JP6875725B2 - Manufacturing methods for asymmetric bilayer lipid molecules, asymmetric organic nanotubes, and asymmetric organic nanotubes - Google Patents

Description

The present invention relates to an asymmetric bilayer lipid molecule containing an aminocarboxylic acid and an asymmetric organic nanotube that is used for encapsulating an active ingredient and can be mass-produced from the asymmetric bilayer lipid molecule.

By self-assembling well-designed amphipathic molecules in a solvent such as water, tubular aggregate structures (hereinafter referred to as "organic nanotubes") are reversibly formed. Since the organic nanotubes have a surface coated with hydrophilic groups, they are easily dispersed in water. In addition, this organic nanotube has a hollow cylinder structure with an inner diameter of about 1 to 100 nm inside, and can enclose small molecules to biomolecules such as proteins and DNA, various nanoparticles, and guest compounds such as drugs.

In addition, organic nanotubes are capable of releasing or sustained release of encapsulated guest compounds in response to external stimuli such as pH, temperature, and light. For this reason, it is attracting attention in application fields such as healthcare, cosmetics, and medical products (Non-Patent Document 1 and Non-Patent Document 2). However, many conventional organic nanotubes have their inner and outer surfaces coated with the same hydrophilic group. Therefore, it has been difficult to selectively and efficiently encapsulate these guest compounds inside the conventional organic nanotubes.

Therefore, mainly the present inventors have developed organic nanotubes (hereinafter sometimes referred to as "asymmetric organic nanotubes") in which the inner surface and the outer surface are coated with different functional groups. This asymmetric organic nanotube has two different hydrophilic portions at both ends of the hydrophobic moiety alkylene chain, and is produced by self-assembly of asymmetric bilayer lipid molecules in an aqueous solvent (Non-Patent Document 3). The lipid molecules form a monomolecular membrane structure in which the molecules are arranged in parallel, or a structure in which they are laminated, by arranging these two hydrophilic parts while selectively forming hydrogen bonds at the time of self-assembly. ..

As a result, asymmetric organic nanotubes having a structure in which bulky sugar residues are arranged on the outer surface and carboxylic acids, amino groups, glycine residues and the like are arranged on the inner surface can be obtained. Therefore, for example, a carboxylic acid-type asymmetric organic nanotube whose inner surface has a negative charge can efficiently produce an inclusion body by simply mixing a guest having a positive surface charge, which has a strong interaction with the inner surface. it can. Representative prior arts of asymmetric organic nanotubes include Patent Documents 1 to 3, Non-Patent Document 4, and Non-Patent Document 6.

According to Patent Document 1, an asymmetric organic tube having an inner diameter of about 20 nm and an inner surface coated with a carboxylic acid can be produced. However, the synthesis of lipids, which are the raw materials for asymmetric organic tubes, requires the use of expensive long-chain dicarboxylic acids and 1-α-bromotetraacetyl glucose (for example, 6400 yen for 5 g), and the total process of 5 steps is about. The yield was as low as about 30%. In addition, a large amount of solvent and silica gel were required, and separation and purification by complicated chromatography were required. Further, the inner surface of the asymmetric organic tube was limited to carboxylic acid.

According to Patent Document 2, asymmetric organic nanotubes having an inner diameter of 8 to 9 nm and an inner surface coated with a carboxylic acid are provided. The synthesis of the raw material lipid is in three steps and can be purified only by reprecipitation. However, as in Patent Document 1, expensive dicarboxylic acids and oligoglycines are indispensable for the synthesis of lipids, and the total yield of lipids is as low as about 15-40%.

According to Patent Document 3, similarly to Patent Document 1, asymmetric organic nanotubes having an inner diameter of 8 to 9 nm and an inner surface coated with a carboxylic acid, an amine, a hydrophobic group or the like are provided. However, the synthesis of lipids, which are the raw materials for asymmetric organic nanotubes, requires at least 4 to 5 steps, and the raw materials for lipids are long-chain dicarboxylic acids and oligoglycines, which are relatively expensive. Furthermore, in order to obtain high-yield and high-purity lipids, it is indispensable to use a monoester derivative (one in which only one carboxylic acid group is ester-protected) that requires synthesis from a long-chain dicarboxylic acid in two steps. Met. Moreover, since 1-glycopyranosylamine has low nucleophilicity and is chemically unstable, the yield of coupling between 1-glycopyranosylamine and a long-chain dicarboxylic acid was as low as 24%.

Non-Patent Document 4 describes a method for producing an asymmetric organic tube using an inexpensive ω-aminocarboxylic acid instead of the dicarboxylic acid. That is, using a lipid obtained by condensing 1-glycopyranosylamine on the carboxylic acid side of inexpensive 12-aminododecanoic acid and triglycine on the amino group side as raw materials, the inner surface is an amino group and the outer surface is a glucose residue. It is possible to form asymmetric organic nanotubes having an inner diameter of 7 to 10 nm each coated with a group.

However, according to the method for producing an asymmetric organic tube described in Non-Patent Document 4, 1-α-bromotetraacetylglucose, which is an expensive sugar protecting group, can be used, and purification by column chromatography can be performed in 5 steps of synthesis. There were synthetic problems such as necessity and the total yield being only 24%. Further, when the dispersion liquid of the asymmetric organic tube is heated, there is a problem that the tube structure is broken at 67 ° C. (For the stability of the asymmetric organic tube, see Non-Patent Document 5).

Non-Patent Document 6 describes the formation of nanotubes by a lipid molecule obtained by dimerizing inexpensive 12-aminododecanoic acid and condensing the ε-amino group of lysine on the carboxylic acid side of the dimer. There is no description of structural analysis or detailed synthesis of this nanotube. However, in general, the use of amino acids having expensive protecting groups is indispensable for the synthesis using amino acids. Further, it is well known that sequential protection / deprotection of amino groups and carboxylic acid groups is indispensable for the synthesis of a dimer of 12-aminododecanoic acid.

Therefore, the synthesis of the lipid molecule requires at least 6 steps using an expensive lysine in which the α-position amino group and the carboxyl group are protected as a raw material, and purification by chromatography is required at each step. Expected to be. Further, the obtained nanotubes were limited to those in which the inner surface was coated with an amino group and the outer surface was coated with an amino group and a carboxyl group of lysine, respectively. As described above, even when 12-aminododecanoic acid is used, a lipid molecule capable of synthesizing organic nanotubes having different inner and outer surfaces inexpensively, easily and in large quantities has not yet been developed.

From the above technical background, it has been strongly desired to develop a lipid molecule capable of solving all the above-mentioned problems and inexpensively synthesizing a large amount of organic nanotubes having different inner and outer surfaces. That is, there has been a strong expectation for the development of lipid molecules that can be produced in a small number of steps using inexpensive raw materials, can be inexpensively purified by simple methods such as reprecipitation and filtration, and can produce organic nanotubes in large quantities at low cost.

Japanese Patent No. 4174702 Japanese Patent No. 5721130 Japanese Patent No. 5807927 U.S. Patent Application Publication No. 2002/137689

Kameda et al., Polymer Papers, Vol.67, No.10, p.560-573 (2010) Kameda et al., "Development of Organic Nanotube Materials and Development of Encapsulation Functions", "Preparation of Micro / Nanocapsules, Sustained Release Control and Application Examples", Chapter 1, "Preparation and Development of Nano / Microcapsules", Section 18. , p.92-100, Technical Information Association, 2014 Shimizu et al., Langmuir, 32, p.12242 (2016) Kameda et al., Chem. Lett., 36, p.896 (2007) Kameda et al., Soft Matter, 4, p.168 (2008) Full Hop et al., J. Am. Chem. Soc., 115, p.1600-1601 (1993) Masuda et al., Langmuir, 20, p.5969 (2004)

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an asymmetric organic nanotube that can be mass-produced at low cost.

The present inventors esterify an intermediate obtained by reacting an amino group such as 12-aminododecanoic acid, which is an inexpensive ω-aminocarboxylic acid, with a lactone derivative of polyhydroxycarboxylic acid, and a carboxylic acid of 12-aminododecanoic acid. By coupling the converted intermediate, the shortest is only a three-step synthesis step including purification such as reprecipitation and filtration, and the total synthesis yield from the raw material is very efficient, about 94%, which will be described later. It has been found that an asymmetric double-headed lipid molecule represented by the general formula 1 can be produced. Furthermore, it was revealed that organic nanotubes are formed by self-assembling these lipid molecules in water, a polar organic solvent, or a mixed solvent thereof. This organic nanotube is an asymmetric organic nanotube whose outer surface is coated with a hydroxyl group derived from lactone and its inner surface is coated with an ester group, and has an inner diameter of about 40 nm.

Surprisingly, when the ester moiety of this lipid molecule is hydrolyzed to a carboxylic acid, the functional group coating the inner surface of the obtained asymmetric organic nanotube can be changed to a carboxylic acid, and an excess of 1 is obtained. It was found that when the ester moiety of this lipid molecule is exchanged for an amide group with 6-hexanediamine or the like, the inner surface of the obtained asymmetric organic nanotube can be changed to an amino group. Further, by simply introducing oligoglycine residues into Y of the general formula 1 described later, the inner diameter is about ½ of the above, about 20 nm, and the inner surface is coated with a carboxylic acid, an ester, an amino group, or the like. We have found that asymmetric organic nanotubes can be formed.

The asymmetrical organic nanotubes thus obtained can encapsulate guest molecules in high yield simply by mixing them with guest molecules having a charge opposite to that of the inner surface. Furthermore, the present inventors have also shown that guest molecules encapsulated in the organic nanotubes can be released by changing the pH. As described above, this asymmetric organic nanotube is made of a lipid that can be easily mass-produced at low cost, and can easily and easily encapsulate the guest in a high yield, and can release the encapsulated guest by changing the pH or the like. It can be expected to be applied in the fields related to cosmetics and pharmaceuticals.

Patent Document 4 describes a synthesis example of 12- (D-gluconoylamino) dodecanoic acid as a compound similar to the asymmetric bilayer lipid molecule represented by the general formula 1 described later. This compound is used as a synthetic intermediate of a compound represented by the general formula 1 described later (corresponding to intermediate 1-a of Example 1 described later), and a desired asymmetric organic nanotube can be obtained from this compound. I know I can't get it. In addition, in the present invention, in the synthesis of this intermediate, the reaction proceeds in a shorter time than in the conventional case only by dispersing the raw material in a small amount of solvent (concentration is about 16 times) and heating as compared with Patent Document 4. However, we found that the desired intermediate could be obtained quantitatively.

The asymmetric bilayer lipid molecule of the present invention is represented by the following general formula 1.

General formula 1 X-NH- (CH ₂ ) _m- CONH- (CH ₂ ) _n- CO-Y

m and n are integers of 5-11. X is an optically active polyhydroxyalkanoyl group. Y is, OH group, an alkoxyl group having 1 to 3 carbon ^{_{atoms, NH- (CH 2) p -NR}} 1 2 groups (p is an integer of 2 to 8, ^{R 1} is hydrogen, methyl or ethyl group, (NH-CH _2- CO) _r- Z group (r is an integer of 1 to 4, Z is an OH group, an alkoxyl group having 1 to 3 carbon atoms, HN- (CH ₂ ) ₂ − NH ₂ groups, or HN- (CH ₂ ) _3- NH ₂ groups), N-tris (hydroxymethyl) methylamino group (NH-C (CH _2- OH) ₃ ), or NH- (CH ₂ ) ^{_{s -N + R 2 2 - (}} CH 2) t -COO - group (s is 2 or 3, ^{R 2} is a methyl or ethyl group, t is a is an integer of 1 to 4) is.

The asymmetric organic nanotube of the present invention is composed of one or more types of asymmetric bilayer lipid molecules of the present invention, and the inner surface and the outer surface are coated with different functional groups. The method for producing asymmetric organic nanotubes of the present invention includes a step of self-assembling one or more types of asymmetric bilayer lipid molecules of the present invention in a liquid. The inclusion body of the present invention has the asymmetrical organic nanotube of the present invention and the guest substance contained in the asymmetrical organic nanotube.

According to the present invention, a group of lipid molecules that are raw materials for asymmetric organic nanotubes, that is, asymmetric bilayer lipid molecules can be synthesized easily and inexpensively. Therefore, asymmetric organic nanotubes can be obtained in large quantities at low cost. In addition, by using this asymmetric double-headed lipid molecule, the outer surface is a hydroxyl group, and the inner surface is a carboxylic acid (negative charge), ester, etc. (hydrophobic), amine (positive charge), betaine (amphoteric), or hydroxyl group (). Hydrophilic) coated asymmetric organic nanotubes are obtained. This asymmetric organic nanotube can contain various guests.

In the electron microscope image (transmission image) of the asymmetric organic nanotube, 1-1 is an image of the ester-type asymmetric organic nanotube obtained in Example 11, and 1-2 is an image of the carboxylic acid-type asymmetric organic nanotube obtained in Example 12. In the electron microscope image (transmission image) of the asymmetric organic nanotube obtained in Example 13, 2-1 is an image of an amine-type asymmetric organic nanotube obtained from compound 1-d, and 2-2 is a betaine obtained from compound 1-e. Image of type asymmetric organic nanotubes 2-3 is an image of betaine type asymmetric organic nanotubes obtained from compound 1-f. In the electron microscope image (transmission image) of the asymmetric organic nanotube obtained in Example 14, 3-1 is an image of a glycine-based asymmetric organic nanotube obtained from compound 1-g, and 3-2 is an image of glycine obtained from compound 1-h. Image of system asymmetric organic nanotubes. The graph which shows the release characteristic at pH 7.4 and pH 5.5 of the inclusion body of rhodamine 6G of the carboxylic acid type asymmetric organic nanotube of Example 15.

Hereinafter, the asymmetric bilayer lipid molecule, the asymmetric organic nanotube, the method for producing the asymmetric organic nanotube, and the clathrate of the present invention will be described with reference to the drawings and examples. The duplicate description will be omitted as appropriate. Further, in the present application, when "~" is described between two numerical values to represent a numerical range, these two numerical values are also included in the numerical range.

(1) Asymmetric bilayer lipid molecule It is generally known that when an amphipathic molecule having a hydrophilic group and a hydrophobic group is heated and dissolved in water and then cooled, it self-assembles by the interaction between the hydrophobic groups. Further, it is known that similar molecules containing an amino group or a carboxyl group as hydrophilic groups self-assemble by interaction between hydrophobic groups when the solubility is lowered by changing the pH of the solvent or the like. Molecules properly designed as shown in the general formula below have different hydrophilic groups at both ends of the hydrophobic group, so the polyhydroxyalkanoyl groups derived from the sugar lactone at the left end, the amide group located in the middle of the central hydrophobic part, and the right end. Specific and multiple hydrogen bonds are formed between the polar groups (CO-Y) of. Therefore, the molecules are arranged in parallel to form a stable solid monolayer structure.

These self-assemblies often only give plate-like or tape-like crystals. However, for example, when the sizes of the hydrophilic parts at both ends of the molecule are different, or when the end of the molecule contains an optically active part, the molecules are twisted little by little in the membrane-like structure, and the difference in size causes the molecules to twist. The membrane is curved, and finally a self-assembled tubular structure is obtained. At this time, since the molecules are arranged in parallel in the membrane, the obtained tube has an asymmetric structure in which different hydrophilic groups are exposed on the inner surface and the outer surface. Almost without exception, it has been clarified by Non-Patent Document 1 and Non-Patent Document 2 that a bulkier hydrophilic group is exposed on the outer surface of the tube and the other hydrophilic group is exposed on the inner surface of the tube.

The asymmetric bilayer lipid molecule according to the embodiment of the present invention is represented by the following general formula 1.

General formula 1 X-NH- (CH ₂ ) _m- CONH- (CH ₂ ) _n- CO-Y

m and n are integers of 5-11. X is an optically active polyhydroxyalkanoyl group. Y is, OH group, an alkoxyl group having 1 to 3 carbon ^{_{atoms, NH- (CH 2) p -NR}} 1 2 groups (p is an integer of 2 to 8, ^{R 1} is hydrogen, methyl or ethyl group, (NH-CH _2- CO) _r- Z group (r is an integer of 1 to 4, Z is an OH group, an alkoxyl group having 1 to 3 carbon atoms, HN- (CH ₂ ) ₂ − NH ₂ group, or _{HN- (CH} 2) a 3 -NH ₂ group), N- tris (hydroxymethyl) methylamino group or ^{_{NH- (CH 2) s -N +}} R 2 2, - (CH 2) _{It is a t-} COO ^- group (s is 2 or 3, R ² is a methyl or ethyl group, and t is an integer of 1-4).

The asymmetric double-headed lipid molecule represented by the above general formula 1 has, for example, a lactone derivative bonded to one end of a dimer of ω-aminocarboxylic acid and a hydrophobic group such as a carboxylic acid, amine or ester at the other end. It is a molecule to which a glycine oligomer chain or the like is bound. Such an asymmetric double-headed lipid molecule can be obtained by using an inexpensive ω-aminocarboxylic acid, a lactone derivative of a polyhydroxycarboxylic acid, or the like, and using only a simple and inexpensive 3 to 6-step process of purification such as reprecipitation and filtration. Can be manufactured.

X is a D-gluconoyl group, m = n = 11 or m = 11 and n = 5, and Y is a methoxy group, an ethoxy group, an OH group, NH- (CH ₂ ) _6- NH ₂ groups, NH- _{(CH 2)} 3 -NMe groups (Me is ^{_{methyl), NH- (CH 2) 3}} -NMe 2 + - (CH 2) -COO - group, or _{(NH-CH 2 -CO) r} -Z groups, ( r is an integer from 1 to 4, Z is OH group, an alkoxyl group having 1 to 3 carbon _{atoms, HN- (CH 2) 2 -NH} 2 group, or _HN- in _{(CH 2)} 3 -NH 2 group Yes), or N-tris (hydroxymethyl) methylamino group is preferred.

As a general rule, the asymmetric bilayer lipid molecule of the present embodiment can be efficiently synthesized with a total yield of about 86% from the raw material through a three- to four-step step and a purification step by reprecipitation. Therefore, asymmetric organic nanotubes can be produced in large quantities and inexpensively from the asymmetric bilayer lipid molecule of the present embodiment. Among the asymmetric bilayer lipid molecules of the present embodiment, the glycine derivative requires 5 or 6 steps for synthesis, and the total yield from the raw material is also 50 to 61%. However, the asymmetric organic nanotubes obtained from this glycine derivative have an excellent advantage that the inner diameter can be controlled to a finer size.

A more specific method for producing the asymmetric bilayer lipid molecule of the present embodiment will be described. In the asymmetric bilayer lipid molecule of the present embodiment, X-NH- (CH ₂ ) _m- COOH (here, a polyhydroxyalkanoyl group in which X is optically active) corresponding to the left side of the above general formula 1 is used as intermediate 1. It is obtained by using NH _2- (CH ₂ ) _n- CO-Y (here, Y is an alkoxyl group having 1 to 3 carbon atoms) corresponding to the right side as intermediate 2 and condensing them.

Intermediate 1 is obtained by heating an optically active lactone and a long-chain aminocarboxylic acid containing a methylene chain having 5 to 11 carbon atoms in an equimolar amount in a solvent such as methanol in the presence of a base such as triethylamine. Obtained quantitatively. Then, the reaction solution can be easily isolated as the desired amine salt by concentrating the reaction solution under reduced pressure or simply cooling the reaction solution. The intermediate 2 is prepared by dispersing a long-chain aminocarboxylic acid containing a methylene chain having 5 to 11 carbon atoms in a predetermined alcohol, adding 1.1 equivalents or more of hydrochloric acid, and heating and refluxing the mixture, or 1. By simply dropping 1 equivalent of thionyl chloride, it can be quantitatively obtained as a hydrochloride or the like. Then, the target substance can be isolated only by distilling off the solvent of the reaction solution.

For the condensation reaction between Intermediate 1 and Intermediate 2, 4- (4,6-dimethoxy-1,3,5-triazine-2-yl) -4-methylmorpholinium chloride (DMT-MM), dicyclohexylcarbodiimide , Or diisopropylcarbodiimide, etc., but DMT-MM, which can carry out a condensation reaction in alcohol in a high yield, is preferable. Even when DMT-MM is used, the reaction proceeds at room temperature or by heating. Further, since the target product precipitates after the reaction, X-NH- (CH ₂ ) _m- CONH- (CH ₂ ) _n- CO-Y can be easily isolated by filtering this.

If X is derived from gluconolactone, can be used as an asymmetric double-headed lipid molecules forming the asymmetric organic nanotube of interest, further OH group to _{Y, NH- (CH 2) p} -NR 1 2 groups (p is It is an integer of 2 to 8, R ¹ is a hydrogen, methyl group, or ethyl group), (NH-CH _2- CO) _r- Z group (r is an integer of 1 to 4, Z is an OH group. , HN- (CH ₂ ) _2- NH ₂ groups, or HN- (CH ₂ ) _3- NH ₂ groups), N-tris (hydroxymethyl) methylamino group , or ^{_{NH- (CH 2) s -N +}} R 2 2 - (CH 2) t -COO - group (s is 2 or 3, ^{R 2} is a methyl or ethyl group, t is 1 to 4 It may be converted to (integer).

That is, among the obtained asymmetric bilayer lipid molecules represented by the general formula 1, for example, compound 1-a (where Y also includes an alkoxyl group having 2 or 3 carbon atoms) (described later in Examples). May be hydrolyzed to convert Y to carboxylic acid compound 1-c (described later in the examples). Further, compound 1-a and compound 1-b (described later in the examples) are mixed with excess diamine, that is, NH- (CH ₂ ) p-NR ¹ ₂ groups (p is an integer of 2 to 8 and R ¹ is an integer of 2 to 8). It is an asymmetric double-headed lipid molecule that is mixed with hydrogen, a methyl group, or an ethyl group), heated, and amidated (hereinafter sometimes referred to as "aminolysis") by an ester exchange reaction between an ester and a diamine compound. Compound 1-d and compound 1-e (both described later in Examples) are obtained.

At this time, as the diamine, ethylenediamine or propylenediamine containing the same primary amine or secondary amine at both ends may be used, but in order to form a hydrogen-bondable -NHCO- type secondary amide, ethylenediamine Is desirable. Further, taking advantage of the fact that aminolysis does not proceed when a tertiary amine is used, for example, when a diamine having a primary amine at one end and a tertiary amine at the other end is used, aminolysis with a primary amino group is selectively promoted. Be done. Since these diamine compounds dissolve the raw material compounds 1-a and 1-b well at room temperature and heating, they may be used as a reaction solvent. After the reaction, these diamines can be removed by concentration under reduced pressure, or if the desired product precipitates at room temperature, it can be removed by filtration. Alternatively, aminolysis can be performed with N-tris (hydroxymethyl) methylamine. In this case, an asymmetric bilayer lipid molecule having a hydroxyl group at Y is obtained.

Further, compound 1-c contains a (NH-CH _2- CO) _r- Z group of a glycine derivative (r is an integer of 1 to 4, and Z is an OH group or an alkoxyl group having 1 to 3 carbon atoms). Can also be condensed with DMT-MM or the like. As a result, compound 1-g (described later in the examples), compound 1-h (described later in the examples) which is a hydrolyzate thereof, and the like can be obtained. Here, when Z is an OH group or an alkoxyl group having 1 to 3 carbon atoms, Z is changed to HN- (CH ₂ ) _2- NH ₂ groups or HN- by aminolysis using an excess of ethylenediamine or propylenediamine. (CH ₂ ) _3- NH ₂ units can also be used.

Furthermore, for example, compound 1-e (i.e. Y is ^{_{NH- (CH 2) p -NR 1}} 2 groups (p is an integer of 2 to 8, ^{R 1} is hydrogen, is methyl group, or ethyl group) ) As a raw material, which is reacted with bromoacetic acid, bromopropionic acid, etc., or after the reaction of compound 1-e with an ester compound of bromoacetic acid or bromopropionic acid, and then hydrolyzed to form a betaine-type lipid. (Z is ^{_{NH- (CH 2) s -N +}} R 2 2 (CH 2) t -COO - group (s is 2-3 integer, ^{R 2} is a methyl or ethyl group, t is 1 It can also be)), which is an integer of ~ 4. Almost all of these elementary reactions proceed in a high yield of 80% or more, and in almost all cases, isolation can be performed by reprecipitation and subsequent filtration, washing, and in the case of high purity, simple vacuum concentration.

For example, in the case of intermediate 1, since the lactone compound is directly reacted with the N-terminal side of the aminocarboxylic acid, intermediate 1 (X-NH- (CH ₂ ) _m- COOH corresponding to the left side of the above general formula 1) Alternatively, the amine salt thereof (the polyhydroxyalkanoyl group derived from the lactone compound corresponds to X) can be synthesized in one step at a higher concentration than before. Therefore, the amount of solvent used can be reduced to about 1/16. It also eliminates the need for the use, introduction and removal of expensive protecting groups for amino groups, which were essential in conventional reactions.

As described above, Intermediate 2 does not require any special synthetic reagent. Furthermore, when DMT-MM or the like is used as a condensing agent for the coupling between Intermediate 1 and Intermediate 2, the obtained compound precipitates, so the target product can be isolated with high yield and high purity simply by filtering. can do. Because of the method for producing an asymmetric bilayer lipid molecule having the above characteristics, it is possible to synthesize an asymmetric bilayer lipid molecule of about 10 g or more at a time even with ordinary laboratory-level equipment.

(2) Asymmetric Organic Nanotube The asymmetric organic nanotube according to the first embodiment of the present invention is composed of one kind of asymmetric bilayer lipid molecule of the present embodiment, and the inner surface and the outer surface are coated with different functional groups. .. The asymmetric organic nanotube according to the second embodiment of the present invention is composed of two or more kinds of asymmetric bilayer lipid molecules of the present embodiment, and the inner surface and the outer surface are coated with different functional groups. The asymmetric organic nanotubes of each embodiment can efficiently encapsulate a guest having a high affinity with the inner surface at a high concentration, and are excellent in sustained release of the guest without damaging the tube structure.

In the asymmetric organic nanotubes of each embodiment, for example, the outer surface is coated with a polyhydroxyalkanoyl group derived from a lactone derivative, only the inner surface is coated with a carboxyl group, an amino group, an ester group, etc., and the inner and outer surfaces are different. It is a type of organic nanotube. The asymmetric organic nanotubes of each embodiment may contain components other than the asymmetric bilayer lipid molecules of the present embodiment, such as additives and unavoidable impurities.

The asymmetric organic nanotube of the first embodiment has a step of self-assembling one kind of the asymmetric bilayer lipid molecule of the present embodiment in a liquid. The asymmetric organic nanotube of the second embodiment has a step of self-assembling two or more kinds of asymmetric bilayer lipid molecules of the present embodiment in a liquid. More specifically, using the asymmetric bilayer lipid molecule represented by the above general formula 1, the outer surface is coated with a hydroxyl group derived from a polyhydroxyalkanoyl group derived from X and the inner surface is derived from Y by the following method. Asymmetric organic nanotubes coated with functional groups can be produced.

Asymmetric organic nanotubes having a carboxylic acid on the inner surface are carboxylic acid-type asymmetric organic nanotubes, asymmetric organic nanotubes having an amino group on the inner surface are amine-type asymmetric organic nanotubes, and asymmetry having a hydrophobic ester group on the inner surface. The organic nanotube is an ester-type asymmetric organic nanotube, the asymmetric organic nanotube having a betaine group consisting of a quaternary ammonium group and a carboxyl group on the inner surface is a betaine-type asymmetric organic nanotube, and the inner surface is a hydrophilic hydroxyl group. Asymmetric organic nanotubes may be referred to as hydroxyl type asymmetric organic nanotubes.

Since the asymmetrical organic nanotubes of each embodiment have high structural stability, they can withstand suction filtration and vacuum drying. In addition, the asymmetric organic nanotubes of each embodiment can withstand physical disturbances such as high-speed stirring and sonication, but are converted into carboxylic acid-type asymmetric organic nanotubes having a short axial ratio and good dispersibility depending on the conditions. ..

(3) Method for producing asymmetric organic nanotubes (3-1) Method for producing carboxylic acid-type asymmetric organic nanotubes (a) Heat-dissolving / cooling method 80 mg of 0.5-5 mg of asymmetric double-headed lipid molecule represented by the above general formula 1 Carboxylic acid is completely dissolved in 1 mL of pure water (millimeter Q water (trade name), etc.) by heating to ~ 100 ° C., and then cooled at a cooling rate of 0.1 to 10 ° C. per minute. Type asymmetric organic nanotubes are obtained. Carboxylic acid type asymmetric organic nanotubes can be confirmed by electron microscopic observation.

When the solubility of the asymmetric double-headed lipid molecule represented by the above general formula 1 in water is low, it is found in a mixed solvent of water with various alcohols such as methanol, ethanol, or isopropanol, in dimethyl sulfoxide (DMSO), or N, By heating and cooling in N-dimethylformamide (DMF) in the same manner as described above, a dispersion liquid of carboxylic acid type asymmetric organic nanotubes can be obtained. By suction-filtering this dispersion and then redispersing it in water, an aqueous dispersion of carboxylic acid-type asymmetric organic nanotubes can be obtained. As the solvent used for dissolving the asymmetric bilayer lipid molecule, a mixed solvent of methanol or ethanol and water is preferable from the viewpoint of solubility and subsequent isolation.

When DMSO or DMF is used as a solvent for dissolving asymmetric double-headed lipid molecules, asymmetric organic nanotubes can be obtained by removing these solvents by concentration under reduced pressure at room temperature, filtration, lyophilization, or membrane dialysis. Further, when DMSO or DMF is used as a solvent for dissolving the asymmetric bilayer lipid molecule, the solubility of the asymmetric bilayer lipid molecule is high, so that an asymmetric organic nanotube is produced at a concentration of the asymmetric bilayer lipid molecule of 5 mg / mL or more. Suitable for. When encapsulating the drug with asymmetric organic nanotubes, the drug is usually dissolved or dispersed in water or an aqueous solvent. Therefore, if the asymmetric organic nanotubes are produced using water or an aqueous solvent, they can be directly used in the drug encapsulation step without going through the solvent removal step, which is preferable.

(3-2) Method for producing amine-type, ester-type, betaine-type, and hydroxyl-type asymmetric organic nanotubes Amine-type asymmetric organic nanotubes, ester-type asymmetric organic nanotubes, betaine-type asymmetric organic nanotubes, and hydroxyl-type asymmetric organic nanotubes are described above. It can be produced in the same manner as the carboxylic acid type asymmetric organic nanotube. Carboxylic acid-type asymmetric organic nanotubes whose inner surface is coated with a carboxyl group include substances having a positive charge on the surface, substances having an amino group, or cationic hydrophobic substances (these are referred to as "cationic agents"). The inclusion of the cationic agent of the carboxylic acid type asymmetric organic nanotube can gradually release the cationic agent out of the carboxylic acid type asymmetric organic nanotube.

(A) pH adjustment method By adjusting the pH, carboxylic acid-type asymmetric organic nanotubes can be produced from an asymmetric bilayer lipid molecule having a carboxylic acid at the end on the Y side represented by the above general formula 1. Similarly, by adjusting the pH, a carboxylic acid type asymmetric organic nanotube can be produced from an asymmetric bilayer lipid molecule having an amino group at the end on the Y side represented by the above general formula 1. That is, the asymmetric bilayer lipid molecule having these carboxylic acids or amines at the Y-side terminal is dispersed and dissolved as a salt in an aqueous solution containing equimolar to about 2 equivalents of sodium hydroxide or amine at room temperature. Then, the mixture is cooled to room temperature, and an acid solution such as hydrochloric acid or an alkaline solution of sodium hydroxide is further added in an equimolar amount to about 2 equivalents to obtain asymmetric organic nanotubes.

As the acid solution, phosphoric acid, formic acid, acetic acid, citric acid, ascorbic acid, sulfuric acid and the like can be used in addition to hydrochloric acid. As the alkaline solution, in addition to the sodium hydroxide aqueous solution, a hydroxide aqueous solution such as lithium, potassium, rubidium, or cesium or ammonia water can be used. The size of the asymmetric organic nanotubes obtained by the pH adjustment method is almost the same as the size of the asymmetric organic nanotubes obtained by the above-mentioned heat dissolution / cooling method, but in the pH adjustment method, the asymmetric bilayer lipid molecule dissolves in the solvent. It has the advantage that the temperature is generally low.

(4) Structure of asymmetrical organic nanotubes The tubular structure of the asymmetrical organic nanotubes obtained from the asymmetric bilayer lipid molecule of the present embodiment can be confirmed by visualizing the space inside the tube by electron microscope observation after negative staining. .. That is, when a dyeing agent that does not allow electron beams to pass through the tube inner space is introduced by capillarity and a transmitted image is obtained by electron microscope observation, the tube inner space where the dyeing agent is distributed becomes a dark image, and an organic substance that allows electron beams to easily pass through. The walls of the tube made up of are lightly contrasted.

The sizes of the asymmetric organic nanotubes obtained from the asymmetric bilayer lipid molecule of the present embodiment are as follows. The carboxylic acid-type asymmetric organic nanotubes obtained from Compound 1-c had an inner diameter of 35 to 60 nm and a film thickness of about 6 to 7 nm. The ester-type asymmetric organic nanotubes obtained from compound 1-a had an inner diameter of 30 to 50 nm and a film thickness of about 7 nm. The amine-type asymmetric organic nanotubes obtained from Compound 1-d had an inner diameter of 30 to 50 nm and a film thickness of about 4 nm. The amine-type asymmetric organic nanotubes obtained from Compound 1-e had an inner diameter of 40 to 80 nm and a film thickness of 7 to 20 nm. The betaine-type asymmetric organic nanotubes had an inner diameter of about 50 to 60 nm and a film thickness of about 7 to 10 nm. The glycine-based asymmetric organic nanotubes obtained from Compound 1-g or Compound 1-h each had an inner diameter of about 20 nm and a film thickness of about 20 nm.

The arrangement of hydrophobic groups on the inner surface of asymmetric organic nanotubes can be confirmed by infrared spectroscopy (IR) spectroscopy. The asymmetric double-headed lipid molecule represented by the above general formula 1 is packed in parallel by an intermolecular multipoint hydrogen bond network formed by a hydroxyl group or an amide derived from a polyhydroxyalkanoyl group in the molecule, and is formed by a monomolecular film or its accumulation. Form nanotubes. As a result, an asymmetric organic nanotube whose outer surface is a hydroxyl group derived from polyhydrochicarboxylic acid and whose inner surface is coated with a carboxylic acid, amine, ester, methyl group, hydroxyl group, or betaine group derived from Y of the above general formula 1 is formed. can get.

In particular intermolecular hydrogen bond network formed from amide groups of the asymmetric double-headed lipid molecules can be identified by a clear peak of the amide I in the infrared spectrum (1640 cm ^-1 vicinity) and amide II (1540 cm around ^-1). _{In addition, in CH 2} scissors vibration absorption that reflects the sub-lattice structure of the oligomethylene chain, if one peak showing a triclinic parallel type is ^{observed at 1465 cm -1} , asymmetric bilayer lipid molecules are lined up in parallel. Indicates that the molecule is packed in. The IR spectra of the asymmetric organic nanotubes obtained in each of the examples described later showed hydrogen bond formation of amide groups, and showed that the molecular arrangements were arranged in parallel in the monomolecular membrane.

Further, the confirmation of the asymmetric tube structure (that is, the structure in which the carboxyl group and various hydrophobic functional groups are oriented on the inner surface and the glucopyranosyl group is oriented on the outer surface) is confirmed by the film of the nanotube estimated from the powder X-ray diffraction pattern of the nanotube. It can be inferred from the relationship between the thickness period d and the molecular length L estimated from the model of the molecule constituting the thickness period (Non-Patent Document 1, Non-Patent Document 2, and Non-Patent Document 7). That is, when the asymmetric organic nanotube is formed, the membrane period d of the nanotube and the molecular length L of the constituent molecules are almost the same, or d is slightly smaller than L (L ≧ d), and X in the above general formula 1 is obtained. When the corresponding part is the "head" and the part corresponding to Y is the "tail", there is no head-head-derived membrane overlap, and the head-tail overlap.

The powder X-ray diffraction pattern of a tube having a head-to-head structure gives a diffraction pattern with a large surface spacing corresponding to a film period of 2d, and this film period is about 1.5 to 2.5 times that of L. (That is, L << 2d). Therefore, as a result of comparing and examining d (or 2d) and L as follows, in any case, L ≧ d was satisfied, and almost no one corresponding to L << 2d was found (Table 1 below). That is, it can be seen that the organic nanotubes of the present embodiment have an asymmetric organic nanotube structure.

The membrane period d (or 2d) of carboxylic acid-type asymmetric organic nanotubes, ester-type asymmetric organic nanotubes, and amine-type asymmetric organic nanotubes obtained by X-ray diffraction measurement, and the asymmetric double-headed lipid molecules constituting these asymmetric organic nanotubes. The relationship of the molecular length L obtained from the molecular model is shown in Table 1. The asymmetric organic nanotubes in Table 1 are obtained from Compound 1-a, Compound 1-c, and Compound 1-e produced in Example 2, Example 4, and Example 6 described later, respectively. The molecular length L was obtained from the molecular model.

As shown in Table 1, all the asymmetrical organic nanotubes had L ≧ d, and the film period in which L << 2d was hardly observed. Therefore, it is suggested that the organic nanotubes of each embodiment are mainly composed of asymmetrical organic nanotubes or asymmetrical organic nanotubes. In general, in a series of lipid groups having different hydrophobic methylene chain lengths of molecules, when the nanotube structures obtained by self-assembly have almost the same morphology and size (inner diameter, outer diameter, wall thickness), the arrangement pattern of the molecules is also the same. It is known to exist (Non-Patent Document 1 and Non-Patent Document 7). Therefore, in the above general formula 1, it is suggested that the asymmetric organic nanotube structure is formed even when m is 5, 6, 7, 8, 9, and 10 smaller than 11.

Production Example 1: Synthesis of Intermediate 2-a (12-aminododecanoic acid methyl ester hydrochloride) 50 g (0.232 mol) of 12-aminododecanoic acid was dispersed in 200 mL of methanol, and hydrochloric acid / methanol (5-10% (weight)) was dispersed. Ratio)) 100 mL was added. The dispersion was stirred at 50 ° C. for 4 hours to give a clear solution. After concentrating this solution under reduced pressure, a white solid was obtained by drying under reduced pressure (62 g (0.232 mol), yield 99%). ¹ It was confirmed by 1 H NMR and IR that this white solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.89 (NH ₃ , 3H, s), 3.58 (OCH ₃ , 3H, s), 2.74 (N-CH _2- , 2H, t), 2.28 ( -CH _2- C = O, 2H, t), 1.51 (-CH _2- , 4H, m), 1.24 (-CH _2- , 14H, m).
IR: 2919, 2847 (CH), 1723 (C = O), 1562 (NH), 1468 (methylene), 1174 (CO).

Production Example 2: Synthesis of Intermediate 2-b (6-aminohexanoic acid methyl ester hydrochloride) A white solid was obtained from 30.4 g (0.232 mol) of 6-aminohexanoic acid in the same manner as in Production Example 1. (33.6 g (0.232 mol), yield 99%). It was confirmed by IR that this white solid was the target product.
IR: 2919, 2847 (CH), 1723 (C = O), 1562 (NH), 1468 (methylene), 1174 (CO).

Example 1: Synthesis of Intermediate 1-a (12- (D-gluconoylamino) dodecanoic acid triethylamine salt) 12-aminododecanoic acid 22 g (0.102 mol) was added to 195 mL of methanol and 10.6 g (0.114 mol) of triethylamine. ) Is dispersed in the mixed solution. To this, 18.0 g (0.101 mol) of D- (+)-glucono-1,5-lactone was added, and the mixture was heated under reflux for 4 hours to obtain a nearly transparent solution. The solution was immediately suction filtered to remove trace amounts of unwanted material and concentrated under reduced pressure to give a white solid (50 g (0.102 mol), 99% yield). ¹ It was confirmed by 1 H NMR and IR that this white solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.60 (-CONH-, 1H, t), 4.46 (OH, 6H, broad peak), 3.97 (-CH-O-, 1H, d), 3.89 (-CH-O-, 1H, m), 3.58 (-CH-O-, 1H, m), 3.56 (-CH-O-, 1H, d), 3.46 (-CH ₂ -O-, 2H, m) ), 3.36 (-CH-O-, 1H, dd), 3.06 (N-CH _2- , 2H, m), 2.18 (-CH ₂ -C = O, 2H, t), -1.48 (-CH _2- , 2H, t), -1.40 (-CH _2- , 2H, m), 1.24 (-CH _2- , 14H, m).
IR: 2919, 2847 (CH), 1723 (C = O), 1562 (NH), 1468 (methylene), 1174 (CO).

Example 2: Synthesis of asymmetric double-headed lipid molecule (Compound 1-a (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is a methoxy group)) The intermediate obtained in Example 1 4.95 g (10 mmol) of 1-a and 3.19 g (0.012 mol) of the intermediate obtained in Production Example 1 were dispersed in 166 mL of THF / water (3/2) and dissolved at 80 ° C. After cooling to 40 ° C., 4.14 g (15 mmol) of DMT-MM was suspended in THF and added. The pH of the reaction solution was monitored with stirring at 40 ° C., and 0.010 mol of triethylamine was added so as to have a pH of 7. After 2 hours, the solution turned white and gelled.

The gel product was suction filtered, and the solid was washed successively with 50 mL of methanol, 50 mL of water, and 50 mL of methanol on a funnel, and then dried under reduced pressure to obtain a solid. Further, this solid was heated and dissolved in a mixture of 360 mL of ethanol, 130 mL of methanol, and 40 mL of water, and then slowly cooled to around 0 ° C. to obtain a solid. After suction filtration of this solid, it was vacuum dried to obtain a white solid (7.32 g, yield 94%). ¹ It was confirmed by 1 H NMR that this white solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.70 (-CONH-, 1H, t), 7.60 (-CONH-, 1H, t), 5.34 (-OH, 1H, d), 4.53 (- OH, 1H, d), 4.47 (-OH, 1H, d), 4.38 (-OH, 1H, d), 4.33 (-OH, 1H, t), 3.96 (-CH-O-, 1H, t), 3.89 (-CH-O-, 1H, m), 3.57 (-CH-O-/-C0OCH ₃ , 4H, m), 3.46 (-CH ₂ -O-, 2H, m), 3.37 (-CH-O -, 1H, m), 3.05 (N-CH _2- , 2H, m), 3.01 (N-CH _2- , 2H, m), 2.28 (-CH _2- , 2H, t), 2.01 (-CH ₂ -C = O, 2H, t), -1.46 (-CH _2- , 4H, m), -1.35 (-CH _2- , 4H, m), 1.23 (-CH _2- , 28H, m).

Example 3: Synthesis of asymmetric double-headed lipid molecule (Compound 1-b (in the above general formula 1, X is a D-gluconoyl group, m = 11, n = 5, Y is a methoxy group)) obtained in Example 1. 2.0 g (4 mmol) of the intermediate 1-a and 0.9 g (5 mmol) of the intermediate 2-b obtained in Production Example 2 were dispersed in 50 mL of THF / water (3/2 (volume ratio)), and a small amount of triethylamine ( 0.27 mL (2 mmol)) and 1.8 g (5.6 mmol) of DMT-MM were suspended in THF and added at room temperature. While stirring at room temperature, the pH of the reaction solution was monitored, and 0.010 mol of triethylamine was added so as to have a pH of 7. After 2 hours, the solution turned white and gelled.

After removing THF under reduced pressure, suction filtration was performed, and the solid obtained with 50 mL of water was washed on a funnel and dried under reduced pressure to obtain a white solid (2.15 g, yield 95%). ¹ It was confirmed by 1 H NMR that this white solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.70 (-CONH-, 1H, t), 7.60 (-CONH-, 1H, t), 5.35 (-OH, 1H, d), 4.53 (- OH, 1H, d), 4.47 (-OH, 1H, d) 4.38 (-OH, 1H, m), 4.35 (-OH, 1H, m), 3.97 (-CH-O-, 1H, t), 3.89 (-CH-O-, 1H, m), 3.58 (-CH-O-/-C0OCH ₃ , 4H, m), 3.47 (-CH ₂ -O-, 2H, m), 3.33 (-CH-O- , 1H, m), 3.07 (N-CH _2- , 2H, m), 2.98 (N-CH _2- , 2H, m), 2.28 (-CH _2- , 2H, t), 2.01 (-CH _2- C = O, 2H, t), -1.49 (-CH _2- , 4H, m), -1.39 (-CH _2- , 4H, m), 1.23 (-CH _2- , 16H, m).

Example 4: Synthesis of asymmetric double-headed lipid molecule (Compound 1-c (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is an OH group)) Compound 1 obtained in Example 2. A total of 4.5 mL of a 4N aqueous sodium hydroxide solution was added in 3 portions while stirring a solution of 3.04 g of −a in 100 mL of dimethylformamide heated at 70 ° C. for about 4 hours. After confirming by IR that the ester peak had disappeared, 4.5 mL of 4N hydrochloric acid was added to bring the solution to near neutrality, and then concentrated under reduced pressure. The obtained solid was dispersed in water, adjusted to pH 4, and the precipitated solid was suction-filtered and washed with water on a filter paper to obtain a solid. The mass of this solid after drying was 2.60 g (yield 88%). ¹ It was confirmed by 1 H NMR that this solid was the target product.

¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.71 (-CONH-, 1H, t), 7.64 (-CONH-, 1H, t), 3.96 (-CH-O-, 1H, d), 3.89 (-CH-O-, 1H, m), 3.58 (-CH-O-, 1H, m), 3.56 (-CH-O-, 1H, d), 3.46 (-CH ₂ -O-, 2H, m), 3.38-3.34 (-CH-O-, 1H, m), 3.05 (N-CH _2- , 2H, m), 3.01 (N-CH _2- , 2H, m), 2.13 (-CH _2- , 2H, t), 2.02 (-CH ₂ -C = O, 2H, t), -1.46 (-CH _2- , 4H, m), -1.37 (-CH _2- , 4H, m), 1.23 (- CH _2- , 28H, m).

Example 5: Asymmetric bilayer lipid molecule (Compound 1-d (in the above general formula 1, X is a D-gluconoyl group, m = 11, n = 5, Y is NH- (CH ₂ ) _6- NH ₂ groups) ) Synthesis 2.5 g of hexamethylenediamine was added to 400 mg of the compound 1-b obtained in Example 3, and the mixture was stirred at 80 ° C. for about 3 hours. The reaction solution was added to 50 mL of methanol, and the produced solid was suction-filtered, and the solid was washed with methanol on a filter paper to obtain a white solid (238 mg, yield 51%). ¹ It was confirmed by 1 H NMR that this white solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.55 (-CONH-, 2H, m), 7.45 (-CONH-, 1H, t), 7.59 (-CONH-, 1H, m), 3.98 ( -CH-O-, 1H, t), 3.90 (-CH-O-, 1H, m), 3.57 (-CH-O-, 1H, m), m), 3.46 (-CH ₂ -O-, 2H , m), 3.41 (-CH-O-, 1H, m), 3.00 (N-CH _2- , 8H, m), 2.02 (-CH ₂ -C = O, 4H, m), 1.47-1.38 (- CH _2- , 12H, m), 1.23 (-CH _2- , 20H, m).

Example 6: Asymmetric bilayer lipid molecule (Compound 1-e (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is NH- (CH ₂ ) _3- NMe ₂ groups)). Synthesis To 0.5 g of compound 1-a obtained in Example 2, 10 mL of N, N-dimethylpropanediamine and 5 mg of sodium methoxide were added, and the mixture was stirred at 90 ° C. for about 4 hours and then at 95 ° C. for about 2 hours. After confirming that the ester peak (around 1720 cm ^-1 ) had disappeared by IR of the reaction solution, the mixture was concentrated under reduced pressure. The obtained solid was dispersed in water, adjusted to pH 9, and the precipitated solid was suction-filtered and washed with water on a filter paper to obtain a solid. The dry mass of this solid was 2.90 g (yield 98%). ¹ It was confirmed by 1 H NMR that this solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.74 (-CONH-, 1H, t), 7.70 (-CONH-, 1H, t), 7.59 (-CONH-, 1H, t), 5.34 ( -OH, 1H, d), 4.53 (-OH, 1H, d), 4.47 (-OH, 1H, d), 4.38 (-OH, 1H, d), 4.33 (-OH, 1H, t), 3.97 ( -CH-O-, 1H, t), 3.89 (-CH-O-, 1H, m), 3.57 (-CH-O-, 1H, m), 3.46 (-CH ₂ -O-, 2H, m) , 3.36 (-CH-O-, 1H, m), 3.09-2.97 (N-CH _2- , 6H, m), 2.17 (-CH _2- , 2H, t), 2.10 (N-CH ₃ , 6H, s), 2.02 (-CH ₂ -C = O, 4H, t), 1.51-1.35 (-CH _2- , 10H, m), 1.23 (-CH _2- , 28H, m).

Example 7: Asymmetric bilayer lipid molecule (Compound 1-f (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is NH- (CH ₂ ) _3- N ⁺ _{MeOH 2} CH ₂ -Synthesis of -COO ^- group)) 0.9 g of the compound 1-e obtained in Example 6 was dispersed in 100 mL of methanol, methyl bromoacetate was added, the mixture was stirred at 65 ° C. for about 12 hours, and then concentrated under reduced pressure. The obtained solid was redispersed in 100 mL of methanol, 1.9 mL of a 4N aqueous sodium hydroxide solution was added, and the mixture was stirred overnight at room temperature. After confirming the disappearance of the ester peak by IR, 1.9 mL of 4N hydrochloric acid was added to the solution for neutralization. The obtained solution was concentrated under reduced pressure and then extracted with methanol to obtain a solid. The mass of this solid after drying was 0.83 g (yield 85%). ¹ It was confirmed by 1 H NMR that this solid was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.98 (-CONH-, 1H, t), 7.72 (-CONH-, 1H, t), 7.60 (-CONH-, 1H, t), 4.6- 4.4 (-OH, 5H, broad), 4.33 (-OH, 1H, t), 3.97 (-CH-O-, 1H, t), 3.89 (-CH-O-, 1H, m), 3.57 (-CH) -O- / N-CH ₃ , 7H, m), 3.46 (-CH ₂ -O-, 2H, m), 3.36 (-CH-O-, 1H, m), 3.16 (N-CH ₂ -CO, 2H, s), 3.09-2.97 (N-CH _2- , 6H, m), 2.27 (-CH _2- CO, 2H, t), 2.02 (-CH _2- CO, 2H, t), 1.51-1.35 ( -CH _2- , 8H, m), 1.23 (-CH _2- , 28H, m).

Example 8: Synthesis of asymmetric bilayer lipid molecule (Compound 1-g (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is an NH- (Gly) _2- OMe group)) 1.0 g (1.7 mmol) of compound 1-c obtained in Example 4 and 0.3 g (1.7 mmol) of diglycine ethyl ester are stirred in 100 mL of DMF for 2 days in the presence of 0.7 g (2.6 mmol) of DMT-MM. did. After distilling off the solvent, the solid was washed successively with citric acid aqueous solution, sodium hydrogen carbonate aqueous solution and water, and vacuum dried to obtain a solid (0.89 g, yield 71%). ¹ It was confirmed by 1 H NMR that this solid was the target product.
¹ H-NMR (500 MHz, in DMSO-d ₆ ): 8.20 (-CONH-, 1H, t), 8.05 (-CONH-, 1H, t), 7.71 (-CONH-, 1H, t), 7.60 ( -CONH-, 1H, t), 3.96 (-CH-O-, 1H, m), 4.08 (-OCH _2- , 2H, m), 3.89 (-CH-O-, 1H, m), 3.82 (N -CH ₂ -CO, 2H, d), 3.70 (N-CH ₂ -CO, 2H, d), 3.57 (-CH-O-, 1H, m), 3.46 (-CH ₂ -O-, 2H, m ), 3.36 (-CH-O-, 1H, m), 3.05 (N-CH _2- , 2H, m), 3.00 (N-CH _2- , 2H, m), 2.18 (-CH _2- , 2H, t), 2.02 (-CH _2- C = O, 2H, t), 1.46 (-CH _2- , 4H, m), 1.35 (-CH _2- , 4H, m), 1.23 (-CH _2- , 28H, m), 1.19 (-CH ₃ , 3H, t).

Example 9: Synthesis of asymmetric bilayer lipid molecule (Compound 1-h (in the above general formula 1, X is a D-gluconoyl group, m = n = 11, Y is an NH- (Gly) _2- OH group)) 1-g of the compound obtained in Example 8 was stirred in methanol at 60 ° C. for 2 days in the presence of KOH. After distilling off the solvent, it was neutralized with an aqueous citric acid solution, washed with water, filtered, and vacuum dried to obtain a solid (0.77 g, yield 90%). ^{1 1} H NMR confirmed that this solid was the target product.
¹ H-NMR (500 MHz, in DMSO-d ₆ ): 8.11 (-CONH-, 1H, t), 8.05 (-CONH-, 1H, t), 7.71 (-CONH-, 1H, t), 7.65 ( -CONH-, 1H, t), 3.96 (-CH-O-, 1H, m), 3.89 (-CH-O-, 1H, m), 3.75 (N-CH ₂ -CO, 2H, d), 3.70 (N-CH ₂ -CO, 2H, d), 3.56 (-CH-O-, 1H, m), 3.46 (-CH ₂ -O-, 2H, m), 3.36 (-CH-O-, 1H, m), 3.05 (N-CH _2- , 2H, m), 3.00 (N-CH _2- , 2H, m), 2.12 (-CH _2- , 2H, t), 2.01 (-CH _2- C = O) , 2H, t), 1.46 (-CH _2- , 4H, m), -1.36 (-CH _2- , 4H, m), 1.23 (-CH _2- , 28H, m).

Example 10: Asymmetric double-headed lipid molecules (Compound 1-i (the above general formula 1, X is D- Gurukonoiru group, m = n = 11, Y is _{[NH-C (CH 2 -OH} ) 3] ( tris compound 1-a0.60g obtained in synthesis example 2 of hydroxy aminomethane) groups were dissolved in DMSO, and heated to .50 ° C. plus trishydroxyaminomethane 0.12g and _K 2 _CO 3 0.14 g After stirring for 24 hours, after confirming the disappearance of the ^{ester group (around 1720 cm -1} _{) by IR, K 2} CO ₃ was removed by filtration. Then, the solid obtained by concentration under reduced pressure was washed with water and trishydroxyaminomethane. Was removed to obtain a solid product (0.65 g, yield 95%). ¹ H NMR confirmed that this solid product was the target product.
¹ H-NMR (400 MHz, in DMSO-d ₆ ): 7.71 (-CONH-, 1H, t), 7.64 (-CONH-, 1H, t), 7.60 (-CONH-, 1H, s), 3.96 ( -CH-O-, 1H, d), 3.89 (-CH-O-, 1H, m), 3.58 (-CH-O-, 1H, m), 3.56 (-CH-O-, 1H, d), 3.50 (-CH ₂ -O-, 6H, s) 3.46 (-CH ₂ -O-, 2H, m), 3.38-3.34 (-CH-O-, 1H, m), 3.05 (N-CH _2- , s) 2H, m), 3.01 (N-CH _2- , 2H, m), 2.13 (-CH _2- , 2H, t), 2.02 (-CH ₂ -C = O, 2H, t), -1.46 (-CH _2- , 4H, m), -1.37 (-CH _2- , 4H, m), 1.23 (-CH _2- , 28H, m).

Example 11: Formation of ester-type asymmetric organic nanotubes by self-assembly of asymmetric double-headed lipid molecules 1-a 1 mg / mg of compound 1-a obtained in Example 2 was added to water / methanol (1/2 (volume ratio)). Asymmetric organic nanotubes were obtained by dispersing at a concentration of mL, dissolving by heating and refluxing, and then cooling at a temperature lowering rate of 0.1 to 10 ° C. per minute. The morphology and size of the asymmetric organic nanotubes can be confirmed by dropping the dispersion liquid onto the grid of an electron microscope and dyeing the inside with an electron beam opaque dyeing agent. In this way, ester-type asymmetric organic nanotubes having an inner diameter of about 30 to 50 nm, a film thickness of about 7 nm, and a length of 2 to 100 μm were obtained. FIG. 1 is an electron microscope image of various asymmetric organic nanotubes. FIG. 1-1 shows an electron microscope image (transmission image) of this ester-type asymmetric organic nanotube.

Example 12: Formation of carboxylic acid-type asymmetric organic nanotubes by self-assembly of asymmetric double-headed lipid molecules 1-c 1 mg of compound 1-c obtained in Example 4 was added to water / methanol (1/2 (volume ratio)). Asymmetric organic nanotubes were obtained by dispersing at a concentration of / mL, dissolving by heating and refluxing, and then cooling at a temperature lowering rate of 0.1 to 10 ° C. per minute. It was confirmed by the same method as in Example 11 that carboxylic acid-type asymmetric organic nanotubes having an inner diameter of about 35 to 60 nm, a film thickness of 6 to 7 nm, and a length of 2 to 30 μm were obtained. FIG. 1-2 shows an electron microscope image (transmission image) of this carboxylic acid type asymmetric organic nanotube.

Example 13: Formation of amine-type or betaine-type asymmetric organic nanotubes by self-assembly of asymmetric bilayer lipid molecules 1-d, 1-e, or 1-f Obtained in Examples 5, 6, and 7. Asymmetric bilayer lipid molecule 1-d, asymmetric bilayer lipid molecule 1-e, and asymmetric bilayer lipid molecule 1-f are dispersed in water / methanol (1/2 (volume ratio)) at a concentration of 1 mg / mL, respectively. Then, after being dissolved by heating and refluxing, each asymmetric organic nanotube was obtained at a temperature lowering rate of 0.1 to 10 ° C. per minute.

Amine-type asymmetric organic nanotubes having an inner diameter of 30 to 50 nm and a film thickness of about 4 nm were obtained from Compound 1-d, and amine-type asymmetric organic nanotubes having an inner diameter of 40 to 80 nm and a film thickness of 7 to 20 nm were obtained from Compound 1-e. It was confirmed by the same method as in Example 11 that the nanotubes were obtained and that the betaine-type asymmetric organic nanotubes having an inner diameter of about 50 to 60 nm and a film thickness of about 7 to 10 nm were obtained from Compound 1-f. .. FIG. 2 is an electron microscope image of various asymmetric organic nanotubes. FIG. 2-1 shows an electron microscope image (transmission image) of the amine-type asymmetric organic nanotube obtained from Compound 1-d. FIG. 2-2 shows an electron microscope image (transmission image) of betaine-type asymmetric organic nanotubes obtained from compound 1-e. FIG. 2-3 shows an electron microscope image (transmission image) of betaine-type asymmetric organic nanotubes from compound 1-f.

Example 14: Formation of glycine-based asymmetric organic nanotubes by self-assembly of asymmetric bilayer lipid content 1-g or 1-h Asymmetric bilayer lipid molecules 1-g and 1-h obtained in Examples 8 and 9, respectively. Was dispersed in water at a concentration of 1 mg / mL, heated and refluxed for several minutes, slowly cooled to room temperature, and self-assembled to obtain each glycine-based asymmetric organic nanotube. It was confirmed from Compounds 1-g and 1-h that glycine-based asymmetric organic nanotubes having an inner diameter of 30 to 50 nm and a film thickness of about 4 nm were obtained in the same manner as in Example 11. FIG. 3 is an electron microscope image of various asymmetric organic nanotubes. FIG. 3-1 shows an electron microscope image (transmission image) of glycine-based asymmetric organic nanotubes obtained from compound 1-g. FIG. 3-2 shows an electron microscope image (transmission image) of glycine-based asymmetric organic nanotubes obtained from compound 1-h.

Example 15: Encapsulation and release of guests into carboxylic acid-type asymmetric organic nanotubes To the carboxylic acid-type asymmetric organic nanotubes obtained in Example 12, an aqueous solution containing 81 mg (170 mmol) of rhodamine 6G was added, and the mixture was allowed to stand overnight. , Washed with water on a membrane filter (pores 200 nm) and freeze-dried to obtain an inclusion body of rhodamine 6G of a carboxylic acid type asymmetric organic nanotube. Next, the included rhodamine 6G was released by thermally decomposing the carboxylic acid-type asymmetric organic nanotubes in DMSO. By absorptiometry, rhodamine 6G was included in 1 mg (1.7 mmol) of nanotubes in an amount of 0.17 mg (0.36 mmol).

Rhodamine 6G inclusions of carboxylic acid-type asymmetric organic nanotubes were dispersed in phosphate buffers adjusted to pH 5.5 and pH 7.4, respectively. The dispersed aqueous solution was subjected to a membrane filter at predetermined time intervals, and the rhodamine 6G released into the separated solution was quantified by absorptiometry to calculate the release rate. The relationship between the release rate and time is shown in FIG. At pH 7.4, as shown in FIG. 4, the carboxyl groups on the inner surface of the asymmetric organic nanotubes became anionic due to proton dissociation, and the release of cationic rhodamine 6G was suppressed by electrostatic attraction. On the other hand, at pH 5.5, as shown in FIG. 4, the proton dissociation of the carboxyl group on the inner surface of the asymmetric organic nanotube is suppressed as compared with pH 7.4, and the electrostatic attraction to the cationic rhodamine 6G is reduced, so that the release is released. It was promoted. As described above, an inclusion body having an asymmetric organic nanotube and a guest substance contained in the asymmetric organic nanotube was obtained, and it was found that this inclusion body slowly releases the guest substance.

Claims (6)

An asymmetric bilayer lipid molecule represented by the following general formula 1.

General formula 1 X-NH- (CH ₂ ) _m- CONH- (CH ₂ ) _n- CO-Y

here,
m and n are integers of 5-11, m = n = 11 or m = 11 and n = 5.
X is a D-gluconoyl group ,
Y is a methoxy group, an ethoxy group, an OH group, an NH- (CH ₂ ) _6- NH ₂ group, an NH- (CH ₂ ) _3- NMe group (Me is a methyl group), an NH- (CH ₂ ) _3- NMe. ^{_{2 + - (CH 2) -COO}} - _{group, (NH-CH 2 -CO)} r -Z groups (r is an integer from 1 to 4, Z is OH group, an alkoxyl group having 1 to 3 carbon atoms, HN- (CH ₂ ) _2- NH ₂ groups, or HN- (CH ₂ ) _3- NH ₂ groups), or N-tris (hydroxymethyl) methylamino group . An asymmetric organic nanotube composed of one of the asymmetric bilayer lipid molecules according to claim 1 , wherein the inner surface and the outer surface are coated with different functional groups. An asymmetric organic nanotube composed of two or more types of asymmetric bilayer lipid molecules according to claim 1, wherein the inner surface and the outer surface are coated with different functional groups. A method for producing asymmetric organic nanotubes, which comprises a step of self-assembling one type of asymmetric bilayer lipid molecule according to claim 1 in a liquid. A method for producing asymmetric organic nanotubes, which comprises a step of self-assembling two or more kinds of asymmetric bilayer lipid molecules in a liquid according to claim 1. An inclusion body comprising the asymmetric organic nanotube according to claim 2 or 3 and a guest substance contained in the asymmetric organic nanotube.

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