JP2009256233A - Medicine having magnetism, guiding system of medicine and device for detecting magnetism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drug delivery system, capable of solving conventional technological problems and easily utilized. <P>SOLUTION: This medicine having magnetism is provided by containing an acid salen complex expressed by formula (I) [wherein, R is a substituting group obtained by leaving hydrogen from a compound having a hydroxy group]. Since it is possible to make an iron salen complex itself have the magnetism, by using the same as the medicine, it is possible to induce the medicine to an affected part in a body by utilizing the magnetism which the medicine itself has, without using a carrier consisting of a magnetic material, as performed conventionally. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a drug having magnetism, a drug guidance system, and a magnetic detection device.

  In general, drugs are administered in vivo to reach the affected area and cause a therapeutic effect by exerting a pharmacological effect in the affected area, but even if the drug reaches a tissue other than the affected area (that is, normal tissue), it is not treated. . Therefore, how to efficiently guide the drug to the affected area is important in the treatment strategy. Such a technique for guiding to a drug affected area is called drug delivery, and research and development have been actively conducted in recent years. This drug delivery has at least two advantages. One is that a sufficiently high drug concentration is obtained in the affected tissue. This is because the pharmacological effect does not appear unless the drug concentration in the affected area is above a certain level, and a therapeutic effect cannot be expected at a low concentration. The second is to induce the drug only to the affected tissue and not unnecessarily to normal tissue. Thereby, a side effect can be suppressed.

  Such drug delivery is most effective in cancer treatment with anticancer agents. Most anticancer drugs inhibit cell proliferation of cancer cells with active cell division, so that even normal tissues, such as bone marrow or hair roots, gastrointestinal mucosa, etc. I will suppress it. For this reason, side effects such as anemia, hair loss, and vomiting occur in cancer patients who receive anticancer drugs. Since these side effects are a heavy burden on the patient, the dosage must be limited, and the pharmacological effect of the anticancer drug cannot be obtained sufficiently. In the worst case, side effects can cause the patient to die. Therefore, it is expected that cancer treatment can be effectively performed while suppressing side effects by inducing anticancer drugs to cancer cells by drug delivery and concentrating on cancer cells to exert pharmacological effects. Has been.

  Other than anticancer agents, for example, it can be applied to male erectile dysfunction drugs. Male erectile dysfunction drugs cause serious systemic hypotension when used in combination with nitro drugs, leading to death, and are particularly problematic for men with middle-aged and older heart disease. This is because the drug for erectile dysfunction does not necessarily concentrate on the affected part, but acts on the blood vessels throughout the body to amplify the vasodilatory action of the nitro preparation. Therefore, it is considered that side effects caused by the combined use with a nitro preparation can be suppressed by inducing a drug for male erectile dysfunction to the affected area by drug delivery and concentrating on the affected area to exert a pharmacological effect.

  As a specific method of drug delivery, for example, guidance to a diseased tissue using a carrier (carrier) has been studied. This is because a drug is placed on a carrier that tends to concentrate on the affected area, and the drug is placed on the carrier to the affected area. It is about letting you carry it. The use of various antibodies, microspheres, or magnetic materials as the carrier has been studied. Among them, a magnetic material is considered promising, and a method in which a carrier that is a magnetic material is attached to a drug and accumulated in an affected area by a magnetic field has been studied (for example, see Patent Document 1 below). This method is considered to be a particularly effective method for anti-cancer agents having high cytotoxicity because of the simplicity of the induction method and the possibility of treatment targeting the affected area.

JP 2001-10978 A

  However, as described above, when a carrier that is a magnetic substance is used as a carrier, oral administration is difficult, the carrier molecule is generally huge, or there are technical problems with the binding strength and affinity with drug molecules. It was pointed out and practical application was difficult.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to realize a drug delivery system that can solve the conventional technical problems and can be easily put into practical use.

（２）Ｒは、電荷移動が０．５電子（ｅ）未満である、前記（１）に記載の磁性を有する薬剤；
（３）Ｒは、下記式（１）〜（２７）のいずれかの化合物から水素が脱離した置換基である、前記（１）に記載の磁性を有する薬剤；

（４）個体に投与された際に、当該個体に加えた磁界によって目的とする組織或いは患部に誘導されるように構成した、前記（１）〜（３）の何れかに記載の磁性を有する薬剤；
（５）前記個体外表面から前記組織又は患部に磁場を与えて、当該組織又は患部に誘導されるようにした、前記（４）に記載の磁性を有する薬剤；
（６）前記個体の前記組織内又は患部内に磁力発生手段を適用し、当該組織又は前記患部に誘導されるようにした、前記（５）に記載の磁性を有する薬剤；
（７）前記個体の前記組織内又は患部内に前記個体の体液を供給する血管等の経路の途中に磁力発生手段を配置して、下流の組織又は患部に誘導されるようにした、前記（４）に記載の磁性を有する薬剤；
（８）体内に投与した前記（１）〜（３）の何れかに記載の磁性を有する薬剤を、当該薬剤の磁性を利用して所定の患部に誘導する誘導システムであって、個体の表面又は当該個体の組織又は患部に対して磁場を発生する手段を配置するようにした、薬剤の誘導システム；
（９）体内に投与した前記（１）〜（３）の何れかに記載の磁性を有する薬剤を、当該薬剤の磁性を利用して所定の患部に誘導する誘導システムであって、個体に対して磁場を発生する手段と、当該磁場を前記固定の目的とする組織又は患部に誘導する手段と、を備える、薬剤の誘導システム；
（１０）前記磁場を発生する手段は、２つの磁石を対にして当該二つの磁石の間に前記目的とする組織又は患部を置き、当該組織又は患部に磁束を集中させるように構成されてなる前記（８）又は（９）に記載の薬剤の誘導システム；
（１１）前記目的とする組織又は患部はＭＲＩ又はＣＴによって同定されてなる前記（８）〜（１０）の何れかに記載の薬剤の誘導システム；
（１２）体内に投与した前記（１）〜（３）の何れかに記載の磁性を有する薬剤の磁性又は発光を検出することにより、当該薬剤の体内動態を検知することを特徴とする磁気検出装置；
（１３）前記磁性を磁気共鳴誘導又は発光によって検出する前記（１２）に記載の磁気検出装置；を提供する。 The present invention relates to (1) a magnetic drug comprising an acid salen complex represented by the following formula (I):

(2) R is a magnetic agent according to (1), wherein charge transfer is less than 0.5 electrons (e);
(3) R is a magnetic agent as described in (1) above, wherein R is a substituent obtained by removing hydrogen from any one of the following formulas (1) to (27);

(4) having the magnetism according to any one of (1) to (3), wherein when administered to an individual, the magnetic field applied to the individual is guided to a target tissue or affected area Drugs;
(5) The magnetic drug according to (4), wherein a magnetic field is applied to the tissue or affected area from the outer surface of the individual so as to be induced in the tissue or affected area;
(6) The magnetic agent according to (5), wherein a magnetic force generating means is applied in the tissue or the affected part of the individual so as to be guided to the tissue or the affected part;
(7) The magnetic force generating means is disposed in the middle of a path of a blood vessel or the like for supplying the body fluid of the individual into the tissue or the affected part of the individual, and is guided to a downstream tissue or affected part. 4) a magnetic drug according to 4);
(8) A guidance system for guiding the magnetic drug according to any one of (1) to (3) administered into the body to a predetermined affected area using the magnetic property of the drug, the surface of an individual Or a drug induction system in which means for generating a magnetic field is disposed on the tissue or affected area of the individual;
(9) An induction system for guiding a drug having magnetism according to any one of (1) to (3) administered to a body to a predetermined affected area using the magnetism of the drug, And a means for inducing a magnetic field; and a means for inducing the magnetic field to the fixed target tissue or affected area;
(10) The means for generating the magnetic field is configured such that two magnets are paired and the target tissue or affected part is placed between the two magnets, and the magnetic flux is concentrated on the tissue or affected part. The drug induction system according to (8) or (9);
(11) The drug induction system according to any one of (8) to (10), wherein the target tissue or affected area is identified by MRI or CT;
(12) Magnetic detection characterized in that the pharmacokinetics of the drug is detected by detecting the magnetism or luminescence of the drug having magnetism according to any one of (1) to (3) administered into the body. apparatus;
(13) The magnetic detection device according to (12), wherein the magnetism is detected by magnetic resonance induction or light emission.

According to the present invention, since the drug itself can be magnetized, the drug can be guided to the affected part in the body by using the magnetic property of the drug itself without using a carrier made of a magnetic material as in the prior art. it can.
Compared to the case where the pharmaceutical compound itself is made an organic magnetic material, a higher magnetic susceptibility can be obtained, so that it can be applied to drug delivery over a wide range without being limited to the affected area existing on the body surface.
As a result, it can be solved that conventional oral administration is difficult, the carrier molecule is generally huge, or there are technical problems in binding strength and affinity with drug molecules. It is possible to realize a drug delivery system that can be easily realized.

  Next, an embodiment of the present invention will be described. The following embodiment is an example for explaining the present invention, and is not intended to limit the present invention only to this embodiment. The present invention can be implemented in various forms without departing from the gist thereof.

(Drug)
The agent of the present invention is a magnetic agent containing an acid salen complex represented by the following formula (I).

R preferably has a charge transfer of less than 0.5 electrons (e). That is, it is preferable that the transfer of electrons of the compound that binds to the iron-salen complex represented by the formula (I) is less than 0.5 electrons (e).

R is preferably a substituent in which hydrogen is eliminated from any compound of the following formulas (1) to (27).

  As an example of the drug of the present invention, by binding the fluorescent dye of the chemical formula (5) to the iron-salen complex of the formula (I), it is possible to obtain a drug that emits light when irradiated with light and has magnetism. it can.

The agent of the present invention is a magnetic agent in which a compound having a hydroxyl group (OH) is bonded to the R portion of the acid salen complex. The compound to be bound is a pharmaceutical compound or a pigment compound.
As the pharmaceutical compound, any drug can be used. For example, a commercially available drug or organic magnetic substance having no magnetism can be used. When an organic magnetic substance is used as a pharmaceutical compound, the magnetic properties of the pharmaceutical compound itself can be used even after the iron oxide as a carrier has left the pharmaceutical compound.

  The magnetic drug of the present invention may be an in vivo marker.

As an example of use of the drug of the present invention, since the drug itself has magnetism, after administration to an individual, a magnetic field can be applied to the individual to induce the drug to the target tissue or affected area.
In another use example, a magnetic field can be applied to the tissue or affected area from the outer surface of the individual to induce the drug to the tissue or affected area.
As another example of use, a magnetic force generating means can be applied to the tissue or affected area of the individual to induce the drug to the tissue or affected area.
As another example of use, magnetic force generating means may be disposed in the path of a blood vessel or the like for supplying body fluid of the individual into the tissue or affected part of the individual to induce the drug to a downstream tissue or affected part. it can.

(Drug guidance system)
The magnetic drug of the present invention is a guidance system that guides the drug administered into the body to a predetermined affected area using the magnetic property of the drug, and applies a magnetic field to the surface, tissue, or affected area of an individual. The present invention can be applied to a drug guidance system in which a generating means is arranged.
The magnetic drug of the present invention is a guidance system for guiding the drug administered into the body to a predetermined affected area using the magnetism of the drug, the means for generating a magnetic field for an individual, and the magnetic field And a means for guiding the target to the target tissue or affected area of the individual.
It is preferable that the means for generating the magnetic field is configured so that two magnets are paired and the target tissue or affected part is placed between the two magnets, and the magnetic flux is concentrated on the tissue or affected part. .
The target tissue or affected area is preferably identified by MRI or CT.

(Magnetic detection device)
The magnetic drug of the present invention can be applied to a magnetic detection device that detects the pharmacokinetics of the drug by detecting the magnetism of the drug administered into the body.
The magnetic drug of the present invention is a magnetic detection device that detects the distribution of the drug in the body by detecting the magnetism of the drug administered into the body and quantifies the biological function (such as brain function) exhibited by the drug. Can be applied.
The magnetism of the drug is preferably detected by magnetic resonance induction.

(Functional diagnosis, cancer chemotherapy)
As another example of use of the magnetic drug of the present invention, by applying electromagnetic waves to a drug induced in cancer tissue, the temperature can be locally increased and cancer cells can be specifically killed.
Thus, when the drug of the present invention is used, functional diagnosis and cancer chemotherapy can be performed simultaneously with one drug. For example, an MRI diagnostic apparatus capable of cancer chemotherapy and a magnetic field induction drug delivery system can be provided.

  EXAMPLES Hereinafter, although an Example demonstrates this invention further in detail, this invention is not limited to these Examples.

Example 1
The iron-salen complex was synthesized as follows.

A mixture of 4-nitrophenol (25 g, 0.18 mol), hexamethylene tetramine (25 g, 0.18 mol), and polyphosphoric acid (200 ml) was stirred at 100 ° C. for 1 hour. The mixture was then taken up in 500 ml ethyl acetate and 1 L water and stirred until completely dissolved. An additional 400 ml of ethyl acetate was added to the solution and the solution separated into two phases, the water phase was removed, the remaining compound was washed twice with a salt solvent and dried over anhydrous MgSO ₄ . As a result, 17 g (yield 57%) of compound 2 was synthesized.

Compound 2 (17 g, 0.10 mol), acetic anhydride (200 ml) and H ₂ SO ₄ (a little) were stirred at room temperature for 1 hour. The resulting solution was hydrolyzed by mixing in ice water (2 L) for 0.5 hour. The obtained solution was filtered and dried in the air to obtain a white powder. When the powder was recrystallized using a solution containing ethyl acetate, 24 g of compound 3 (76% yield) of white crystals could be obtained.

  Compound 3 (24 g, 77 mmol and a mixture of carbon (2.4 g) supporting 10% palladium in methanol (500 ml) was reduced overnight in a hydrogen reducing atmosphere at 1.5 atmospheres. Compound 4 (21g) was synthesized.

Compound 4 (21 g, 75 mmol) and di (tert-butyl) dicarbonate (18 g, 82 mmol) were stirred in anhydrous dichloromethane (DCM) (200 ml) overnight in a nitrogen atmosphere. The resulting solution was evaporated in vacuo and then dissolved with methanol (100 ml). Thereafter, sodium hydroxide (15 g, 374 mmol) and water (50 ml) were added and refluxed for 5 hours. Thereafter, the mixture was cooled, filtered through a filter, washed with water, and then dried in vacuo to obtain a brown compound.
The obtained compound was subjected to flash chromatography using silica gel twice to obtain 10 g of compound 6 (yield 58%).

  Compound 6 (10 g, 42 mmol) was placed in 400 ml of absolute ethanol, refluxed with heating, and ethylenediamine (1.3 g, 21 mmol) was added to 20 ml of absolute ethanol with stirring for several hours with a few drops. The mixed solution was cooled in an ice container and stirred for 15 minutes. Then, it was washed with 200 ml of ethanol, filtered, and dried under vacuum. Compound 7 was synthesized in 8.5 g (yield 82%).

Compound 7 (8.2 g, 16 mmol) and triethylamine (22 ml, 160 mmol) in anhydrous methanol (50 ml) were added, and a solution of FeCl ₃ (2.7 g, 16 mmol) in 10 ml methanol was mixed under a nitrogen atmosphere. . When mixed for 1 hour in a nitrogen atmosphere at room temperature, a brown compound was obtained. Then, it was dried in vacuum. The obtained compound was diluted with 400 ml of dichloromethane, washed twice with a salt solution, dried with Na ₂ SO ₄ , and dried in vacuo to obtain complex A.
The obtained compound was recrystallized in a solution of diethyl ether and paraffin and measured by high performance liquefaction chromatography to obtain 5.7 g of complex A (iron-salen complex) having a purity of 95% or more (yield 62%).
The subsequent ligation with the drug was performed through a reaction step such as acylation of the drug and Et3N.

(Example 2)
The electron transfer of the compound of Formula 1 and the compound bonded thereto was also determined by the first principle calculation.
What is the system that realizes this computer simulation? The computer includes known hardware resources as a computer, that is, includes a memory, an arithmetic device including an arithmetic circuit such as a CPU, and display means for outputting an arithmetic result. The memory includes data for specifying an existing organic compound or three-dimensional structure, and a software program for realizing computer simulation. This software can add / change / delete the side chains of each compound, cross-link between the given side chains, calculate the region with the high spin charge density described, and determine the spin charge density of the entire structure Is. As this program, for example, a commercially available product (Dmol3, Accelrys Inc.) can be used.
The user inputs the position where the side chain is added to the compound, or selects the side chain to be changed or deleted, and further uses the memory support program to determine where to form a bridge in the arithmetic unit. specify. The arithmetic unit receives this input value, calculates the spin charge density, and outputs the result to the display screen. Further, the user can obtain the spin charge density of a known compound by adding the structure data of the existing compound to the computer system.
The method for designing magnetic drugs is the same as PCT / JP2007 / 63011.

The charge transfer binding to the iron-salen complex (chemical formula (1)) and its R moiety can be obtained by integrating the upward and downward spin charge densities obtained above in a three-dimensional space.
Table 1 shows the calculation results of charge transfer. Table 1 shows the charge transfer bound to the iron-salen complex (chemical formula (I)) and its R moiety. A minus indicates that the number of electrons is increasing. A plus indicates that the number of electrons is decreasing.

Claims (13)

A drug having magnetism, comprising an iron-salen complex represented by the following formula (I):

  The magnetic agent according to claim 1, wherein R is a charge transfer of less than 0.5 electrons (e). The drug having magnetism according to claim 1, wherein R is a substituent obtained by removing hydrogen from any one of the following formulas (1) to (27).

  The magnetic drug according to any one of claims 1 to 3, which is configured to be guided to a target tissue or an affected part by a magnetic field applied to the individual when administered to the individual.   The magnetic drug according to claim 4, wherein a magnetic field is applied to the tissue or affected area from the outer surface of the individual so as to be guided to the tissue or affected area.   The magnetic agent according to claim 5, wherein a magnetic force generating means is applied in the tissue or the affected part of the individual so as to be guided to the tissue or the affected part.   The magnetic force generating means is arranged in the middle of a path of a blood vessel or the like for supplying the body fluid of the individual into the tissue or the affected part of the individual so as to be guided to a downstream tissue or affected part. Drug with magnetic properties. A guidance system for guiding the drug having magnetism according to any one of claims 1 to 3 administered into the body to a predetermined affected area using the magnetism of the drug,
A drug induction system in which means for generating a magnetic field is arranged on the surface of an individual or on the tissue or affected area of the individual. A guidance system for guiding the drug having magnetism according to any one of claims 1 to 3 administered into the body to a predetermined affected area using the magnetism of the drug,
A drug guidance system comprising: means for generating a magnetic field for an individual; and means for guiding the magnetic field to the fixed target tissue or affected area.   9. The means for generating a magnetic field is configured so that two magnets are paired, the target tissue or affected area is placed between the two magnets, and magnetic flux is concentrated on the tissue or affected area. Or the drug guidance system according to 9,   The drug induction system according to any one of claims 8 to 10, wherein the target tissue or affected part is identified by MRI or CT.   A magnetic detection apparatus for detecting the pharmacokinetics of the drug by detecting magnetism or luminescence of the drug having magnetism according to any one of claims 1 to 3 administered into the body.   The magnetic detection device according to claim 12, wherein the magnetism is detected by magnetic resonance induction or light emission.