric acid, L-aspartic acid, L-theanine, L-arginine, beta-alanine, L-citrulline, L-histidine, leucine, isoleucine, valine, phenylalanine, proline, tryptophan, serine, tyrosine, glutamine, asparagine and histidine, or short peptides formed by condensing various amino acids; and/or

The diacid is selected from the group consisting of oxalic acid, malonic acid, succinic acid, glutamic acid, aspartic acid, ethylenediamine N, N diacetic acid, and N, N dicarboxyethylenediamine.

3. A method for preparing a hydrophobized polysaccharide according to claim 1 or 2, comprising the steps of:

1) cholesterol and connecting molecules are subjected to esterification reaction to generate an intermediate;

2) the polysaccharide or disaccharide and the intermediate are subjected to condensation reaction to generate the hydrophobic polysaccharide.

4. Hydrophobized glucan, characterized in that the structure of the hydrophobized glucan is represented by formula (I):

wherein R is₁、R₂Or R₃Any one of them isThe rest is H, and n is any integer larger than 2.

5. The method for producing a hydrophobized glucan according to claim 4, comprising the steps of:

firstly, reacting succinic acid with glycine protected by carboxyl in an organic solvent, adding a proper amount of catalyst and dehydrating agent, and reacting at the temperature of 0-60 ℃ for 1-96 h to obtain diacetoxy succinamide;

② the carboxyl protection removal of diacetoxy succimide, the specific method is: adding the diacetic acid succinamide into a sodium hydroxide aqueous solution for hydrolysis, neutralizing with a hydrochloric acid aqueous solution, quickly dissociating carboxyl of the diacetic acid succinamide, drying under reduced pressure to remove water, redissolving in an organic solvent, adding a proper amount of a catalyst and a dehydrating agent, and reacting at 0-300 ℃ for 1-96 hours; then adding cholesterol into the reaction system, carrying out esterification reaction, reacting for 1-96 h at 0-300 ℃, adding water to terminate the reaction, and refining and drying the precipitate to obtain an intermediate;

redissolving the intermediate obtained in the step II in an organic solvent, adding glucan, adding a proper amount of catalyst and dehydrating agent, reacting for 1-96 h at 0-300 ℃, filtering the reaction system after the reaction is finished, adding an alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobized glucan.

6. The method of claim 5, wherein the catalyst of steps (i) and (ii) is at least one selected from DMAP, DCC, pyridine, and concentrated sulfuric acid, and the dehydrating agent is selected from phosphorus pentoxide, DCC, molecular sieve, calcium chloride, zinc chloride, magnesium sulfate; and/or

The alcohol solvent is absolute ethyl alcohol or methanol;

preferably, the mole ratio of glucan, succinic acid, glycine and cholesterol is 1-2: 1-2: 2-4: 1-2, preferably 1: 1: 2: 1 or 2: 1: 4: 1.

7. use of the hydrophobized polysaccharide of claim 1 or 2, or the hydrophobized glucan of claim 4 in any one of the following:

a. as a drug delivery vehicle;

b. for the preparation of antibacterial agents;

c. used alone or in combination with other active ingredients for pharmaceutical preparation;

wherein the active ingredient is at least one of traditional Chinese medicine, western medicine and biological medicine.

8. A medicament or composition comprising the hydrophobized polysaccharide of claim 1 or 2, or the hydrophobized glucan of claim 4;

preferably, the medicament or composition comprises bupleurum extract;

more preferably, the weight ratio of hydrophobized polysaccharide or hydrophobized glucan to the bupleurum extract is 500: 1-1: 500, preferably 100: 1-1: 100.

9. the bupleurum aqueous emulsion is characterized in that the bupleurum aqueous emulsion is obtained by mixing and dissolving oleic acid esterified glucan and bupleurum extract in water according to the proportion, using a probe emulsifier or ultrasonic treatment until emulsion is formed, and then dissolving the hydrophobized glucan of claim 4 in water until the hydrophobized glucan is completely dissolved and mixing with the emulsion;

wherein the weight ratio of the hydrophobized glucan, the oleic acid esterified glucan, the bupleurum extract and the water is 1-0.01:0.01-1:0.01-1:97-99.97, preferably 0.1: 0.1: 0.1: 99.7;

the structure of the oleic acid esterified glucan is shown as the formula (II):

wherein R is₁、R₂Or R₃Any two of them are H, the rest aren is any integer greater than 2.

10. The use of the aqueous bupleurum emulsion of claim 9 for any one of the following applications:

(1) used for preparing anti-inflammatory drugs;

(2) is used for preparing antibacterial drugs;

(3) used for preparing antiviral drugs;

(4) is used for preparing anti-tumor drugs;

(5) used for preparing the medicine for treating the immune diseases;

(6) used for preparing diabetes treatment medicines;

(7) for the preparation of a medicament for the treatment of multiple sclerosis;

(8) can be used for preparing washing and caring products.

Technical Field

The invention relates to the field of biomedicine, and particularly relates to a hydrophobized polysaccharide and a preparation method and application thereof.

Background

Representative drugs of current immunomodulators are levamisole and ladder-shaped dragon, which play an antiviral role mainly by inducing an organism to generate interferon. They belong to chemically synthesized small molecule drugs, and have limited clinical applications due to large toxic and side effects. Because of low toxicity and cell targeting, the cholesterol modifier of polysaccharide is widely used in vaccine loading, drug delivery and amino acid and peptide delivery systems as a functional emulsifier, and the research of the cholesterol modifier as an immunomodulator is rarely reported.

Disclosure of Invention

The invention aims to provide a novel hydrophobized polysaccharide, and a preparation method and application thereof.

In order to achieve the object of the present invention, in a first aspect, the present invention provides a hydrophobized polysaccharide having the following general structural formula: G-P-O;

wherein G is polysaccharide or disaccharide, P is a connecting molecule with carboxyl at two ends formed by condensing amino acid and diacid, and O is cholesterol; g and P are connected with hydroxyl on the polysaccharide or disaccharide through ester bonds, and P and O are connected through ester bonds.

The polysaccharide is water-soluble polysaccharide selected from hyaluronic acid, chondroitin sulfate, dermatan sulfate, heparin, water-soluble starch, water-soluble inulin, water-soluble chitosan, water-soluble dextran, water-soluble pullulan, water-soluble mannose, water-soluble algal polysaccharide, water-soluble starch, water-soluble hydroxyethyl dextran, water-soluble levan, water-soluble xyloglucan, water-soluble cellulose, various water-soluble polysaccharides and physiologically active polyhydroxy compounds (such as sialic acid).

The disaccharide can be selected from sucrose, fructose or lactose, etc.

The amino acid can be at least one of glycine, glutamic acid, L-lysine, L-cysteine, DL-alanine, DL-methionine, L-ornithine, gamma-aminobutyric acid, L-aspartic acid, L-theanine, L-arginine, beta-alanine, L-citrulline, L-histidine, leucine, isoleucine, valine, phenylalanine, proline, tryptophan, serine, tyrosine, glutamine, asparagine, histidine and the like, any synthetic amino acid and can also be selected from short peptides (such as diglycine) formed by condensing various amino acids.

The diacid may be selected from the group consisting of oxalic acid, malonic acid, succinic acid, ethylenediamine N, N diacetic acid, and N, N dicarboxyethylenediamine. And any chemically synthesized diacid, and also from amino acids with two carboxyl groups, such as glutamic acid, aspartic acid, etc., and chemically synthesized amino acids with two terminal carboxyl groups.

The cholesterol may be cholesterol of any origin or cholesterol class of compounds, for example, cholesterol of various animal origins or cholesterol having a cyclopentanoperhydrophenanthrene nucleus.

In a second aspect, the present invention provides a method for preparing the hydrophobized polysaccharide, comprising the steps of:

1) cholesterol and connecting molecules are subjected to esterification reaction to generate an intermediate;

2) the polysaccharide or disaccharide and the intermediate are subjected to condensation reaction to generate the hydrophobic polysaccharide.

In a third aspect, the present invention provides a hydrophobized glucan having a structure represented by formula (I):

wherein R is₁、R₂Or R₃Any one of them isThe rest is H, and n is any integer larger than 2.

In a fourth aspect, the present invention provides a method for preparing the hydrophobized glucan, comprising the steps of:

firstly, reacting succinic acid with glycine protected by carboxyl in an organic solvent, adding a proper amount of catalyst and dehydrating agent, and reacting at the temperature of 0-60 ℃ for 1-96 h to obtain diacetoxy succinamide;

② the carboxyl protection removal of diacetoxy succimide, the specific method is: adding the diacetic acid succinamide into a sodium hydroxide aqueous solution for hydrolysis, neutralizing with a hydrochloric acid aqueous solution, quickly dissociating carboxyl of the diacetic acid succinamide, drying under reduced pressure to remove water, redissolving in an organic solvent, adding a proper amount of a catalyst and a dehydrating agent, and reacting at 0-300 ℃ for 1-96 hours; then adding cholesterol into the reaction system, carrying out esterification reaction, reacting for 1-96 h at 0-300 ℃, adding water to terminate the reaction, and refining and drying the precipitate to obtain an intermediate;

redissolving the intermediate obtained in the step II in an organic solvent, adding glucan, adding a proper amount of catalyst and dehydrating agent, reacting for 1-96 h at 0-300 ℃, filtering the reaction system after the reaction is finished, adding an alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobized glucan.

In the method, the catalyst is selected from at least one of DMAP (4-dimethylaminopyridine), DCC (dinitrophenol), pyridine and concentrated sulfuric acid, and the dehydrating agent is selected from inorganic salts such as phosphorus pentoxide, DCC (dicyclohexylcarbodiimide), molecular sieve, calcium chloride, zinc chloride, magnesium sulfate and the like, and the dosage of the inorganic salts is proper.

The alcohol solvent can be absolute ethyl alcohol or methanol and the like, and the amount of the alcohol solvent is proper.

Preferably, the mole ratio of glucan, succinic acid, glycine and cholesterol is 1-2: 1-2: 2-4: 1-2, preferably 1: 1: 2: 1 or 2: 1: 4: 1.

in the method and the step III, the reaction system is filtered, the filter residue is collected and dried, and the DMAP and the byproduct Dicyclohexylurea (DCU) can be recycled.

In a fifth aspect, the invention provides the use of any one of the following:

a. as a drug delivery vehicle;

b. for the preparation of antibacterial agents;

c. can be used alone or in combination with other active ingredients for preparing medicines. For example, the drug can be used for the treatment of itching and beriberi, for the treatment of influenza (influenza virus), and the like.

Wherein the active ingredient can be at least one selected from Chinese medicine, western medicine and biological medicine.

The hydrophobic polysaccharide can be used as a carrier of anti-inflammatory, antibacterial, antiviral and antitumor drugs, amino acids and peptides, and can be used together with various anti-inflammatory drugs, various antibacterial drugs, various antiviral drugs, various antitumor drugs, various amino acids and various peptides for treating various immune diseases. For example, various inflammations, various bacterial infections, various viral infections, various tumors, diabetes, multiple sclerosis, and immune diseases such as myasthenia gravis. And as a skin care product for moisturizing and wrinkle removing and as a hair care product for maintaining the health of hair.

Wherein, the anti-inflammatory drugs, the antibacterial drugs, the antiviral drugs and the antitumor drugs can be traditional Chinese medicines, western medicines or biological medicines.

Wherein, various inflammatory diseases such as dental neuritis, gastritis, enteritis, colitis, hepatitis, rachitis, arthritis, lupus erythematosus, vaginitis, urethritis, allergic inflammation such as nasal mucosa congestive inflammation, lung inflammation caused by immune factor storm, eczema, mite, pruritus caused by mosquito bite, etc.

Among them, various fungal infectious diseases such as bacterial, actinomycete, spirochete, mycoplasma, chlamydia, rickettsia infectious diseases. Fungal infectious diseases such as beriberi, tinea manuum, psoriasis, contact dermatitis, etc.

Wherein the bacteria include pathogenic bacteria such as Escherichia coli including enterohemorrhagic Escherichia coli, Staphylococcus aureus, Medinieria micranthi, Pseudomonas aeruginosa, Coccus destructor, Cholera, Typhus, Chlamydophilaelis dysentery, pneumococcus, pertussis, Corynebacterium diphephiariae, tetanus, Influenza, pestis, botulium, Bacillus anthracis, Lapityriella, Salmonella, VRE, Rhizoctonia, Halloyla, Salmonella typhi, Salmonella Paratyphi, Chlamydophila, Ameba, Legiella, Lymerrelliosis, Broccosis (Pyrola) and the like; coxiella bernetetiQ heat, Chlamydia, and other Rickettsia; protozoa such as malaria pathogenic protozoa and cryptosporidium tyzzer; fungi such as cryptococcosis and aspergillosis.

Among them, various kinds of viral infectious diseases such as neocoronavirus, HPV virus, influenza virus, such as influenza a type, influenza type, hepatitis C virus, hepatitis a virus, hepatitis B virus, Rotavirus, cytomegavirus: infectious diseases such as CMV virus, RS virus, heat of throat and head membrane, HIV virus, varicella zoster virus, Herpes simplex virus type 1 and type 2, ATL (adult T cell leukemia) virus, Coxsackie virus, entero virus, Herpes burst virus, measles virus, rubella virus, epidemic infraauricular adenovirus virus, acute gray white myelitis virus, Japanese encephalitis virus, rabies virus, hepatitis C virus, Norwalk virus, rabies virus, RS virus, Cytomegalovirus, foot and mouth disease virus, transmissible gastroenteritis virus, rubella virus, ATL virus, adeno virus, Echovirus, Herpes virus, natural poxvirus, denguefer fever virus, yellow fever virus, WestNilevirus, SARS virus, Ebola hemorrhagic fever, Marburghemorrhizange virus, Lassevesaffer virus, Handvirus and Nivirus.

The treatment of various tumors includes various cell types of lung cancer, nasopharyngeal carcinoma, intestinal cancer, skin cancer, oral cancer, breast cancer, head and neck cancer, pancreatic cancer and other various tumor diseases.

The amino acids may be derived from animals or plants. The peptides can be any of peptides of microbial origin, chemically synthesized peptides, biologically extracted peptides.

Further, the hydrophobized polysaccharide serves as a carrier for the active ingredient; it can be used in combination with other conventional medicinal carriers or medicinal emulsifying agents.

Furthermore, the hydrophobic polysaccharide is used for preparing medicines or antibacterial and miliaria-removing antipruritic agents.

Wherein the active component comprises bupleurum root extract which specifically comprises saikoside and bupleurum polysaccharide.

In a sixth aspect, the present invention provides a medicament or composition comprising the hydrophobized polysaccharide, or the hydrophobized glucan.

Preferably, the medicament or composition comprises bupleurum extract; or the active ingredients of the medicine or the composition comprise total saikosaponin and bupleurum polysaccharide.

More preferably, the weight ratio of hydrophobized polysaccharide or hydrophobized glucan to the bupleurum extract is 500: 1-1: 500, preferably 100: 1-1: 100.

in a seventh aspect, the invention provides a bupleurum aqueous emulsion, which is obtained by mixing and dissolving the hydrophobized glucan, the oleic acid esterified glucan and the bupleurum extract in water according to a proportion and using a probe emulsifier or ultrasonic wave for treatment.

Wherein the weight ratio of the hydrophobized glucan, the oleic acid esterified glucan, the bupleurum extract and the water is 1-0.01:0.01-1:0.01-1:97-99.97, preferably 0.1: 0.1: 0.1: 99.7.

the structure of the oleic acid esterified glucan is shown as the formula (II):

wherein R is₁、R₂Or R₃Any two of them are H, the rest aren is any integer greater than 2. The oleic acid esterified glucan is hydrophobic polysaccharide in ZL 201910418160.0.

The bupleurum aqueous emulsion has an average particle size of 0-1000 nm.

In an eighth aspect, the invention provides any one of the following uses of the aqueous emulsion of bupleurum:

(1) used for preparing anti-inflammatory drugs;

(2) is used for preparing antibacterial drugs;

(3) used for preparing antiviral drugs;

(4) is used for preparing anti-tumor drugs;

(5) used for preparing the medicine for treating the immune diseases;

(6) used for preparing diabetes treatment medicines;

(7) for the preparation of a medicament for the treatment of multiple sclerosis;

(8) can be used for preparing washing and caring products.

By the technical scheme, the invention at least has the following advantages and beneficial effects:

the hydrophobized polysaccharide provided by the invention has immunoregulation performance, and can play a role in immunoregulation together with the bupleurum extracts (saikoside and bupleurum polysaccharide).

And (II) the raw materials used for synthesizing the hydrophobic polysaccharide are safe and nontoxic, and can be used in the fields of food and medicines. The hydrophobized polysaccharide is nontoxic, can be completely decomposed in nature, and has no acute toxicity or long-term toxicity.

The hydrophobic polysaccharide modifier belongs to a novel high-efficiency drug delivery carrier, the prepared liquid medicine has high pharmacological activity, is stronger than that of the traditional drug delivery system, and has remarkable pharmacological effect when being a trace amount of liquid medicine, and has the characteristic of one-time cure without relapse due to belonging to an immunoregulatory drug.

Drawings

FIG. 1 shows the results of nuclear magnetic measurements of hydrophobized dextran modifications prepared in the preferred embodiment of the present invention.

FIGS. 2-4 show lung pathology in the placebo, model and drug-administered groups, respectively, in accordance with a preferred embodiment of the present invention.

Detailed Description

The invention provides a novel hydrophobized polysaccharide, a preparation method thereof and application of the hydrophobized polysaccharide as an immune regulation substance in the aspect of pharmaceutical preparation. Such hydrophobized polysaccharides (also called hydrophobized polysaccharide modifications) have various physiological activities, such as anti-immune, immune enhancing activity. Can be used as carriers of antiinflammatory, antibacterial, antiviral, antitumor, amino acids, and peptides, and can be used together with antiinflammatory, antibacterial, antiviral, antitumor, amino acids, and peptides for treating various immune diseases. For example, various inflammations, various fungal infections, various viral infections, various tumors, diabetes, multiple sclerosis, and immune diseases such as myasthenia gravis; and as a skin care product for moisturizing and wrinkle removing and as a hair care product for protecting the health of hair. Can also be used alone for treating various immunological diseases. For example, various inflammations, various bacterial infections, various viral infections, various tumors, diabetes, multiple sclerosis, and immune diseases such as myasthenia gravis; and as a skin care product for moisturizing and wrinkle removing and as a hair care product for maintaining the health of hair.

The invention adopts the following technical scheme:

the molecular general formula of the hydrophobized polysaccharide provided by the invention is as follows: G-P-O, consisting of three parts:

(1) a water-soluble polysaccharide;

(1) a linking molecule (linking arm) having carboxyl groups at both ends, which is formed by condensing amino acid and diacid;

(3) cholesterol.

Wherein G is polysaccharide or disaccharide (as hydrophilic group), P is a molecular fragment (as connecting arm) with two carboxyl groups at two ends and formed by condensation of diacid and two amino acids, and O is cholesterol (as hydrophobic group); preferably, G is dextran and P is diacetoxy succinamide. G and P are connected with hydroxyl on the polysaccharide through ester bonds, and P and O are connected through ester bonds.

The connecting arm is a molecular fragment formed by condensing amino acids and diacids. The amino acid is selected from at least one of glycine, glutamic acid, L-lysine, L-cysteine, DL-alanine, DL-methionine, L-ornithine, gamma-aminobutyric acid, L-aspartic acid, L-theanine, L-arginine, beta-alanine, L-citrulline, L-histidine, leucine, isoleucine, valine, phenylalanine, proline, tryptophan, serine, tyrosine, glutamine, asparagine, histidine, and the like, and any synthetic amino acid, and may be selected from short peptides obtained by condensing various amino acids. The diacids are selected from oxalic acid, malonic acid, succinic acid, ethylenediamine N, N-diacetic acid and N, N-dicarboxyethylenediamine, and any chemically synthesized diacids, and also from amino acids with two carboxyl groups such as glutamic acid, aspartic acid, and the like, and chemically synthesized amino acids with two terminal carboxyl groups.

The hydrophobic polysaccharide modifier is a functional polysaccharide which takes glucan as a hydrophilic group, takes cholesterol as a hydrophobic group and takes diacetoxy succinamide (a connecting arm) as a loading group through condensation reaction of the glucan and the cholesterol ester intermediate.

In the present invention, the polysaccharide is at least one selected from hyaluronic acid, chondroitin sulfate, dermatan sulfate, heparin, water-soluble starch, water-soluble inulin, water-soluble chitosan, water-soluble dextran, water-soluble pullulan, water-soluble mannose, water-soluble algal polysaccharide, water-soluble starch, water-soluble hydroxyethyldextran, water-soluble fructan, water-soluble xyloglucan, water-soluble cellulose, and various water-soluble polysaccharides, and may be a polyhydroxy compound (e.g., sialic acid) having physiological activity.

The disaccharide is sucrose, fructose or lactose.

Preferably, in the general formula G-P-O, G is glucan, P is diacetoxy succinamide, and the structure of the hydrophobic polysaccharide is shown in the formula (I). The hydrophobic polysaccharide is formed by reacting hydroxyl of cholesterol with one end carboxyl of diacetoxy succinamide, firstly preparing acetic acid succinyl cholesterol ester, and then reacting with glucan to esterify the other end carboxyl of the connecting arm with glucan to obtain a hydrophobic glucan modifier (hydrophobic glucan).

The invention also provides a preparation method of the hydrophobized polysaccharide modifier, which comprises the following steps:

1) condensation of diacid and amino acid to produce molecular fragment with terminal carboxyl as connecting arm;

2) the hydroxyl group of cholesterol and the carboxyl group at one end of the connecting arm are subjected to esterification reaction to generate a cholesterol esterified connecting arm;

3) the hydroxyl groups on the polysaccharide are condensed with the terminal carboxyl groups on the linking arms esterified with cholesterol via ester bonds.

The hydrophobized polysaccharide of the formula (1) is prepared by the following method:

firstly, reacting succinic acid with glycine protected by carboxyl in an organic solvent, adding a proper amount of catalyst and dehydrating agent, and reacting at the temperature of 0-60 ℃ for 1-96 h to obtain diacetoxy succinamide;

② the carboxyl protection removal of diacetoxy succimide, the specific method is: adding the diacetic acid succinamide into a sodium hydroxide aqueous solution for hydrolysis, neutralizing with a hydrochloric acid aqueous solution, quickly dissociating carboxyl of the diacetic acid succinamide, drying under reduced pressure to remove water, redissolving in an organic solvent, adding a proper amount of a catalyst and a dehydrating agent, reacting at 0-300 ℃ for 1-96 h, adding cholesterol, carrying out an esterification reaction, reacting at 0-300 ℃ for 1-96 h, adding water to terminate the reaction, and refining and drying a precipitate for later use;

dissolving the refined product obtained in the step II in an organic solvent, adding glucan, adding a proper amount of catalyst and dehydrating agent, reacting for 1-96 h at 0-300 ℃, filtering the reaction system after the reaction is finished, adding an alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobic glucan modifier.

In the above method, the organic solvent in step (i) is at least one selected from the group consisting of toluene, xylene, dimethylformamide, dimethylsulfoxide, and dichloromethane.

In the method, the catalysts are DMAP (4-dimethylaminopyridine) and DCC (dicyclohexylcarbodiimide), the dehydrating agent is DCC, and the amount of the dehydrating agent and the DCC is proper. In addition, the catalyst can also be selected from pyridine and concentrated sulfuric acid; the dehydrating agent can be selected from inorganic salts such as phosphorus pentoxide, molecular sieve, calcium chloride, zinc chloride, magnesium sulfate, etc.

In the method, the alcohol solvent is absolute ethyl alcohol or methanol, and the amount of the alcohol solvent is proper.

In the method, the molar ratio of the glucan to the succinic acid to the glycine to the cholesterol is 1-2: 1-2: 2-4: 1-2, preferably 1: 1: 2: 1 or 2: 1: 4: 1.

in the method and the step III, the reaction system is filtered, the filter residue is collected and dried, and the DMAP and the byproduct Dicyclohexylurea (DCU) can be recycled.

The invention also provides any one of the following applications of the hydrophobized polysaccharide modifier or the hydrophobized polysaccharide modifier prepared by the method:

a. as an active ingredient in combination with an immunomodulatory drug;

b. as an immunomodulator drug alone;

wherein the active ingredients comprise traditional Chinese medicines, western medicines and biological medicines.

The hydrophobic polysaccharide modifier provided by the invention can be used in combination with other medicines.

The invention also provides a medicament or a composition containing the modified hydrophobic polysaccharide or the modified hydrophobic polysaccharide prepared by the method and at least one active ingredient.

Preferably, the active ingredients are total saikosaponin and bupleurum polysaccharide.

The weight ratio of the hydrophobization polysaccharide modifier to the total saponins of bupleurum and the bupleurum polysaccharide is 100: 1-1: 100, preferably 10: 4-10: 50.

more preferably, the medicament or the composition is an aqueous emulsion, and the average particle size is 0-1000 nm, preferably below 500 nm. The weight ratio of the hydrophobized polysaccharide to the total saponins of Chinese thorowax root and the Chinese thorowax root polysaccharide is 10: 1-10: 100, preferably 10: 4-10: 50.

more preferably, the pharmaceutical or composition is in the form of an aqueous solution.

The invention also provides a preparation method of the medicine or the composition, which comprises the following steps: dissolving the hydrophobic polysaccharide modifier in water, adding bupleuri radix total saponin and bupleuri radix polysaccharide, completely dissolving, and treating with probe emulsifier or ultrasonic wave until forming stable emulsion in water or solution.

The invention also provides application of the aqueous emulsion prepared from the hydrophobization polysaccharide modifier, the bupleurum total saponin and the bupleurum polysaccharide in the aspects of mosquito bite itching relieving, beriberi, tinea manuum and contact dermatitis treatment.

The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention. Unless otherwise specified, the technical means used in the examples are conventional means well known to those skilled in the art, and the raw materials used are commercially available products.

The bupleurum extract in the following embodiments comprises bupleurum total saponin and bupleurum polysaccharide, and is prepared according to the method of the literature (Zhangguo pine, Guangxianghua, and Xiaojijiao, etc.. the extraction process of bupleurum total saponin is optimized [ J ]. China experimental and prescriptions J.2011 (12): 17-20): adding 8 times of 80% ethanol into bupleuri radix powder, adjusting pH to 8, heating and reflux-extracting at 80 deg.C for 2 times, each for 1 hr, and distilling under reduced pressure to remove solvent to obtain bupleuri radix total saponin. Dissolving the residues in water, soaking at 50 deg.C for 1 hr, concentrating under reduced pressure, and drying to obtain bupleuri radix polysaccharide.

Example 1 hydrophobized Glucan modification and method of making the same

The hydrophobized polysaccharide prepared in this embodiment is prepared by synthesizing a diacetoxy succinamide linking arm, reacting the hydroxyl group of cholesterol with a carboxyl group at one end of the linking arm to prepare cholesterol esterified diacetoxy succinamide, and reacting the cholesterol esterified diacetoxy succinamide with dextran to obtain a hydrophobized dextran modifier. The preparation method comprises the following steps:

1. dissolving 100g (0.01mol) of succinic acid in 2L of toluene, adding 0.02mol of glycine protected by carboxyl, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, reacting at room temperature for 48h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 2L of absolute ethyl alcohol to obtain a white precipitate, namely diacetoxysuccinamide.

2. The carboxyl protection removal of diacetoxy succinamide comprises the following steps: adding 100g of diacetoxy succinamide into 1L of 1N aqueous solution of NAOH to react for 2h at room temperature, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, removing the carboxyl of the diacetoxy succinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 2L of toluene, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, adding 0.01mol of cholesterol to react for 48h at room temperature, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Dissolving 100g of the refined product obtained in the step 2 in 2L of toluene solution, adding 0.01mol of glucan, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, reacting at room temperature for 48h, filtering the reaction system after the reaction is finished, adding 2L of absolute ethyl alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobic polyglucan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

Example 2 hydrophobized Glucan modification and method of making the same

The preparation method comprises the following steps:

1. dissolving 100g (0.02mol) of succinic acid in 4L of toluene, adding 0.04mol of glycine protected by carboxyl, adding 2g of catalyst DMAP and 20g of dehydrating agent DCC, reacting at 40 ℃ for 24h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 4L of absolute ethyl alcohol to obtain a white precipitate, namely diacetoxysuccinamide.

2. The carboxyl protection removal of diacetoxy succinamide comprises the following steps: adding 100g of diacetoxy succinamide into 1L of 1N NaOH aqueous solution to react for 2h at room temperature, adding 50mL of 1N HCl aqueous solution to neutralize the rest sodium hydroxide, dissociating carboxyl of the diacetoxy succinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 4L of toluene, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, adding 0.02mol of cholesterol to react for 24h at 40 ℃, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Dissolving 100g of the refined product obtained in the step 2 in 4L of toluene solution, adding 0.01mol of glucan, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, reacting at 40 ℃ for 24h, filtering the reaction system after the reaction is finished, adding 4L of absolute ethyl alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobic polyglucan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

Example 3 hydrophobized Glucan modification and method of making the same

The preparation method comprises the following steps:

1. dissolving 100g (0.015mol) of succinic acid in 1L of toluene, adding 0.03mol of glycine protected by carboxyl, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, reacting at 50 ℃ for 12h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 1L of absolute ethyl alcohol to obtain a white precipitate, namely diacetoxy succinamide.

2. The carboxyl protection removal of diacetoxy succinamide comprises the following steps: adding 100g of diacetoxy succinamide into 1L of 1N aqueous solution of NAOH to react for 2h at room temperature, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, removing the carboxyl of the diacetoxy succinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 1L of toluene, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, adding 0.015mol of cholesterol to react for 12h at 50 ℃, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Dissolving 100g of the refined product obtained in the step 2 in 1L of toluene solution, adding 0.01mol of glucan, adding 0.13g of catalyst DMAP and 1.3g of dehydrating agent DCC, reacting at 50 ℃ for 12h, filtering the reaction system after the reaction is finished, adding 1L of absolute ethyl alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobic polyglucan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

The nuclear magnetic detection data of the hydrophobized dextran modifier prepared in examples 1 to 3 are as follows;

¹HNMR(400MHz，D₂o)1.25, 1.40, 1.45ppm (cholesterol), 2.73, 2.86, 3.02ppm (succinic acid), 3.44-5.35 ppm (dextran and glycine), specifically: the absorption peaks at 1.25ppm, 1.40ppm and 1.45ppm are derived from cholesterol, the absorption peaks at 2.73ppm, 2.86ppm and 3.02ppm are derived from succinic acid and the absorption peaks at 3.44-5.35 ppThe absorption peaks for m are from dextran and glycine (figure 1).

Example 4 aqueous emulsion of Bupleurum and method for preparing the same

10g of oleic acid esterified glucan (namely ZL201910418160.0 hydrophobic glucan in the specification of example 1) is dissolved in 1L of water, 10g of radix bupleuri extract is added, a probe emulsifier or ultrasonic wave is used for processing until polydisperse aqueous emulsion is formed, 10g of hydrophobic glucan modifier prepared in example 1 is dissolved in 3L of water to be completely dissolved, and the two solutions are mixed to obtain the aqueous radix bupleuri emulsion.

EXAMPLE 5 aqueous emulsion of Bupleurum and method for preparing the same

10g of oleic acid esterified glucan (namely ZL201910418160.0 hydrophobic glucan in the specification of example 1) is dissolved in 1L of water, 10g of radix bupleuri extract is added, a probe emulsifier or ultrasonic wave is used for processing until polydisperse aqueous emulsion is formed, 10g of hydrophobic glucan modifier prepared in example 1 is dissolved in 4L of water to be completely dissolved, and the two solutions are mixed to obtain the aqueous radix bupleuri emulsion.

Example 6 aqueous emulsion of Bupleurum and method for preparing the same

5g of oleic acid esterified glucan (namely ZL201910418160.0 hydrophobic glucan in the specification of example 1) is dissolved in 2L of water, 5g of radix bupleuri extract is added, a probe emulsifier or ultrasonic wave is used for treatment until polydisperse aqueous emulsion is formed, 20g of hydrophobic glucan modifier prepared in example 1 is dissolved in 2L of water to be completely dissolved, and the two solutions are mixed to obtain the aqueous radix bupleuri emulsion.

In examples 4 to 6, the oleic acid esterified glucan, the aqueous emulsion of the bupleurum extract and the aqueous solution of the hydrophobic glucan modifier are uniformly mixed, subjected to ultrasonic treatment for 5 minutes, filtered by a 0.22 micron filter membrane, subjected to ultraviolet sterilization and then filled. In the preparation of the aqueous bupleurum emulsion of the embodiments 4 to 6, firstly, the oleic acid esterified glucan and the bupleurum extract are emulsified to fully dissolve and emulsify the bupleurum total saponin, and then, the oleic acid esterified glucan and the bupleurum extract are mixed with the water solution of the hydrophobized glucan modifier. Thus, the interference of the bupleurum root extract on the drug effect of the hydrophobized glucan modifier can be avoided, the curative effect can be improved, and the cost can be reduced.

The stability test result of the bupleurum aqueous emulsion is as follows:

10ml of each of 3 batches of samples are taken and placed in the temperature of 40 plus or minus 2 ℃, 25 plus or minus 2 ℃ and 20 plus or minus 2 ℃ for 3 months respectively, and the properties, the content and the microbial limit are not obviously changed.

Nasal irritation test of aqueous bupleurum emulsions the following:

10 Kekang rats with the body mass of 300 +/-20 g and half of male and female are selected and provided by the laboratory animal center of the Unionidae medical college. The liquid medicine is atomized and inhaled for 30 minutes by an atomizer in a sealed box, and rats have no discomfort or allergic symptoms.

EXAMPLE 7 therapeutic Effect of aqueous emulsion of Bupleurum on pruritus

1. Drug administration and evaluation method

The application and evaluation methods are carried out according to the literature (quality control and curative effect observation of the liniment [ J ]. practical medicine and clinic [ 2010, 13 (1): 36-38). 21 volunteers recruited from pharmacies, hospitals and schools to cause itching due to mosquito bites were treated by applying the aqueous bupleurum emulsion and the hydrophobized dextran solution. The medicine is applied only 1 time, and each time, 1.5mg is applied. The itching relieving effect is observed within three minutes, and the curative effect is investigated within one week. The test standards of the curative effect of the volunteers are divided into four types of cure, obvious effect, effective and ineffective. And (3) healing: the pruritus of the volunteer is cured, and the skin red and swollen disappears; the effect is shown: the pruritus of the volunteer is cured, and the red and swollen part of the skin is subsided; the method has the following advantages: the pruritus of the volunteers is relieved, and the red and swollen part of the skin is faded; and (4) invalidation: the itching of the volunteers was not relieved, and the red and swollen parts of the skin were not resolved.

2. Results

After 10 volunteers suffering from pruritus caused by mosquito bites are treated by one-time smearing with the bupleurum aqueous emulsion, 6 volunteers are cured, accounting for 60 percent; the treatment effect of 4 patients is obvious, 40%; the total effective rate is 100%. Total effective rate is [ < ten effective recovery + effective ] ÷ 10 × 100%. Volunteers were 56 years old at maximum and 20 years old at minimum, and the therapeutic effect was not clearly correlated with age (table 1).

TABLE 1 therapeutic effect of aqueous emulsion of Bupleurum root on pruritus

No adverse reaction occurred after 10 volunteers applied the liquid medicine once (Table 2).

TABLE 2 aqueous emulsion safety evaluation of Bupleurum

EXAMPLE 8 therapeutic Effect of Hydrophobized aqueous dextran solution on pruritus

1. The evaluation of the therapeutic effect of hydrophobized aqueous dextran solution on pruritus was carried out according to example 7. The concentration of the hydrophobized dextran aqueous solution was the same as that of the bupleurum aqueous emulsion of example 7, i.e. the content ratio of the hydrophobized dextran was the same as the sum of the weight of the bupleurum extract, the oleic acid esterified dextran and the hydrophobized dextran contained in the bupleurum aqueous emulsion, and the value was 3 mg/mL.

2. Results

After 11 volunteers suffering from pruritus caused by mosquito bites are subjected to one-time smearing treatment by using hydrophobized glucan, 9 volunteers are cured, accounting for 81.8%; the treatment effect of 2 patients is obvious, accounting for 18.2%; the total effective rate is 100%. Total effective rate ═ ten significant effects on recovery + effective ÷ 11 × 100%. Volunteers were 60 years old at maximum and 20 years old at minimum, and the efficacy was not clearly correlated with age (table 3).

TABLE 3 Effect of hydrophobized dextran on the treatment of itching

No adverse reaction occurred in any of the 11 volunteers after applying the liquid medicine at one time (Table 4).

TABLE 4 evaluation of safety of hydrophobized glucan

Example 9 therapeutic Effect of aqueous emulsion of Bupleurum on beriberi, tinea manuum, and contact dermatitis

1. Drug administration and evaluation method

The medication and the evaluation method are carried out according to the literature reference (quality control and clinical curative effect analysis of the Zea Guishan dexamethasone acetate liniment [ J ]. Chinese medical guidance 2013, 11 (32): 180-. 12 patients with beriberi, tinea manuum and contact dermatitis are gathered from drugstores, hospitals and schools and are treated by applying the bupleurum aqueous emulsion. The medicine is applied only 1 time, and each time, 1.5mg is applied. The itching relieving effect is observed within three minutes, and the curative effect is investigated within one week. The detection standards of the curative effect of patients with beriberi, tinea manuum and contact dermatitis are four types of cure, obvious effect, effective and ineffective. And (3) healing: the skin lesion of the patient is completely removed, and the pruritus is cured; the effect is shown: the skin damage of the patient is reduced by more than 70%, and the pruritus is improved; the method has the following advantages: the tip recession of the skin of a patient suffering from the diseases is 30-69%, and the pruritus is relieved; and (4) invalidation: the skin lesion of the patient is reduced to be below 30 percent, or the symptom is not obviously improved, and the pruritus is not reduced.

2. Results

After 12 patients with beriberi, tinea manuum and contact dermatitis are treated by one-time smearing with the bupleurum aqueous emulsion, 9 patients are cured, accounting for 75 percent; 1 patient had significant effect, 8.3%; 1 patient was therapeutically effective, 8.3%; 1 patient failed, 8.3%; the total effective rate is 91.7%. Total effective rate is [ < ten effective recovery + effective ] ÷ 12 × 100%. Volunteers were 56 years old at maximum and 21 years old at minimum, and the efficacy was not clearly correlated with age (table 5).

TABLE 5 therapeutic effect of aqueous emulsion of Bupleurum on beriberi, tinea manuum, and contact dermatitis

No adverse reaction occurred after one-time smearing of 12 patients with the bupleurum aqueous emulsion (Table 6).

TABLE 6 aqueous emulsion safety evaluation of Bupleurum

Compared with the clinical common hormone medicine dexamethasone, the bupleurum aqueous emulsion has obvious advantages for treating pruritus and beriberi. In terms of administration time, the aqueous emulsion of Bupleurum root is administered in a single dose of 1.5mg, while dexamethasone is administered in a total dose of 3.0mg per week. In the aspect of curative effect, the curative ratio and the total effective rate of the bupleurum aqueous emulsion are obviously higher than those of a dexamethasone treatment group, and the bupleurum aqueous emulsion has the advantage of no relapse after recovery. In the aspect of safety, the bupleurum extract, the oleic acid esterified glucan of the complex and the hydrophobized glucan modifier of the complex in the bupleurum aqueous emulsion are food and pharmaceutical grade compounds, so that the safety is guaranteed, the effect is achieved by one-time medication, and the risk of long-term medication is avoided. Dexamethasone, on the other hand, has serious adverse reactions in the case of long-term administration (Table 7).

TABLE 7 comparison of the efficacy of the aqueous emulsion bupleurum treatment, hydrophobized dextran treatment and the dexamethasone treatment control (example,%)

The difference of the total effective rate of the treatment group and the control group has statistical significance (P is less than 0.01).

Example 10 transnasal therapeutic Effect of aqueous emulsion of Bupleurum on wind-cold type common Cold model mice

Female mice were 36, body weights (20. + -.2) g. Mice were purchased from the animal center of Bengbu medical institute, housed in the animal house of Bengbu medical institute, freely fed and drunk, observed for quarantine, adaptively fed for 3 days, weighed, and randomly divided into 3 groups, i.e., a blank control group, a model group, and a Bupleurum aqueous emulsion treatment group (1.5 mg per administration), each group consisting of 12 mice. Mouse contamination box (polystyrene material, specification 330mm x 215mm x 200mm), sulfur dioxide preparation: concentrated sulfuric acid and sodium bisulfite. Mice in the model group and the administration group were infected with the virus 10 am every day, and the mice were free to eat the drinking water the rest of the time.

The specific contamination method comprises the following steps:

the experiment adopts a static contamination mode, SO₂The concentration is (28 +/-2) mg/m³. The mice are grouped and placed in a mouse contamination box (330mm multiplied by 215mm multiplied by 200mm), and the other parts of the contamination box except for the stomata are in a sealed state. 2.5g of sodium bisulfite is taken each time and put into concentrated sulfuric acid for reaction, air holes are naturally sealed until SO is obtained₂After five minutes of diffusion in the toxicant exposure chamber, the stomata were opened again and the mice were removed. Contamination is carried out in a ventilated kitchen. The mice of the model group and the administration group start to inject 2mg/kg of estradiol benzoate diluted solution into the abdominal cavity from the 14 th day after two weeks of drug exposure for 7 days, and are blown for 5 minutes at 18 ℃ after the injection for the last 3 days to prepare the mouse cold model.

Animals were sacrificed and harvested:

after the end of day 21 after the infection treatment, the animals were fasted and freely drunk water for 20 hours, and at 8 o' clock in the next morning, the mice in the blank control group and the model group were sacrificed by cervical spine removal after weighing. Immediately opening the chest cavity of the mouse, and visually observing the shape, texture, color, presence or absence of obvious pulmonary fibrosis nodules and other changes of the two lungs. The lungs were immediately harvested and weighed after 5mL of ice-cold saline was injected from the right ventricle and lavage of the lungs through pulmonary circulation several times until both lungs were white. And taking the left lung of the mouse to prepare a pathological lung section. The liquid medicine treatment group was prepared into lung sections in the same manner after the treatment was completed.

As a result:

and (3) molding by using 24 Kunming mice, removing 8 dead mice in the middle of the molding failure, and successfully molding 16 mice. But then appearMice were sacrificed and then the model group mice were all sacrificed and blood leukocytes were counted. Every other day, the bupleurum aqueous emulsion is atomized and inhaled for 10 minutes for two weeks in succession for the mice in the administration group, after the administration is finished, the normal group (8) and the mice in the administration group (6) are all killed after the neck is removed, the white blood cells are taken out for counting, and the lung is taken as the pathology. The white blood cell counts of the normal mice and the administration mice are approximately the same, and the white blood cell count of the model mice is obviously higher. The lung pathology is shown in fig. 2-4. The lung tissue of the mice in the normal group is small, and the alveoli are normal. The lung tissue of the model group mice is larger and the pulmonary alveoli are larger, which indicates that the SO is larger₂The acute inflammation caused by the inflammation is successfully modeled. The lung tissue and the alveoli of the mice in the administration group are obviously larger, which indicates that the pulmonary emphysema and the alveoli of the mice are enlarged due to the capillary inflammation, but the survival period of the mice in the administration group can be prolonged by the administration treatment.

At present, most of medicines for treating immune diseases are small molecular medicines, for example, antifungal medicines such as Daktarin cream and the like are selected for treating beriberi, and the antipruritic effect is poor and the beriberi is easy to relapse. The bupleurum aqueous emulsion has exact effects of quickly relieving itching caused by mosquito bites and treating beriberi, tinea manuum and contact dermatitis. And has the characteristics of one-time cure and no relapse.

At present, specific medicines, such as a nasal drop for treating cold nasal obstruction, are also lacked for treating influenza (influenza virus), and the curative effect is poor. The bupleurum aqueous emulsion has pharmacological action of resisting influenza virus. One common cold treating case, one common cold recovering case (F30), nasal cavity instillation to treat nasal obstruction fast, reduce common cold symptom and shorten course of disease.

According to the preparation method of the hydrophobized glucan provided by the invention, the following compounds are synthesized, and the synthesis method is specifically shown in examples 11-14.

Example 11 hydrophobized Chitosan modification and method of making same

The hydrophobization chitosan prepared in this embodiment is prepared by synthesizing a diacetoxy succinamide linking arm, reacting the hydroxyl group of cholesterol with a carboxyl group at one end of the linking arm to prepare cholesterol esterification diacetoxy succinamide, and reacting with chitosan to obtain a hydrophobization chitosan modifier. The preparation method comprises the following steps:

1. dissolving 100g (0.01mol) of succinic acid in 2L of toluene, adding 0.02mol of glycine protected by carboxyl, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, reacting at room temperature for 48h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 2L of absolute ethyl alcohol to obtain a white precipitate, namely diacetoxysuccinamide.

2. The carboxyl protection removal of diacetoxy succinamide comprises the following steps: adding 100g of diacetoxy succinamide into 1L of 1N aqueous solution of NAOH to react for 2h at room temperature, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, removing the carboxyl of the diacetoxy succinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 2L of toluene, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, adding 0.01mol of cholesterol to react for 48h at room temperature, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Re-dissolving 100g of the refined product obtained in the step 2 in 2L of toluene solution, adding 0.01mol of chitosan, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, reacting at room temperature for 48h, filtering the reaction system after the reaction is finished, adding 2L of absolute ethyl alcohol into the filtrate, collecting the precipitate, and drying to obtain the hydrophobic chitosan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

The structure of the synthesized hydrophobic chitosan modifier is as follows:

wherein R is₁Or R₂Any one of them isThe balance is H, wherein n is any integer larger than 2.

Example 12 hydrophobized sialic acid-modified substance and method for producing same

The hydrophobized sialic acid prepared in this embodiment is obtained by synthesizing a diacetoxy succinamide linking arm, reacting the hydroxyl group of cholesterol with a carboxyl group at one end of the linking arm to prepare a cholesterol esterified diacetoxy succinamide, and reacting the cholesterol esterified diacetoxy succinamide with sialic acid. The preparation method comprises the following steps:

1. dissolving 100g (0.01mol) of succinic acid in 2L of toluene, adding 0.02mol of glycine protected by carboxyl, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, reacting at room temperature for 48h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 2L of absolute ethyl alcohol to obtain a white precipitate, namely diacetoxysuccinamide.

2. The carboxyl protection removal of diacetoxy succinamide comprises the following steps: adding 100g of diacetoxy succinamide into 1L of 1N aqueous solution of NAOH to react for 2h at room temperature, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, removing the carboxyl of the diacetoxy succinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 2L of toluene, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, adding 0.01mol of cholesterol to react for 48h at room temperature, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Re-dissolving 100g of the refined product obtained in the step 2 in 2L of toluene solution, adding 0.01mol of sialic acid, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, reacting at room temperature for 48h, filtering the reaction system after the reaction is finished, adding 2L of water into the filtrate, filtering to remove the precipitate, adding absolute ethyl alcohol into the system, collecting the precipitate, and drying to obtain the hydrophobized sialic acid modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

The structure of the synthesized hydrophobized sialic acid modifier is as follows:

wherein R is₁、R₂、R₃、R₄、R₅Or R₆Any one of them isThe balance is H, wherein n is any integer larger than 2.

Example 13 hydrophobized Glucan modification and method of making the same

The hydrophobized glucan prepared in this example is obtained by synthesizing a diglycidylsuccinate linking arm, reacting the hydroxyl group of cholesterol with a carboxyl group at one end of the linking arm to prepare cholesteryl esterified diglycidylsuccinate, and reacting the cholesteryl esterified diglycidylsuccinate with glucan to obtain a hydrophobized glucan modifier. The preparation method comprises the following steps:

1. dissolving 100g (0.01mol) of succinic acid in 2L of toluene, adding 0.02mol of carboxyl protected diglycine, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, reacting at room temperature for 48h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 2L of absolute ethyl alcohol to obtain a white precipitate, namely diglycine succinate.

2. The carboxyl protection removal method of the diglycidylsuccinate comprises the following steps: adding 100g of diglycidylsuccinate into 1L of 1N aqueous solution of NAOH to react at room temperature for 2h, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, removing the carboxyl of diglycidylsuccinamide, distilling the reaction system under reduced pressure to remove water, redissolving the reaction system in 2L of toluene, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, adding 0.01mol of cholesterol to react at room temperature for 48h, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Re-dissolving 100g of the refined product obtained in the step 2 in 2L of toluene solution, adding 0.01mol of glucan, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, reacting at room temperature for 48h, filtering the reaction system after the reaction is finished, adding 2L of absolute ethyl alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobized glucan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

The structure of the synthesized hydrophobized glucan modifier is as follows:

wherein R is₁、R₂Or R₃Any one of them isThe balance is H, wherein n is any integer larger than 2.

Example 14 hydrophobized Glucan modification and method of making the same

The hydrophobized glucan prepared in this embodiment is obtained by synthesizing a biglycinyl ethylenediamine N, N diacetate connecting arm, reacting the hydroxyl group of cholesterol with a carboxyl group at one end of the connecting arm to prepare cholesteryl esterified biglycinyl ethylenediamine N, N diacetate, and reacting with glucan to obtain a hydrophobized glucan modifier. The preparation method comprises the following steps:

1. dissolving 100g (0.01mol) of ethylenediamine N, N-diacetic acid in 2L of toluene, adding 0.02mol of glycine protected by carboxyl, adding 1g of catalyst DMAP and 10g of dehydrating agent DCC, reacting at room temperature for 48h, filtering to remove a byproduct dicyclohexylurea, adding a small amount of water into filtrate to terminate the reaction, and adding 2L of absolute ethyl alcohol to obtain a white precipitate, namely bisglycinyl ethylenediamine N, N-diacetic acid ester.

2. The carboxyl protection removal of the diglycine base ethylenediamine N, N diacetate comprises the following specific steps: adding 100g of diglycine ethylenediamine N, N diacetate into 1L of 1N aqueous solution of NAOH to react at room temperature for 2h, adding 50mL of 1N HCl to neutralize the rest sodium hydroxide, dissociating carboxyl of the diglycine ethylenediamine N, N diacetate, decompressing and distilling the reaction system to remove water, redissolving the reaction system in 2L of toluene, adding 0.5g of catalyst DMAP and 5g of dehydrating agent DCC, adding 0.01mol of cholesterol to react at room temperature for 48h, adding water to stop the reaction, and refining and drying the precipitate for later use.

3. Re-dissolving 100g of the refined product obtained in the step 2 in 2L of toluene solution, adding 0.01mol of glucan, adding 0.25g of catalyst DMAP and 2.5g of dehydrating agent DCC, reacting at room temperature for 48h, filtering the reaction system after the reaction is finished, adding 2L of absolute ethyl alcohol solvent into the filtrate, collecting the precipitate, and drying to obtain the hydrophobized glucan modifier.

And (3) filtering and collecting filter residues of the reaction system in the steps 2 and 3 to obtain a byproduct Dicyclohexylurea (DCU), and drying the filter residues for recycling.

The structure of the synthesized hydrophobized glucan modifier is as follows:

wherein R is₁、R₂Or R₃Any one of them isThe balance is H, wherein n is any integer larger than 2.

Although the invention has been described in detail hereinabove with respect to a general description and specific embodiments thereof, it will be apparent to those skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.