JP2008266214A - Composite particles using gold iron oxide particles, and mri contrast medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a practical MRI contrast medium applicable to not only liver tumor but also tumors of several objective tissues, and to provide particulates applicable as the contrast medium. <P>SOLUTION: The composite particles are provided by bonding a polyalkylene glycol through sulfur to all or a part of gold particulates in gold iron oxide particles comprising magnetic iron oxide particle and a plurality of gold particulates thereon. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to composite particles using gold iron oxide particles and an MRI contrast agent containing the composite particles.

  In recent years, CT (Computed Tomography) using X-rays and MRI (Magnetic Magnetic Resonance) using magnetic resonance as image diagnostic techniques that can visually read information necessary for diagnosis of cancer lesions and decision of treatment policy The resonance image method is generally known. In particular, the MRI method can detect even smaller cancers compared to conventional serum biochemical or histological cancer diagnosis, and it does not use X-rays, so there is no risk of radiation exposure for children and healthy subjects. There is an advantage that the person can be inspected with confidence.

  The MRI method is a technique that uses the nuclear magnetic resonance (NMR) phenomenon of hydrogen nuclei (protons), which occupy most of the human body constituents, to image the difference and distribution of the states as light and shade. This is because the conventional CT method using X-rays basically obtains anatomical findings, but cross-sectional images in arbitrary directions such as sagittal, transverse, and coronal images are available. It has features such as being capable of imaging and good soft tissue contrast, and has been widely applied to clinical use with the progress of three-dimensional image processing technology.

In the MRI method, a contrast agent is often used in order to contrast a specific tissue including cancer more clearly. A contrast agent is a pharmaceutical product for examination for enhancing image contrast between a normal tissue and a target tissue in diagnosis, and is usually used by intravenous injection. Contrast agents for MRI differ in principle from the X-ray imaging diagnosis such as CT method, so X-ray absorptive substances such as barium and iodine are not magnetic substances that usually affect nuclear magnetic resonance. For example, gadolinium preparations and iron preparations are commercially available. Specific examples include ferridex (manufactured by Eiken Chemical Co., Ltd., sold by Tanabe Seiyaku Co., Ltd.) using (Fe ₂ O ₃ ) m (FeO) n (where 0 <n / m <1) as a raw material.

  However, since a commercially available contrast medium for MRI has high liver accumulation and poor blood stability, there is a problem in that its use is limited to liver tumor imaging due to physiological and physical characteristics. Therefore, in order to develop a tumor imaging method based on MRI as a more versatile cancer diagnostic technique, development of an MRI contrast agent that can be applied not only to liver tumors but also to various target tissues is desired. It was.

  Here, Patent Document 1 discloses a method for producing gold iron oxide particles. This document describes that the gold iron oxide particles may be used as a contrast agent, but its practicality as an MRI contrast agent is unclear.

  Non-Patent Document 1 describes that fine particles in which PEG is supported on the surface of iron fine particles coated with a polymer film can be used as an MRI contrast agent. However, the method for producing fine particles is not sufficiently disclosed to the extent that it can be reproduced, and lacks practicality as an MRI contrast agent.

WO2004 / 083124 J.AM.CHEM.SOC.2006,128,7383-7389

  An object of the present invention is to provide a practical MRI contrast agent that can be applied not only to liver tumors but also to tumors of various target tissues, and microparticles that can be used therefor.

  As a result of intensive studies to solve the above problems, the present inventors have found that all or part of the gold fine particles of the gold iron oxide particles provided with a plurality of gold fine particles on the surface of the magnetic iron oxide particles has sulfur added thereto. The present inventors have found that composite particles to which polyalkylene glycol is bonded can be applied not only to liver tumors but also to tumors of various target tissues as MRI contrast agents.

The present invention has been completed based on the above findings, and provides novel composite particles of the following items and an MRI contrast agent containing the composite particles.
Item 1. Composite particles in which polyalkylene glycol is bonded to all or part of gold fine particles of gold iron oxide particles having a plurality of gold fine particles on the surface of magnetic iron oxide particles via sulfur.
Item 2. Item 2. The composite particle according to Item 1, wherein the magnetic iron oxide is at least one selected from the group consisting of Fe ₃ O ₄ , γ-Fe ₂ O ₃ and ferrite.
Item 3. Item 3. The composite particle according to Item 1 or 2, wherein the primary particle size of the gold iron oxide particles is 5 to 200 nm.
Item 4. Item 4. The composite particle according to any one of Items 1 to 3, wherein the average particle size of the secondary particles of the gold iron oxide particles is 100 to 1000 nm.
Item 5. Item 5. The composite particles according to any one of Items 1 to 4, wherein the weight ratio of the gold fine particles to the magnetic iron oxide particles in the composite particles is 10: 1 to 1: 1 (gold fine particles: magnetic iron oxide particles).
Item 6. Item 6. The composite particles according to any one of Items 1 to 5, wherein the gold fine particles have an average particle size of 1 to 20 nm.
Item 7. Item 7. The composite particle according to any one of Items 1 to 6, wherein the entire surface of the magnetic iron oxide particle is substantially covered with gold fine particles.
Item 8. Item 8. The composite particle according to any one of Items 1 to 7, wherein the polyalkylene glycol is polyethylene glycol (PEG).
Item 9. Item 9. The composite particle according to any one of Items 1 to 8, wherein the polyalkylene glycol has a molecular weight of 2000 to 300,000.
Item 10. Item 10. An MRI contrast agent comprising the composite particle according to any one of Items 1 to 9. Item 11. The MRI contrast agent according to Item 10, which is a tissue non-specific MRI contrast agent.

The composite particle of the present invention is characterized in that it can be used as an MRI contrast agent that can be applied not only to liver tumors but also to tumors of various target tissues.
Conventional MRI contrast agents are hardly taken up into tumor tissues after intravenous administration by intravenous drip or the like, and about 80% of the administered particles are taken up into normal hepatocytes (mainly Kupffer cells) in just a few minutes after administration. Contrast agents accumulated only in normal liver tissue by this mechanism cause local magnetic field disturbance only in normal hepatocytes when irradiated with electromagnetic waves, resulting in an MRI signal contrast between liver tumor and normal liver tissue. It is enhanced to enable high-sensitivity imaging of liver tumors. However, on the other hand, there is a problem that the use of the conventional MRI contrast agent is limited to liver tumor imaging because such a biological phenomenon does not occur in other target tissues.

In this regard, the MRI contrast agent using the composite particles of the present invention is characterized in that it accumulates specifically in the tumor tissue by binding polyalkylene glycol via sulfur to the gold fine particles on the surface of the magnetic iron oxide particles. As a result, it has become a non-tissue-specific and versatile MRI contrast agent whose use is not limited to liver tumor imaging.
In addition, the composite particles of the present invention can arbitrarily adjust the amount of polyalkylene glycol supported by adjusting the amount (number and size) of gold fine particles supported in the gold iron oxide particles. Dynamics can be easily controlled.
In the composite particles of the present invention, since polyalkylene glycol is bonded to gold iron oxide particles via sulfur, polyalkylene glycol is not detached from the gold iron oxide particles after administration, and as an MRI contrast agent. It is highly practical.
The composite particles of the present invention can be produced by a simple method of mixing gold iron oxide particles and polyalkylene glycol having a thiol group, for example. In addition, as described later, since the gold iron oxide particles are obtained in a sterilized state, it is possible to easily obtain sterilized composite particles using a polyalkylene glycol having a thiol group that has been separately sterilized. Easy to use.

Hereinafter, the present invention will be described in detail.
The composite particles of the present invention are composite particles in which polyalkylene glycol is bonded to all or part of gold fine particles of gold iron oxide particles having a plurality of gold fine particles on the surface of magnetic iron oxide particles via sulfur. It is characterized by that.

Hereinafter, after the details of the method for producing composite particles are described, the composite particles will be described.
Method for Producing Gold Iron Oxide Particles Gold iron oxide particles are obtained by dispersing magnetic iron oxide particles in a liquid containing gold ions or a gold complex and irradiating with gamma rays, electron beams, or ultrasonic waves. Specifically, it can be produced by the method described in Patent Document 1.

< Magnetic iron oxide particles >
The magnetic iron oxide particles used in the present invention are magnetic iron oxide fine particles. Examples of the iron oxide include magnetite, iron tetroxide (Fe ₃ O ₄ ), gamma hematite, and ferrite. Among these, fine particles of triiron tetroxide (Fe ₃ O ₄ ) and gamma hematite (γ-Fe ₂ O ₃ ) are preferable because of their low toxicity to living bodies.
Magnetic iron oxide particles having an average primary particle size of about 10 nm may be used. Here, the average particle diameter is an average value obtained by measuring the particle diameters of 20 particles by electron microscope observation.
Moreover, the said magnetic iron oxide particle and its manufacturing method are known. For example, it can be produced by the PVS (Physical Vapor Synthesis) method (see CJ Parker, MN Ali, BB Limpany, US Pat. No. 5,514,349A). Furthermore, since magnetic iron oxide particles are already commercially available, in the present invention, such a commercially available product, for example, Feridex (manufactured by Eiken Chemical Co., Ltd., sold by Tanabe Seiyaku Co., Ltd.) can also be used.

< Supporting gold fine particles >
Gold fine particles can be provided on the surface of magnetic iron oxide particles by adding the above-described magnetic iron oxide particles to a solution containing gold ions or a gold complex and irradiating them with gamma rays, electron beams or ultrasonic waves.
The gold ion-containing liquid is an aqueous solution or alcohol solution containing gold ions, and the preparation is carried out with a suitable compound that gives gold ions as water, hydrous alcohol or alcohol (methanol, ethanol, n-propanol, etc.), hydrochloric acid, sulfuric acid, nitric acid, etc. It can be carried out by dissolving it in an acid (which may contain an organic substance such as alcohol). Suitable compounds include gold nitrate, chloride, acetate, citrate and the like. Of these, HAuCl ₄ is preferred.
Examples of the liquid containing a gold complex include an aqueous solution of a compound in which an appropriate ligand is coordinated to the gold ion, a hydrous alcohol, or an alcohol solution. The ligand is not particularly limited as long as it has an unshared electron pair or a negative charge, and can be selected without limitation from known ones. Specifically, for example, halide ions, cyanide ions, ammonia, pyridine, etc. as monodentate ligands; ethylenediamine, acetylacetone ions, etc. as bidentate ligands; ethylenediaminetetraacetate ions as hexadentate ligands And so on.
The gold concentration in the gold ion-containing liquid and the gold complex-containing liquid may be about 1 μM to 1M. The amount of magnetic iron oxide particles added to the gold ion-containing liquid and gold complex-containing liquid may be about 0.001 to 50% by weight.

< Gamma ray, electron beam, or ultrasonic irradiation >
Although a general gamma ray can be used as the gamma ray, the gamma ray by cobalt 60 is preferable. The irradiation amount and the irradiation time are usually 3 kGy / h, and the irradiation may be performed for about 3 hours.
As the electron beam, a general electron beam can be used, but an electron beam by a linear accelerator is preferable. The irradiation amount and irradiation time may be irradiation of an electron beam (energy: 10 MeV) from an electron beam accelerator, usually at 1 MGy / h for about 20 seconds.
As the ultrasonic wave, a general ultrasonic wave can be used, but an ultrasonic wave of about 200 kHz is preferable. The irradiation amount and the irradiation time are usually 200 W and may be irradiation for about 30 minutes.
By the above method, gold iron oxide particles suitable for the production of the composite particles of the present invention can be obtained.

< Polyalkylene glycol bond >
In the composite particles of the present invention, an excessive amount of polyalkylene glycol having sulfur atoms is added to the gold iron oxide particles in the solution containing the gold iron oxide particles obtained by the above method and incubated at room temperature for about 1 hour. Can be obtained. You may make it react with the polyalkylene glycol which has a sulfur atom in the state which isolate | separated gold iron oxide particles from said solution, and was suspended in solutions, such as distilled water. The incubation temperature and time are preferably about 16 to 25 ° C. and about 1 hour. If it is the said range, reaction will fully advance and the yield of the target composite particle will also become sufficient.

< Polyalkylene glycol >
The polyalkylene glycol used for the production of the composite particles of the present invention has a sulfur atom in the end of the molecule or in the molecule. This is because sulfur atoms are used to bond the gold iron oxide particles and the polyalkylene glycol. The sulfur atom should just be contained as a thiol group (-SH group), for example. The site and number of sulfur atoms contained in the polyalkylene glycol molecule are not particularly limited. The sulfur atom may be bonded to the terminal or inside of the polyalkylene glycol molecule. Among these, it is preferable that the terminal is bonded. When at least one polyalkylene glycol molecule is bonded to the inside of the polyalkylene glycol molecule, the polyalkylene glycol molecule is bent and bonded to the gold iron oxide particle, so that the number of polyalkylene glycol chains extending from the gold iron oxide particle is increased.
As the polyalkylene glycol used in the present invention, a known polyalkylene glycol can be used without limitation. Known polyalkylene glycols include polymethylene glycol, polyethylene glycol, polypropylene glycol, and the like, and polyethylene glycol (hereinafter sometimes referred to as “PEG”) is preferable from the viewpoint of good biocompatibility.
The molecular weight of the polyalkylene glycol is usually about 2000 to 300,000, preferably about 2000 to 200,000, and more preferably about 5000 to 150,000. Within the above range, a non-tissue-specific contrast agent having high blood retention and low liver accumulation is obtained.
Thus, the composite particle of the present invention is obtained in which a plurality of gold fine particles are provided on the surface of the magnetic iron oxide fine particles, and the polyalkylene glycol is bonded to the gold fine particles via sulfur atoms.

Composite Particles of the Present Invention In the composite particles of the present invention, PEG is bonded to gold fine particles via sulfur atoms (via Au—S bonds). Specific examples include -S-, -SS- and the like. Further, the case where atoms other than sulfur intervene in addition to sulfur is also included in the scope of the present invention.
In the composite particles of the present invention, the average particle size of the gold fine particles supported on the magnetic iron oxide particles is usually about 1 to 20 nm, preferably about 1 to 10 nm, more preferably about 1 to 5 nm. If it is the said range, PEG can be couple | bonded with high efficiency using a surface area. Moreover, if it is the said range, a gold fine particle will exist stably on the magnetic iron oxide surface, and the favorable dispersibility of a composite particle can be maintained.
The average particle size of the primary particles of the gold iron oxide particles is preferably about 5 to 200 nm, more preferably about 30 to 100 nm, and still more preferably about 50 to 100 nm. Further, although the gold iron oxide particles may be aggregated, the average particle diameter of the secondary particles is preferably about 100 to 1000 nm, more preferably about 100 to 800 nm, and still more preferably about 100 to 500 nm. The primary particle here means a particle in which gold fine particles are supported on the surface of magnetic iron oxide, and the secondary particle means an aggregate of a plurality of the primary particles. If it is the said range, it will be easy to pass through the blood-vessel wall in a tumor tissue, and it can accumulate | store in a tumor tissue effectively. By adjusting the size of the magnetic iron oxide particles as a raw material, the average particle diameter of the gold iron oxide particles can be adjusted to the above range. The primary particle diameter of the gold iron oxide particles is a value measured by dynamic light scattering or electron microscope observation, and the secondary particle diameter is a value measured by the dynamic light scattering method.
Further, the supported amount of the gold fine particles in the gold iron oxide particles is preferably such that the weight ratio of the gold fine particles to the magnetic iron oxide particles (gold fine particles: magnetic iron oxide particles) is about 1 to 10: 1. It is more preferable that the ratio is about 1. If it is the said range, polyalkylene glycol can fully be carry | supported and a practical contrast effect will be acquired.
By adjusting the concentration of the gold ion or gold complex in the gold ion or gold complex-containing liquid and the amount of the magnetic iron oxide fine particles added thereto within the above range, the supported amount of the gold fine particles can be adjusted within this range. it can. The surface of the magnetic iron oxide particles is preferably substantially covered with gold, so that the amount of polyalkylene glycol bound can be increased. The amount of polyalkylene glycol supported on the gold iron oxide particles is determined by the amount of gold fine particles supported on the magnetic iron oxide particles and the number and position of sulfur atoms in the polyalkylene glycol molecule. The greater the amount of polyalkylene glycol supported, the better the blood retention.
<Use of composite particles of the present invention>
The composite particles of the present invention can be used in various applications as a dispersion as produced. Moreover, it can also be made into a product suspended in a suitable solution or dried. Since the composite particle of the present invention is magnetic, it can be suspended in another solution or separated from the solution by magnetic separation using a magnet or the like using the magnetism. Further, since the composite particles of the present invention are magnetized, they can be guided to a target tissue using an external magnetic field.
The composite particle of the present invention can be suitably used as an active ingredient of an MRI contrast agent. The form of the preparation in this case may be the same as that of a conventional MRI contrast agent. A typical example is a preparation in which the composite particles of the present invention are suspended in a solution such as physiological saline. The concentration of the composite particles in the solution may be about 1 to 50% by weight, for example. Since the polyalkylene glycol is bonded to the composite particles of the present invention, the preparation can contain no dispersant and can be a highly safe preparation.
When actually used as an MRI contrast agent in the human body, as in the conventional method of administering an MRI contrast agent, the vein concentration is adjusted to a salt concentration that can be intravenously injected as it is or mixed with glucose injection solution at the time of use. It can be administered by injection or infusion. The dose may be about the same as a commercially available iron MRI contrast medium.
The MRI contrast agent using the composite particles of the present invention has a feature that it has non-specific tissue by carrying polyalkylene glycol, and the contrast site is not limited to a liver tumor.

  EXAMPLES The present invention will be described in detail below based on examples, but the present invention is not limited to these examples.

(1) Preparation of magnetic iron oxide particles for preparation of composite particles of the present invention Commercially available magnetic iron oxide particles (generic name: fermoxides, molecular formula (Fe ₂ O ₃ ) m (FeO) n: where 0 <n / m <1, trade name: Feridex (registered trademark), manufactured by Eiken Chemical Co., Ltd., sold by Tanabe Seiyaku Co., Ltd.). Feridex has an average primary particle size of 10 nm and an average secondary particle size of 80 nm.

(2) Preparation of gold ion-containing liquid for preparation of composite particles of the present invention HAuCl ₄ was dissolved in pure water so that 0.5 mM of gold ions was contained. Furthermore, to this solution, polyvinyl alcohol (average molecular weight 22000) was added to a concentration of 10 grams / liter, and 2-propanol was added to a concentration of 10 milliliters / liter. All reagents were purchased from Wako Pure Chemical Industries.

(3) Preparation of gold iron oxide particles for preparation of the composite particles of the present invention The above magnetic iron oxide particles 5 mg and gold ion-containing liquid (gold ions 0.5 mM, 50 ml) are mixed in a 100 ml beaker, An electron beam (energy: 10 MeV) from a linear accelerator was irradiated for 20 seconds at a dose rate of 1 MGy / h.
By the above method, gold fine particles were supported on the surface of the magnetic iron oxide particles, and gold iron oxide particles for preparing the composite particles of the present invention were obtained. The average particle size of the gold fine particles supported on the obtained gold iron oxide particles was 6 nm, and the secondary particle size of the gold iron oxide particles was 250 nm. Further, the supported amount of gold fine particles in the gold iron oxide particles was 1: 1 (magnetic iron oxide: gold fine particles).

(4) Preparation of polyalkylene glycol for preparation of composite particles of the present invention Commercially available PEG-SH (manufactured by NOF Corporation, trade name SUNBRIGHT (registered trademark) SH Series, molecular weight 5000) was used.

(5) Preparation of composite particles of the present invention The above-mentioned gold iron oxide particles are purified or concentrated to a final concentration of 20 mg / ml by centrifugation, and 40 μl of 10 mM PEG-SH is further added, followed by 1 hour at room temperature (22 ° C.) Incubated. As a result, composite particles in which PEG was bonded to the surface of the gold iron oxide particles via sulfur atoms were produced. The solution was centrifuged to precipitate composite particles and resuspended in distilled water. The composite particles purified by repeating this washing operation three times were used in the following experiments.

(6) Demonstration experiment of PEG binding to gold iron oxide particles In the presence of polyvinyl alcohol (hereinafter referred to as “PVA”), PEG hydrogen bonds with PVA, so that PVA works as a cross-linking agent and PEG The gold iron oxide particles on which is supported cause aggregation and precipitation. Using this phenomenon, it was proved that PEG was actually supported on the composite particles of the present invention. Specifically, after adding a PVA solution so that the final concentration is 0.2 to 0.3 (g / ml) to the composite particles prepared in (5) above, the particles are incubated at room temperature for 3 hours, The presence or absence of aggregation was confirmed visually.
The results are shown in FIG. Aggregation due to the addition of PVA did not occur with the gold iron oxide particles alone, whereas in the composite particles to which PEG-SH was bound, precipitation of the particles was observed due to cross-linking of PVA and PEG. From this, it was found that gold magnetic iron oxide can be modified with PEG by using PEG-SH.

(7) Demonstration experiment that PEG is bonded to gold iron oxide particles by sulfur atom-When an excessive amount of cysteine is added in the presence of PEG by S-bonding and incubated at room temperature for about 1 hour, cysteine The inside -SH group causes a competitive reaction with the -S-bond of PEG, resulting in substitution of PEG and cysteine. In the suspension in which PEG is replaced with cysteine when PVA is further added after purification, aggregation and precipitation due to hydrogen bonding between PEG and PVA are not observed. Using this phenomenon, it was proved that PEG was bonded to gold iron oxide particles by sulfur atoms. Specifically, after adding a 10 mM cysteine solution to the composite particles of the present invention prepared in (5) above, the PVA qualitative reaction described in (6) was performed.
The result is shown in FIG. In the composite particles of the present invention, aggregation or precipitation of PVA-dependent particles was observed, whereas in the group in which PVA was added after mixing the composite particles of the present invention and an excess amount of cysteine, particle aggregation was performed. Was not recognized at all. The above results confirm that PEG-SH is bonded to the particle surface via a sulfur atom.

(8) Applicability experiment of composite particles of the present invention as an MRI contrast agent In order for the composite particles of the present invention obtained in (5) to function effectively as an MRI contrast agent, a sufficient ability to shorten the relaxation time of water molecules It is necessary to have. Therefore, Feridex, gold iron oxide particles, and the composite particles of the present invention obtained in (5) are suspended in distilled water at various concentrations, and an NMR measurement apparatus (Varian: Varian Unity INOVA 400WB high resolusion NMR spectrometer) Were used to measure T1, T2, and T2 * values.
Results Table 1 shows the measurement results of T1, T2, and T2 * of each particle. As a result of H-NMR spectral analysis, it was found that the composite particles of the present invention obtained in (5) have the property of shortening the relaxation time (T1, T2, T2 *) of water molecules. From this result, it was shown that the composite particles of the present invention retain the properties as an MRI contrast agent.

* T1 “s”, T2 “s”, T2 * “s”: Index of relaxation time of water. The smaller these values, the more relaxed the water.

(9) Contrast was actually performed using the composite particles of the present invention obtained in the imaging experiment (5) using the composite particles of the present invention. After administering Feridex, gold iron oxide particles, and the composite particles of the present invention at 10 mg / mouse from the tail vein, whole body MRI images of the mice were photographed using an NMR measurement apparatus. The suitability as an MRI contrast agent was evaluated. Specifically, tumor cells (Meth-A fibroblastoma) were transplanted under the abdominal skin tissue of mice (Balb / c, 6 weeks old), and tumor-bearing mice having a major axis of about 15 to 20 mm were prepared. . The tumor-bearing mice were administered 1 mg / 100 μl (distilled water) / mouse from the tail vein with the composite particles of the present invention obtained in (5) or 4 to 7 hours later, and MRI imaging of the whole body and tumor cross section was performed. Carried out.
Results The results obtained are shown in FIG. In the mouse administered with the upper ferridex, the tumor implanted in the abdomen is not shown in white and contrasted, whereas the tumor in the mouse administered with the lower composite particle is clearly contrasted in black. From these results, it was confirmed that the composite particles of the present invention sufficiently and practically function as an MRI contrast agent that has an accumulation property in cancer tissue and can be applied to organs other than the liver.

(10) Tumor accumulation evaluation experiment of composite particles of the present invention It was confirmed that the composite particles of the present invention were accumulated in tumor cells of tissues other than the liver. Specifically, tumor cells (Meth-A fibroblastoma) were transplanted under the abdominal skin tissue of mice (Balb / c, 6 weeks old), and tumor-bearing mice having a major axis of about 15 to 20 mm were prepared. . MRI contrast agent using the composite particles of the present invention obtained in (5) and gold iron oxide particles not subjected to PEG modification obtained in (3) were injected into the tumor-bearing mice via tail vein (1 mg / 100 μl). (Distilled water) / mouse), and after 24 hours from the injection, the tumor tissue was collected and stained with Berlin Blue. Specifically, the collected tissue was fixed with 4% formalin diluted with phosphate buffered saline (room temperature, 24 hours), and further immersed in a 0.3 (g / ml) sucrose solution. Frozen tissue sections (3 μm) were prepared from tissues immersed for 24-72 hours and reacted with Berlin blue solution containing 0.01 (g / ml) potassium ferrocyanide and 0.01 (g / ml) hydrochloric acid for 30 minutes. It was. By observing the colored specimen under a microscope, the localization of the blue colored iron oxide particles was analyzed.
The result is shown in FIG. In the group administered with gold iron oxide particles not subjected to PEG modification, no blue spot derived from iron oxide was observed in the tumor tissue. On the other hand, since a blue stained image derived from iron oxide particles was observed in the tumor tissue of mice administered with the composite particles of the present invention, the tumor tissue of the MRI contrast agent was modified by PEG modification of the gold iron oxide particles. It was shown that the integration can be improved.

  The MRI contrast agent using the composite particles of the present invention is not limited to liver tumors and can be used in a non-tissue-specific manner, so that image diagnosis by MRI with wider versatility is possible.

It is a figure which added what added PVA to the suspension of the composite particle which carry | supported PEG on the gold iron oxide particle and the gold iron oxide particle. It is the figure which added PVA to the suspension of the composite particle which carried out the cysteine process, and the composite particle which has not carried out the cysteine process. It is a MRI contrast image of the mouse | mouth which administered the ferridex, and the mouse | mouth which administered the MRI contrast agent which consists of composite particle | grains of this invention. It is a figure which shows what stained the tumor tissue of a mouse | mouth with Berlin blue.

Claims (11)

  A composite particle comprising a gold iron oxide particle having a plurality of gold fine particles on the surface of a magnetic iron oxide particle and polyalkylene glycol bonded to all or a part of the gold fine particle via sulfur. _2. The composite particle according to claim 1, wherein the magnetic iron oxide is at least one selected from the group consisting of Fe ₃ O ₄ , γ-Fe ₂ O ₃ and ferrite.   The composite particles according to claim 1 or 2, wherein the primary particles of gold iron oxide particles have an average particle size of 5 to 200 nm.   The composite particle according to any one of claims 1 to 3, wherein the secondary particles of the gold iron oxide particles have an average particle size of 100 to 1000 nm.   The composite particles according to any one of claims 1 to 4, wherein a weight ratio of the gold fine particles to the magnetic iron oxide particles in the composite particles is 10: 1 to 1: 1 (gold fine particles: magnetic iron oxide particles).   The composite particle according to any one of claims 1 to 5, wherein the average particle diameter of the gold fine particles is 1 to 20 nm.   The composite particle according to any one of claims 1 to 6, wherein the entire surface of the magnetic iron oxide particle is substantially covered with gold fine particles.   The composite particle according to any one of claims 1 to 7, wherein the polyalkylene glycol is polyethylene glycol (PEG).   The composite particle according to any one of claims 1 to 8, wherein the molecular weight of the polyalkylene glycol is 2000 to 300,000.   The MRI contrast agent containing the composite particle in any one of Claims 1-9.   The MRI contrast agent according to claim 10, which is a tissue non-specific MRI contrast agent.