WO2007126151A1 - 機能性粒子およびそれを用いた標的物質の分離方法 - Google Patents
機能性粒子およびそれを用いた標的物質の分離方法 Download PDFInfo
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- WO2007126151A1 WO2007126151A1 PCT/JP2007/059550 JP2007059550W WO2007126151A1 WO 2007126151 A1 WO2007126151 A1 WO 2007126151A1 JP 2007059550 W JP2007059550 W JP 2007059550W WO 2007126151 A1 WO2007126151 A1 WO 2007126151A1
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Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
- G01N33/53—Immunoassay; Biospecific binding assay; Materials therefor
- G01N33/543—Immunoassay; Biospecific binding assay; Materials therefor with an insoluble carrier for immobilising immunochemicals
- G01N33/54313—Immunoassay; Biospecific binding assay; Materials therefor with an insoluble carrier for immobilising immunochemicals the carrier being characterised by its particulate form
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T428/00—Stock material or miscellaneous articles
- Y10T428/29—Coated or structually defined flake, particle, cell, strand, strand portion, rod, filament, macroscopic fiber or mass thereof
- Y10T428/2982—Particulate matter [e.g., sphere, flake, etc.]
Definitions
- the present invention relates to a functional particle suitable for separation, immobilization, analysis, extraction, purification, reaction, etc. of a target substance.
- the present invention also relates to a method of treating a target substance using powerful particles.
- Patent Document 1 Japanese Patent Laid-Open No. Hei 4 (1990)). Issue gazette).
- the composite particle having a force is magnetic and is formed, for example, by including a magnetic material in non-magnetic beads.
- the target particles bonded to the composite particles are recovered by moving the composite particles by applying a magnetic field to collect and aggregate them, and then recovering the aggregated and aggregated composite particles.
- Magnetic separation Such magnetic field or magnetic methods (hereinafter also referred to as “magnetic separation” or simply “magnetic separation”) require a smaller amount of sample than methods such as centrifugation, column separation, or electrophoresis. In addition, it has the feature that it can be carried out in a short time without denaturing the target substance.
- the density of the composite particles used was as small as 1.0 ⁇ ⁇ 111 3 to 3.4 g Z cm 3 , it was difficult to efficiently aggregate the composite particles. The reason why the density of the composite particles is relatively small is that a resin or silica having a low density is used as a base material, and a magnetic powder material is dispersed therein to form composite particles.
- the density of the composite particles depends on the amount of the magnetic powder material.
- the content of the magnetic powder material is only about 20% by weight, and the density of the composite particles is The value is close to low material density.
- Patent Document 2 Japanese Patent Application Laid-Open No. Hei 9 0 5 9 989
- the zirconium particles described in Patent Document 2 are It is made of a porous material with a three-dimensional internal penetration network (ie, through-hole), and nonspecific binding is likely to occur during the separation of the target substance.
- an object of the present invention is to provide a particle preferable for separation of a target substance in terms of movement / aggregation of particles and nonspecific binding. It is also an object of the present invention to provide a method for separating a target substance using powerful particles or a method for obtaining a particle on which a target substance is immobilized. Furthermore, a target substance using the particles of the present invention is also provided. Providing a method for conducting analysis, extraction, purification or reaction of these is also an issue of this effort. '
- the present invention is a particle to which a target substance can bind
- Substance or functional group capable of binding the target substance is immobilized on the surface of the particle body
- the density of the particles is 3.5 g / c ni 3 to 9. O gZ cm 3 , and
- a particle characterized in that the particle body does not have a through-hole.
- the particles of the present invention have “substance or functional group capable of binding a target substance” immobilized on the surface thereof.
- “substance or functional group that binds to the target substance” is immobilized. Therefore, when the target substance and particles coexist, the target substance can bind to the particles, so that the particles of the present invention can only be used for various uses such as separation, purification or extraction of the target substance. Not even The particles of the present invention can also be used for single-armed medical technology applications.
- the “target substance” substantially means a substance that can be various objects such as extraction, quantification, purification, or analysis as well as separation, and is directly or indirectly bound to the particle. Any kind of substance can be used if it is possible.
- Specific target substances include, for example, nucleic acids, proteins (including avidin and biotinylated HRP, etc.), sugars, lipids, peptides, cells, fungi, bacteria, yeasts, winoles, glycolipids, glycoproteins, complexes, Examples include inorganic substances, vectors, low molecular compounds, high molecular compounds, antibodies, and antigens.
- the particles of the present invention can be said to exhibit various functions in that they can be used for separation, purification, extraction or analysis of various target substances. Therefore, the particles of the present invention can be called “functional particles”.
- the particle of the present invention has a density of 3.5 g Z cm 3 to 9.0 g Z cm 3 , and has a feature that the density (or specific gravity) is larger than particles generally used for separation of target substances. have.
- the particles of the present invention have a feature that no through-holes are formed in the particle main body and that the particles are not porous. For this reason, in general, the specific surface area of the particles has become relatively small, from 0.0 0 0 5 m 2 / g to 1.0 m 2 Z g.
- the particle body does not have a through hole means that the particle body is substantially solid and the particle does not have an internal through network structure. That is, “the particle body does not have a through-hole” in this specification means “the particle body or the particle body core is solid”, “even if the particle surface is uneven, Does not exist even inside the particle ”, and“ the bulk density is higher than that of a general porous particle ”.
- a method for separating a target substance using the above-described particles is also provided.
- Such a separation method is a method for separating a target substance from a sample using the particles of the present invention as described above, and includes the following steps:
- the method of the present invention is characterized in that particles to which a target substance is bound are aggregated and aggregated by natural sedimentation. That is, the method of the present invention has a feature that the target substance is separated only by spontaneous sedimentation of particles without using a magnetic field or magnetism for particle movement and aggregation. In this way, the target substance can be separated only by the spontaneous sedimentation of particles because the natural sedimentation rate of particles is faster than before.
- the particles of the present invention not only have a high density of 3.5 ⁇ ⁇ 111 3 to 9.0 g Z c ni 3 but also have no through-holes and a specific surface area of 0. OOO. Since O m 2 / g is relatively small, there is an effect that a sufficient separation speed can be obtained only by the moving speed by the natural sedimentation of particles without using a centrifugal separation method and a magnetic separation method. In other words, the particles of the present invention are preferable particles for natural sedimentation not only in terms of density but also in terms of specific surface area.
- the particles of the present invention do not have through holes and have a specific surface area of 0.0. Since it is substantially non-porous, from 0 5 m 2 / g to l. O m V g, such adverse gas effects can be eliminated.
- “natural sedimentation” means that particles settle in a liquid under the action of gravity.
- “separation” means nucleic acid, protein, sugar, lipid, peptide, cell, fungus, bacteria, yeast, virus, glycolipid, glycoprotein, complex, inorganic substance, vector, low molecular weight compound, polymer Samples containing target substances such as compounds, antibodies or antigens (eg human or animal urine, blood, serum, plasma, semen, saliva, sweat, tears, ascites, amniotic fluid, etc .; human or animal organs) Suspensions of hair, skin, nails, bones, muscles or nerve tissues, extracts, lysates or disruptions; stool suspensions, extracts, lysates or disruptions; suspensions of cultured cells or tissues Solution, extract, lysate or disruption solution; virus suspension, extract, lysate or disruption solution; cell suspension, extract, lysis solution or disruption solution; soil suspension, extract Lysates or lysates; plant suspensions, extracts, Solution solution
- target substances such
- the particle to which the target substance is bound is moved. Substantially means to select the target substance from the sample.
- the “separation speed” substantially refers to the speed at which particles bound to the target substance move in the sample, and in the case of using for natural sedimentation, it substantially means the sedimentation speed of the particles. .
- the separation speed is high, the time required to separate the target substance from the sample is short. It should be understood that when the particles of the present invention have magnetism, the separation rate can be additionally increased by applying a magnetic field.
- the particles of the present invention can obtain a sufficient separation rate only by spontaneous sedimentation, the particles of the present invention can be used to separate, immobilize, analyze, extract, and purify target substances without using complicated mechanisms. Alternatively, a reaction or the like can be performed. In other words, when the particles of the present invention are used, a simple system for separating, immobilizing, analyzing, extracting, purifying or reacting a target substance can be obtained.
- the particles of the present invention are also effective for downsizing or chipping such a system.
- the particles of the present invention not only the density is large, the specific surface area is 0. 0 0 0 5 m 2 Z g ⁇ l. 0 m 2 Z g and relatively small, regarded as substantially non-porous As a result, non-specific binding of substances other than the target substance to the particles can be suppressed. In other words, due to the non-porous nature of the particles, there are few or substantially no particle pores or particle surfaces that can absorb and adsorb substances other than the target substance, and substances other than the target substance bind to the particles. Can be suppressed.
- the particles of the present invention can suppress nonspecific binding, the target substance can be efficiently purified and separated by simple operations.
- the polymer may adhere to the main body surface of the particle
- a “substance or functional group capable of binding the target substance” can be immobilized on the surface of the polymer (hereinafter also referred to as “adhesion polymer”).
- adheresion polymer a “substance or functional group capable of binding the target substance”
- the “substance that can bind the target substance” can be immobilized on the particle surface.
- “substance or functional group capable of binding the target substance” force s, immobilized on the surface of the particle body c
- the particles used in the separation method of the present invention not only have a high density but also have a specific surface area of 0.05 0 m 2 / g to l. Particles that are relatively small and can be considered substantially non-porous. As a result, when particles are supplied to a sample containing the target substance, it is possible to prevent a gas such as air from being taken into the particle ridge, and a sufficient separation rate can be obtained even by natural sedimentation. . Furthermore, as described above, the particles used in the separation method of the present invention are particles that can suppress “non-specific binding in which substances other than the target substance bind to the particles”.
- FIG. 1 is a diagram schematically showing the steps of the method of the present invention.
- FIG. 2 is a photograph of the non-porous yttrium-added di / reconia particles! That are the raw material particles of Example 1.
- Fig. 3 shows the non-porous yttrium-added ginol-coa particles p! It is the surface enlarged photograph of.
- FIG. 4 is a photograph of porous silica particles r 6 that are raw material particles of Comparative Example 6.
- FIG. 5 is an enlarged photograph of the surface of porous silica particles r 6 that are the raw material particles of Comparative Example 6.
- the particles of the present invention have a density suitable for separation of target substances. That is, body fluids such as human or animal urine, blood, serum, plasma, semen, saliva, sweat, tears, ascites, amniotic fluid; human or animal organs, hair, skin, nails, bones, muscles or nerve tissues Suspension, extract, lysate or disrupted solution; stool suspension, extract, lysate text is disruption; cultured cell or tissue suspension, extract, lysate or disrupted solution; virus suspension Suspension, extract, lysate or lysate; cell suspension, extract, lysate or disruption; soil suspension, extract, lysate or disruption; plant suspension, Extracted liquid, dissolved liquid or crushed liquid; foods ⁇ Processed food suspension, extracted liquid, dissolved liquid or crushed liquid; density at which the sedimentation rate of particles becomes relatively large when dispersed in a sample such as waste water The particles have.
- body fluids such as human or animal urine, blood, serum, plasma, semen, saliva, sweat, tears, as
- the particle density is less than 3.5 g / cm 3 , the speed of particle movement due to spontaneous sedimentation is not practically preferable, while when the particle density is greater than 9.0 gZcm 3 , the target substance is bound. It is not preferable for the stirring to be performed. Therefore, density of the particles of the present invention, 3. 5 g / cm 3 ⁇ 9 .
- a O gZcm 3, more preferably 5 is 0 g / cm 3 ⁇ 8. 0 g / cm 3, more preferably Is 5.5 g / cm 3 to 7.0 g Z cm 3 .
- density in the present specification means a true density in which only the volume occupied by the substance itself is a volume for density calculation, and the true density measuring device Ultrabitanometer 1000 (Uuasa Iotas) It can be obtained by using
- Preferred specific surface area of the particles of the present invention 0. 0005m 2 Zg ⁇ :.
- the particles of the present invention can be regarded as substantially non-porous, and the possibility that a substance other than the target substance binds to the particles (ie, “the possibility of non-specific binding”) is suppressed. . This means that the accuracy of target substance separation is improved.
- the particles of the present invention are substantially non-porous and have through-holes (ie, inner 0
- the “specific surface area” referred to in the present specification is a specific surface area obtained by using a specific surface area pore distribution measuring device S A 3 100 (manufactured by Coulter).
- the particles of the present invention can obtain a sufficient separation rate only by natural sedimentation.
- the natural sedimentation rate of particles in the sample containing the target substance is faster.
- the material of the particle body is not particularly limited as long as the particles of the present invention have the above-described density and specific surface area.
- the particle body is made of a metal or metal oxide, such as zirconia (zirconium oxide, yttrium-doped zirconium oxide), iron oxide, alumina, nickel, nickel, iron, copper and It is made of at least one material selected from the group consisting of aluminum.
- the particles of the present invention are magnetic.
- the particles of the present invention having magnetism are also referred to as “magnetic particles”. This is because the magnetic separation operation can be supplementarily performed for spontaneous sedimentation of particles. As a result, the particles can be moved faster, and the target substance (more specifically, the “target substance bound to the particles”) can be separated in a shorter time. Also, pipetting and decanting can be easily performed by collecting and fixing particles in a specific part by magnetism.
- the material of the main body of the magnetic particle is not particularly limited as long as the particle becomes magnetic.
- the main body of the magnetic particles is formed of at least one iron oxide selected from the group consisting of a gannet oxide comprising a transition metal and iron, ferrite, magnetite, and ⁇ -iron oxide. It is preferable.
- the body of magnetic particles contains Eckel, cobalt, iron and their metals. It may comprise at least one metal material selected from the group consisting of alloys consisting of g .
- “an oxide having a garnet structure comprising a transition metal and iron” is generally called YIG.
- magnetic particles may be formed by coating non-magnetic particles with a magnetic material, or by simply depositing a magnetic material on non-magnetic particles. May be formed.
- electroless plating, electroplating, sputtering, vacuum deposition, ion plating, or chemical vapor deposition can be used.
- non-magnetic particles include, for example, high-density particles composed of dinoleconia (zirconium oxide, yttrium-doped zirconium oxide), alumina, or the like.
- particles made of aluminum, silica, resin or the like having a lower density can be used.
- magnetic substance used for coating or deposition, ferrite, magnetite, ⁇ / —iron oxide, or a garnet-structured oxide comprising transition metal and iron, as in the case of the magnetic particles described above.
- iron oxides such as nickel, cobalt, iron, or alloys comprising these metals.
- the volume of the magnetic substance coating is preferably 5% or more with respect to the volume of the particles (particles including the magnetic substance coating).
- the thickness of the magnetic substance coating is preferably 1.7% or more with respect to the diameter of the particles (particles including the magnetic substance coating).
- magnétique properties of magnetic particles include “saturation magnetization” and “coercivity”.
- saturation magnetization the higher the value of saturation magnetization, the better the responsiveness of particles to a magnetic field.
- the magnetism in order to provide magnetism to particles having a relatively high density as in the present invention, the magnetism must be increased. It is necessary to provide a magnetic substance on the surface or inside of the particles that are not tinged. Here, since the magnetic substance has a lower density than the non-magnetic particles, the necessary density must be maintained by limiting the amount of the magnetic substance to be provided.
- a non-magnetic polymer is deposited on the particle body, it is practically difficult to obtain a larger saturation magnetic field than in the case where particles are made of only a magnetic substance.
- the saturation magnetization of the particles of the present invention is preferably 0.5 A m 2 / kg to 85 A ⁇ m 2 Zkg (0.5 emu Zg to 85 emu Zg), more preferably 3 A ⁇ M 2 Zk g ⁇ ; L 0 A 'm
- the coercive force is preferably OkAZn!
- the values of “saturation magnetization” and “coercive force” in this specification are values measured using a vibrating sample magnetometer (model VSM-5, manufactured by Toei Kogyo Co., Ltd.). Specifically, the value of “saturation magnetization” is a value obtained from the amount of magnetic field when a magnetic field of 797 kA / m (10 kiloelsted) is applied. The value of “coercive force” is the value of the applied magnetic field where the amount of magnetization becomes zero when a magnetic field of 797 kAZm is applied, the magnetic field is returned to zero, and the magnetic field is gradually increased in the opposite direction. Value.
- the shape of the particle of the present invention is not particularly limited, and may be, for example, a spherical shape, an ellipsoidal shape, a particle shape, a plate shape, a needle shape, or a polyhedral shape (for example, a cubic shape).
- the particle shape is preferably a regular shape, and particularly a spherical shape.
- the “non-magnetic particle body” is spherical. It is preferable to have a shape or an ellipsoidal shape.
- the average size (ie, “average particle size”) of the particles of the present invention is preferably from 1 / xm to L mm.
- the average particle size is smaller than 1 ⁇ , it is difficult to sufficiently increase the moving speed due to the natural sedimentation of the target substance during separation of the target substance, while when the average particle size is larger than l mm, the target This is because the particles may settle before binding to the substance, and the target substance may not be sufficiently separated. More preferably 5 n! An average particle size of ⁇ 500 ⁇ m, more preferably 10 ⁇ ! An average particle size of ⁇ 100 ⁇ m.
- Particle size refers to the length of the particle in all directions (the length of the particle, including the thickness of the polymer that is applied when the polymer is applied to the particle body).
- the term “average particle size” means, for example, 300 particles based on an electron micrograph or an optical micrograph of a particle. This means the particle size calculated as the average number of particles. Note that particles made of pure metal tend to oxidize rapidly when the size is small, and in some cases there is a risk of igniting the particles; ⁇ , with relatively large particle sizes such as the present invention, rapid oxidation may occur. The risk of ignition of particles is reduced.
- “Substances capable of binding a target substance” (hereinafter also referred to as “substances to which a target substance can bind”) immobilized on the surface of the particles of the present invention include piotin, avidin, streptavidin and It is preferably at least one substance selected from the group consisting of neutravidin.
- the “functional group capable of binding the target substance” (hereinafter also referred to as “functional group capable of binding the target substance”) immobilized on the surface of the main body of the particle of the present invention is a carboxyl group, Hydroxyl group, epoxy group, tosyl group, succinimide group, maleimide group, phenol group, sulfate group such as thioter group and disulfide group, aldehyde group, azide group, hydrazide group, primary amino group, secondary amino group At least one functional group selected from the group consisting of a tertiary amino group, an imidoester group, a canolepositimide group, an isocyanate group, a iodine acetyl group, a halopoxyl group, a double bond, and a double bond It is preferable.
- the “functional group to which the target substance can bind” may be a derivative of the functional group described above.
- immobilization generally means that a “substance capable of binding a target substance” or a “functional group capable of binding a target substance” exists near the surface of the particle body. It does not necessarily mean only the mode in which the “substance that can bind the target substance” or the “functional group that can bind the target substance” is directly attached to the surface of the particle body. Absent.
- immobilization substantially means an embodiment in which “substance or functional group capable of binding to a target substance” is immobilized on at least a part of the particle surface.
- the “possible substance or functional group” does not necessarily have to be immobilized over the entire particle surface.
- the “substance or functional group to which the target substance can bind” is present over the entire particle surface so that the particle body is included in the “substance or functional group to which the target substance can bind”.
- the term “target substance binds” not only includes a mode in which the target substance is “adsorbed” or “absorbed” with respect to the particle, but also between the target substance and the particle. It also includes embodiments in which the target substance is bound to the particles due to various “affinities” acting on the particles.
- the target substance is bound to the particle via the substance or functional group. be able to.
- the method for immobilizing the “substance that can bind the target substance” to the particle body is not particularly limited, and any technique that can bind or attach the “substance that can bind the target substance” to the particle body. Any method may be used. “Substances that can be bound by the target substance” are not limited to directly binding or adhering to the particle body, but if necessary, silicon-containing substances (for example, siloxane, silane coupling agent and sodium silicate), Alternatively, another substance such as a resin having a functional group to which the target substance can bind or adhere is attached or introduced in advance to the particle body, or the surface of the particle body is subjected to noble metal deposition treatment and then the target substance.
- silicon-containing substances for example, siloxane, silane coupling agent and sodium silicate
- the “substance that can be bound to the target substance” can be easily immobilized on the particle. It's okay.
- a silicon-containing substance is used, a “substance that can bind to the target substance” is immobilized on the surface of the particle body, and such a silicon-containing substance is present.
- An example of a method for fixing a “substance capable of binding a target substance” to a particle body is described, for example, by reacting a silane coupling agent having an epoxy group or an amino group on the surface of the particle body.
- a substance that can bind to the target substance can be immobilized on the particle.
- the method for immobilizing the “functional group to which the target substance can bind” to the particle body is not particularly limited, and the “functional group to which the target substance can bind” is bonded to or attached to the particle. Any method can be used as long as it is possible.
- the “functional group to which the target substance can bind” may be chemically treated and converted to another functional group to change the reactivity, adsorption, etc.
- the “functional group to which the target substance can bind” is directly bonded or attached to the particle body, but also a silicon-containing substance (for example, Other substances such as siloxane, silane coupling agent and sodium silicate), resin having functional groups to which the target substance can bind or attach, are previously attached to or introduced into the particle body, or the particle body.
- a noble metal deposition treatment to the surface of the particles and attaching or introducing another substance such as a sulfur-containing compound having a functional group to which the target substance can bind or adhere in advance to the particle body.
- the functional group to which the target substance can bind may be easily immobilized on the particle body.
- a silicon-containing substance is used, a “functional group to which the target substance can bind” is immobilized on the surface of the particle body, and a powerful silicon-containing substance exists.
- TMC T S 1, 3, 5, 7-tetramethylcyclotetrasiloxane
- the dispersion liquid obtained by dispersing the precursor particles in an organic solvent is added to the T , ⁇
- the organic solvent to be used may be any kind of organic solvent as long as it is easily evaporated by an evaporator and has a low boiling point, and examples thereof include toluene, hexane, and benzene. If the vacuum desiccator saddle is subjected to heat drying, the same effect as the chemical vapor deposition method (CVD method) is brought about.
- CVD method chemical vapor deposition method
- the heating temperature should be in a range where TMC TS evaporates and decomposition does not occur. Necessary. Specifically, a heating temperature of about 30 to 80 ° C is preferable.
- the last heating process in the thermostatic chamber is a process in which the reactions between TMC TS attached to the particle surface proceed. If the temperature becomes too high, TMC TS is likely to be decomposed, and if it is carried out for a long time, there will be no reactive sites required in the subsequent functional group immobilization step.
- a heating temperature of 200 ° C. and a reaction time within 2 hours are preferred. Since the particles become hydrophobic, it can be confirmed that a TMC TS film was formed on the particle surface.
- a functional group immobilization step is performed.
- a compound containing a functional group to be immobilized must have a double bond at the end, but there are no other restrictions.
- the structure used may have any structure between the functional group and the double bond site.
- the number of functional groups is not limited to one, and a plurality of functional groups may be used. A plurality of different types of functional groups may be immobilized.
- the Si—H part contained in TMC TS and the double bond part of the compound containing the functional group such as an epoxy group or a carboxyl group are included.
- the functional groups react with each other and are introduced to the particle surface.
- the particles obtained in the pretreatment step are dispersed in a solvent, and in a heated state, a reaction catalyst and a compound having a functional group to be immobilized are added and reacted for several hours.
- the solvent to be used is not limited as long as it can dissolve the compound having the functional group to be immobilized and can obtain a stable reaction rate even when heated to 60 ° C or higher. Any of 15 types of solvents may be used, such as water and ethylene glycol.
- any type of catalyst may be used as long as the reaction catalyst promotes the above-described reaction, and, for example, chloroplatinic acid or the like can be used.
- the polymer is attached to a part of the surface of the particle body, and the “substance or functional group capable of binding the target substance” is immobilized on the surface of the particle body or the polymer. Yes.
- the polymer covers the entire surface of the particle body, and a “substance or functional group capable of binding the target substance” is immobilized on the surface of the polymer.
- the particles of the present invention can also be referred to as “encapsulated particles” or “core-shell-structured particles” based on the morphology of the particles.
- the polymer attached to the surface of the particle body is preferably one that contributes to the immobilization of the “substance that can be bound by the target substance” or the “functional group that can be bound by the target substance”. It can be arbitrarily selected depending on the type of “substance” or “functional group to which the target substance can bind”, the use conditions of the particles, and other necessary characteristics.
- typical deposited polymers include polystyrene or its derivatives, poly (meth) acrylic acid, poly (meth) atanolate ester, polyvinyl ether, polyurethane, polyamide, poly (vinyl acetate), poly (bull alcohol), Mention may be made of at least one synthetic polymer selected from the group consisting of polyallylamine and polyethyleneimine.
- polymers such as semi-synthetic polymer compounds such as hydroxyalkynorecenolose, carboxyalkylcellulose or sodium alginate, or natural polymer compounds such as chitosan, chitin, starch, gelatin or gum arabic, etc. It doesn't matter. still,
- a polymer in which a functional group to which a “substance capable of binding a target substance” or “functional group to which a target substance can bind” can be bonded or attached may be introduced.
- polystyrene when particles are used in an aqueous system, polystyrene, polymetatalylate alkyl, polybulether or poly (polyether) is difficult to penetrate.
- a polymer such as butyl acetate may be selected.
- “deposition” substantially means an embodiment in which a polymer is attached or present on at least a part of the particle surface, and the polymer is not necessarily attached or present on the entire surface of the particle body. It does not have to be. However, in a preferred embodiment, the entire surface of the particle body is coated with a polymer so that the particle body is included in the polymer film. If the entire surface of the particle body is coated with a polymer, it is not only preferable in that the number of “substances or functional groups capable of binding a target substance” to be immobilized on the polymer surface is increased. It is preferable in that elution of metal ions (that is, metal ions constituting the particle main body) caused by the constituent material of the main body can be further suppressed.
- metal ions that is, metal ions constituting the particle main body
- the method for adhering the polymer to the particle body is not particularly limited, and any method may be used as long as the polymer can be attached to the particle body surface. For example, the following methods can be mentioned.
- the initiator particles and the chain transfer agent are bonded or adsorbed on the surface of the precursor particles, and the polymer is extended from the particle surface, thereby the precursor particles.
- a polymer is deposited on the surface of the substrate.
- the polymer is deposited on the surface of the precursor particles by performing polymerization in the presence of the precursor particles using a monomer that precipitates as the polymerization reaction proceeds. The deposition can be performed more efficiently by selecting each charge so that the polymer and the particle attract each other, or fixing a polymerizable double bond on the particle surface.
- a combination of a monomer and a solvent capable of forming a monomer emulsion is selected, and The polymer particles are deposited on the particle surface by polymerizing the precursor particles in the monomer emulsion obtained from 1 .
- a surface treatment or a surfactant that is familiar to the monomer so that the precursor particles are preferentially present in the monomer emulsion.
- the solubility of the polymer is decreased by mixing precursor particles in the polymer solution, adding a poor solvent, changing pH, and adding a large amount of salt. And depositing the polymer on the surface of the precursor particles.
- techniques such as charge selection and fixation of polymerizable double bonds are effective.
- the precursor particles may be alternately immersed in polymer solutions having different charges to form a laminate on the particle surface.
- the surface of the precursor particles Prior to the polymer deposition process, the surface of the precursor particles may be subjected to a specific process.
- a specific process for example, in addition to magnetizing treatment, coating treatment with metal or inorganic material, adsorption treatment of surfactant, treatment with reactive substances such as silane coupling agent or titanium coupling agent, siloxane coating treatment, and Si in siloxane — Functional group introduction treatment (hydrosilylation reaction), acid treatment or alkali treatment, solvent washing treatment or polishing treatment may be performed on H.
- These treatments remove dirt on the surface of the precursor particles, control the charge on the surface of the precursor particles, and introduce reactive functional groups on the particle surface, improving the efficiency of polymer deposition, The adhesion between the deposited polymer and the particle surface is improved by 1 ".
- the surface of the main body of the particle of the present invention is In addition to the substance or functional group to which the substance can bind "and the deposited polymer, such a silicon-containing substance must be present (for example, a silicon compound can be interposed between the particle body surface and the deposited polymer surface).
- a silicon-containing substance must be present (for example, a silicon compound can be interposed between the particle body surface and the deposited polymer surface).
- the polymerization is performed by previously bonding or adsorbing the initiator and / or polymerizable double bond to the surface of the precursor particle, the deposition of the surface of the adhered polymer is likely to occur, which may be advantageous for polymer deposition treatment. .
- treatments for imparting other characteristics such as reduction of non-specific binding, suppression of elution of metal ions, etc., adjustment of density, provision of color, fluorescence, etc. may be performed.
- the polymer to be deposited may be subjected to a crosslinking treatment.
- a crosslinking treatment When the deposited polymer is crosslinked, Properties such as durability, solvent resistance or low swellability can be improved.
- the method of crosslinking is not particularly limited, but the typical methods are classified as follows.
- (1) a and (2) a and (3) As an example of combining a, the polymerization may be started from the surface of the precursor particle, or the polymer may be deposited on the surface of the precursor particle. In the process of attaching the polymer, a heat treatment including a bifunctional monomer is performed, or a bifunctional monomer is included in the process of encapsulating the precursor particles in the monomer emulsion. A method of performing heat treatment is possible. As an example of combining (1) and (2) a and (3) a, the precursor particles are coated by precipitation of a polymer having a carboxyl group or polymerization of a monomer having a carboxyl group.
- (3) a can be used to introduce an epoxy group or isocyanate group, and a double bond can be introduced.
- (3) b can be used.
- a “substance that can bind to the target substance” or an “functional group that can bind to the target substance” is immobilized on the surface of the particles of the present invention and / or the surface of the adherent polymer. I understand that.
- the method of immobilizing the “functional group to which the target substance can bind” is not particularly limited in the embodiment in which the adherent polymer is provided on the surface of the particle body, and the “functional group to which the target substance can bind” is not limited. If it can be bonded or attached to the body, Any method may be used. Furthermore, the “functional group to which the target substance can bind” may be immobilized before, during or after the polymer deposition process.
- a technique for fixing the “functional group to which the target substance can bind” is, for example, “the target substance can be bound in the polymerization reaction of the polymer to be deposited”.
- a monomer having a “functional group” is polymerized or copolymerized.
- monomers having a “functional group to which the target substance can bind” include (meth) acrylic acid, (meth) glycidyl acrylate, (meth) hydroxyalkyl acrylate, and (meth) dimethyl acrylate.
- an adherent polymer is provided on the surface of the particle body, if it is desired to immobilize a “functional group with higher binding to the target substance”, it is reactive to the functional group a introduced into the adherend polymer by the above method
- a compound having two functional groups that is, a functional group having higher functional group c and “functional group c having higher binding property to the target substance” may be additionally introduced into the particles.
- the functional group a and the functional group b it is possible to obtain particles in which the “functional group c having higher binding property to the target substance” is immobilized.
- the compound having the functional group a may be additionally introduced into the particle having the functional group a introduced therein (also in this case, the functional group to which the target substance can bind is bonded via the binding between the functional group a and the functional group b. Is fixed to the particle). Such a compound may be introduced twice or more times to make the linker longer.
- the surface of the adherend polymer and the “functional group to which the target substance can bind” are further apart, or when the distance between the surface of the particle body and the “functional group to which the target substance can bind” is further separated, Increases the degree of freedom of the ⁇ functional group that can be bound to '' and improves the reactivity of the target substance. It is possible to expect an advantageous effect that the degree of freedom increases and the function of the target substance is not suppressed. If the number of atoms from the main chain of the polymer to the functional group is defined as the length of the linker, the length of the phosphorus force ⁇ "is 5 or more and 50 or less, and the above effects can be expected especially.
- the main chain it is particularly preferable to use a non-specific adsorptive substance such as a bio-related substance (for example, a polyethylene glycol chain).
- the method of immobilizing the “substance that can bind to the target substance” in the embodiment in which the adherent polymer is provided on the surface of the particle body is not particularly limited, and the “substance that can bind the target substance” is bound to the particle. Any method may be used as long as it can be adhered.
- the “substance to which the target substance can bind” may be immobilized either before, during or after the polymer deposition process.
- the “substance capable of binding to the target substance” can be immobilized on the particle by the same technique as that for introducing the “functional group to which the target substance can bind” described above.
- a functional group having a binding property with a “substance that can bind to a target substance” is introduced in advance on the surface of the particle main body or the surface of the adherend polymer, and the “substance that can bind to the target substance” is introduced through the functional group.
- hydrophobic polymer when a hydrophobic polymer is used as the adherent polymer and a hydrophobic substance is used as the “substance to which the target substance can bind”, a so-called “hydrophobic interaction” occurs in which the hydrophobic substances adsorb in water.
- a hydrophobic “substance that can bind to the target substance” can be immobilized on the surface of the deposited polymer.
- the target substance binds to the particle by the adsorption force or affinity acting between the “substance or functional group capable of binding the target substance” and the target substance. It will be.
- adsorption is synonymous with “chemisorption”.
- the “target substance” is avidin
- the particle body is formed of zirconia
- the target substance is bound to This is the case when the “substantially possible substance or functional group” is an epoxy group.
- the particle based on the type of affinity acting with the target substance, the particle
- the “substances or functional groups capable of binding the target substance” immobilized on the surface of the main body can be broadly classified into the following five categories (Note that the substances or functional groups listed in each classification are only examples. Note that other substances or functional groups are also conceivable).
- “substance or functional group capable of binding a target substance” is hereinafter referred to as “substance or functional group having affinity”.
- the affinity between the target substance and the target substance is derived from electrostatic interaction, ⁇ - ⁇ interaction, ⁇ -force thione interaction or dipole interaction.
- Silica activated carbon, sulfonic acid group, carboxyl group, jetylaminoethyl group, triethylaminoethyl group, fuel group, argene, cellulose, lysine, polylysine, polyamide, poly (N-isopropylacrylamide) ), Crown ether or cyclic compounds having ⁇ electrons, or functional group derivatives thereof, oxygen conjugates or fluorescent probe conjugates, etc.
- Alkyl group octadecyl group, octyl group, cyanopyl group or ptyl group or fluorene group, or their functional group derivatives, oxygen conjugate or fluorescent probe conjugate etc.
- Iminodiacetic acid nickel, nickel ion, nickel-canoide, cobalt, conolto ion, cobalt complex, copper, copper ion or copper complex, or oxygen bonds thereof Combined or fluorescent probe conjugate
- Affinity acting with the target substance is caused by biochemical interaction B “Example of substance or functional group I with affinity ( biochemical interaction: including interaction with biomolecules) Antigen 'antibody reaction, ligand' receptor binding, hydrogen bond, coordination bond, hydrophobic interaction, electrostatic interaction, ⁇ - ⁇ interaction, ⁇ -cation interaction, dipole interaction and fan (Derwals force, etc.)
- the term “having affinity” as used herein means that an electrostatic interaction, ⁇ ⁇ , occurs between a target substance and a substance or functional group immobilized on a particle. Substantially means that interaction, ⁇ -cation interaction, dipole interaction, hydrophobic interaction, biochemical interaction, hydrogen bond or coordination bond are brought about. It should be noted that depending on the type of substance or functional group immobilized on the particle body, two or more of the above-mentioned affinity may be combined, and there may be an overlapping substance or functional group in the above classification. I want.
- the classification is not necessarily limited to the above-described classification, and any substance or functional group may be used as long as it has a function of acting on a target substance and causing the target substance to exist on or near the particle surface. (For example, one having an affinity due to a complementary shape with the target substance is considered).
- the mode or method for immobilizing the “substance or functional group having an affinity for the target substance” on the surface of the precursor particle is not limited.
- ⁇ substances or functional groups having affinity for the target substance '' bind to and adhere to the surface of unfixed particles. It can be immobilized by action or absorption.
- the “substance or functional group having affinity for the target substance” can also be immobilized on the surface of the unfixed particles by using a general particle coating method.
- the separation method using the particles of the invention will be described in detail:
- the profitable separation method is a method for separating a target substance from a sample or obtaining particles with a fixed target substance using the particles of the present invention described above.
- the separation method of the present invention comprises:
- the sample containing the target substance and the particles of the present invention come into contact with each other, and the particles and the target substance are bound to each other (see FIG. 1 (a)).
- the sample and the particles are brought into contact with each other by supplying particles to the sample containing the target substance.
- a stirring process may be performed so that the bonding is promoted.
- the particles to be supplied can be supplied not as a single particle but as a powder in the form of a plurality of particles having an average size of 1 m to 1 mm as described above.
- the amount of particles in the powder form provided is determined in relation to the type of sample and separation application, etc., and is not comprehensively identifiable. can, analysis, until gram in research applications (1 0- 2 g ⁇ l 0 3 about g), and the industrial case of using the kilograms (1: L 0 3 about kg) from ton (1 Up to about 10 t).
- Samples that contain the target substance such as beakers, graduated cylinders, test tubes, microtubes, biochips, chemical chips, ⁇ -TAS chips, etc., are provided so that particles are naturally precipitated in step (ii). It is preferable to use it as it is.
- the binding between the target substance and the particle is caused by the adsorption force or affinity acting between them. More specifically, an adsorption force or friendly force acts between the “substance or functional group capable of binding the target substance” immobilized on the particle body and the target substance, thereby Particles bind to each other.
- an adsorption force or friendly force acts between the “substance or functional group capable of binding the target substance” immobilized on the particle body and the target substance, thereby Particles bind to each other.
- the particles used in the method of the present invention are particles that can suppress non-specific binding of substances other than the target substance to the particles. Therefore, even if the sample contains substances other than the target substance, the target substance can be preferentially bound to the particles.
- the target substance is, for example, a nucleic acid, a protein (for example, avidin opiop . (Including biotinylated HRP), sugar, lipid, peptide, cell, fungus, bacteria, yeast, virus, glycolipid, glycoprotein, complex, inorganic substance, vector, low molecular weight compound, high molecular weight compound, antibody or antigen, etc. It is.
- the sample may be, for example, human or animal urine, blood, serum, plasma, semen, B sap, sweat, tears, fl water, amniotic fluid, etc .; human or animal organs Suspension of hair, skin, nails, bone, muscle or nerve tissue, extract, lysate or disrupted solution; stool suspension, extract, lysate or disrupted solution; suspended cell or cultured tissue Suspension, extract, lysate or lysate; virus suspension, extract, lysate or lysate; cell suspension, extract, lysate or lysate; soil suspension, extraction Liquid suspension, extract solution, dissolution solution or destruction solution; food suspension / extraction solution, extraction solution, dissolution solution or destruction solution; drainage, etc.
- step (ii) the sample provided with the particles is allowed to stand, and the particles of the present invention are allowed to settle spontaneously in the sample (see Fig. 1 (b)). Since the particles used in the method of the present invention have density characteristics and specific surface area characteristics as described above, a relatively fast natural sedimentation rate can be obtained. In other words, not only the greater density of the particles used is, be regarded as a specific surface area of particles 0. 0 0 0 5 m 2 Z g ⁇ l. 0 m 2 g and a relatively small substantially non-porous Therefore, when a particle containing a target substance is subjected to a particle, it is suppressed that a gas such as air is taken into the particle (that is, the gas cannot exist inside the particle. (Effects such as buoyancy caused by gas can be eliminated). As a result, it is possible to obtain a sufficient separation rate by simply allowing the particles to settle naturally.
- step (iii) the target substance is separated from the sample or the target substance is immobilized by collecting the particles of the present invention precipitated in the sample (see Fig. 1 (c)).
- the particles precipitated in the sample can be recovered by sucking and removing the supernatant with a pipette or the like. Since the target substance is bound to the collected particles as described above, the target substance is separated from the sample by collecting the particles. In this way, in the method of this effort, the target substance in the sample can be separated, or particles with the target substance immobilized thereon can be obtained.
- a method for analyzing, extracting, purifying, or reacting the target substance becomes possible.
- the target substance is injected with the target substance in the form of particles loaded with “antibody capable of binding to target substance” fixed in the chip.
- the detection target substance is immobilized on the particles in the chip, and the amount of detection target substance is absorbed, chemiluminescent, or fluorescent using an antibody that binds to the detection target substance, such as an enzyme, fluorescent dye, or magnetic substance.
- the detection target substance can be quantitatively analyzed or qualitatively analyzed.
- the detection target substance is a nucleic acid
- the nucleic acid to be detected is immobilized on the particles in the chip, and the amount of the nucleic acid to be detected is detected by absorption, chemical emission, fluorescence, or magnetism.
- Qualitative analysis is possible. At this time, it may be carried out at the same place or at different places among a plurality of reaction vessels on the chip in each reaction stage.
- the target substance is injected into the chip particles by injecting the target substance into the chip in a form in which particles fixed with a substance capable of binding to the target substance are loaded in the chip.
- the target substance can be reacted by mixing, heating, stirring, and irradiating with UV light at various locations on the chip.
- gravity can be used for movement between a plurality of reaction vessels on the chip or for stirring in each reaction vessel. It is also possible to fix the enzyme or catalyst to the particles and use gravity to enter the reaction system.
- the attachment method is not particularly limited, and a general particle coating method may be used.
- a general particle coating method may be used.
- “substance or functional group capable of binding the target substance” is immobilized on the surface of the particle body, and such polyethylene glycol is present. .
- the present invention as described above includes the following aspects:
- First aspect a particle to which a target substance can bind
- Substance or functional group capable of binding the target substance is immobilized on the surface of the particle body
- the density of the particles is 3.5 g / cm 3 to 9. O g Z cm 3 ;
- Second aspect The particle according to the first aspect, wherein the particle has a specific surface area of 0.005 m 2 / g to 1.0 m 2 Z g.
- the polymer is deposited on a part of the surface of the particle body
- the polymer covers the entire surface of the particle body
- Substance or functional group capable of binding the target substance is fixed on the surface of the polymer. Particles characterized by no stabilization.
- the polymer is polystyrene, poly (meth) acrylic acid, poly (meth) acrylic ester, polyvinylinoate, polyurethane, polyamide, polyacetate butyl, polyvinyl alcohol Particles characterized by being at least one polymer selected from the group consisting of polyarylamine and polyethyleneimine.
- the particle main body is at least one selected from the group consisting of zirconia (zirconium oxide, yttrium-doped zirconium oxide), iron oxide, and alumina.
- the average particle size is 1 / im to: L mm.
- a substance capable of binding a target substance j 1 at least selected from the group consisting of biotin, avidin, streptavidin and neutravidin Particles characterized by being one or more substances.
- the “functional group capable of binding the target substance” force carboxyl group, hydroxyl group, epoxy group, tosyl group, succinimide group, maleimide group Thiol group, thioether group, disulfide group, aldehyde group, azide group, hydrazide group, primary amino group, secondary amino group, tertiary amino group, imide ester group, carposimide group, isocyanate group,
- a particle comprising at least one functional group selected from the group consisting of a doacetyl group, a halogen-substituted product of a carboxyl group, and a double bond.
- the silicon-containing substance and / or polyethylene glycol is present on at least a part of the surface of the particle body and / or the surface of the polymer. Particles.
- Fifteenth aspect In any one of the first to fourteenth aspects described above, by the adsorptive or friendly force acting between the "substance or functional group capable of binding the target substance" and the target substance, A particle characterized in that a target substance can bind to the particle.
- the affinity acting between the “substance or functional group capable of binding the target substance” and the target substance is an electrostatic interaction, ⁇ - ⁇ mutual Particles characterized by the action, ⁇ -cation interaction, dipole interaction, hydrophobic interaction, hydrogen bond, coordination bond or biochemical interaction.
- 18th aspect A method for analyzing, extracting, purifying, or reacting a target substance using the method of the 17th aspect.
- the particles of the present invention can be used for quantification, separation, purification and analysis of target substances such as cells, proteins, nucleic acids or chemical substances.
- the particles of the present invention can bind nucleic acids such as DNA, and as a result, can be used for DNA analysis, and thus contribute to tailor-made medical technology.
- the particles prepared in Example 1 are yttrium-doped zirconia particles Pi in which a hydroxyl group is immobilized.
- yttrium-added zircoyu particles made by Nitsukato Co., Ltd. were prepared.
- Such particles Pi had a particle size 50 ⁇ ⁇ , specific surface area 0. 02m 2 / g, a density of 6 gZcm 3.
- 1 g of particles p was dispersed in toluene, and 0.5 g of 1,3,5,7-tetramethylcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600) was obtained from the resulting dispersion.
- the particles were left in a vacuum desiccator for 4 hours at 50 ° C. After that, the particles p were heated for 1 ⁇ 5 hours in a thermostat at 150 ° C. By this treatment, it was confirmed that the particle p 1 was changed to spherical water and that the particle 1 was coated with 1, 3, 5, 7-tetramethylcyclotetracyclohexane.
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C. for 4 hours.
- the dispersion obtained by supplying 10 ml 1 of ethanolamine to the particles was stirred for 12 hours at room temperature.
- the particles were washed, filtered and dried to obtain yttrium-doped zircouore particles Pi having hydroxyl groups immobilized on the surface. Powerful particles were hydrophilic. The specific surface area of the particles was 0.02 m 2 / g, the density was 6 g / cm 3 , and the particle size was about 50 / xm (particles P
- the particles prepared in Example 2 are yttrium-doped zirconia particles P 2 having a hydroxyl group immobilized thereon.
- yttrium-added zirconia particles produced by Nitsukato Co., Ltd. 2 were prepared.
- the particle P 2 had a particle size of 50 / im and a specific surface area of 0.22 m 2 / gs density of 6 gZ C m 3 .
- 1 g of particles! 2 is dispersed in water, and a silane coupling agent (KBM-903, manufactured by Shin-Etsu Chemical Co., Ltd.) is added to the resulting dispersion to obtain a silane coupling agent on the surface of particle p 2 Was deposited.
- KBM-903 manufactured by Shin-Etsu Chemical Co., Ltd.
- the specific surface area of particle P 2 was 0.02 m 2 Zg, the density was 6 g / c 3 , and the particle size was about 50 // m (particle P 2 particle size and zirconia particle p 2 particle size The difference from the diameter is within the measurement error range).
- the measured saturation magnetization of the particle P 2 was 4.5 A ⁇ m 2 / kg.
- the particles prepared in Example 3 are yttrium-doped zirconia particles P 3 having a hydroxyl group immobilized thereon.
- the method for preparing the particles is different from that in Example 1.
- Jirukoyua particles p 3 made of Nitsukato Corporation.
- the particles p 3 had a particle size of 50 m, a specific surface area of 0.02 m 2 / g, and a density of 6 gZcm 3 . 10 g of particles! 3 was dispersed in 25 g of pure water, and 3 g of 3-daricidoxypropyltrimethoxysilane having an epoxy group at the end was added to the resulting dispersion and stirred for 4 hours.
- the dispersion obtained by supplying 10 ml 1 of ethanolamine to the particles was stirred for 12 hours at room temperature. And by subjecting the particles to washing 'filtration' drying, water on the surface 3.
- Yttrium-added zircouore particles ⁇ 3 with immobilized acid groups were obtained. Such particles ⁇
- the specific surface area of the particle [rho 3 is a 0. 02m 2 /, density 6 g / cm 3, a particle size of about 5 ⁇ (the particle diameter of the particle size and Jirukonia particle [rho 3 particle [rho 3 The difference is within the measurement error range).
- the particles prepared in Example 4 are yttrium-doped zirconia particles 4 in which a hydroxyl group is immobilized.
- Examples 1 and 3 differ in the method of particle preparation.
- yttrium-added karozircoua particles ⁇ 4 manufactured by Nitsukato Co., Ltd. were prepared.
- the particle ⁇ 4 had a particle size of 50 / zm, a specific surface area of 0.02 m 2 Zg, and a density of eg Zcm 3 .
- 10 g particles! > 4 was dispersed in 25 g of pure water, and 5 g of tetraoxysilane and 5 g of ammonia water were added to the resulting dispersion and stirred for 4 hours. Thereafter, 3 g of 3-glycidoxypropyltrimethoxysilane having an epoxy group at the end was added to the dispersion and stirred for 3 hours.
- the particles were washed with water, and then the dispersion obtained by supplying 1 Oml of 10 wt% ethanolamine to the particles was stirred for 12 hours at room temperature. Thereafter, the particles were washed, filtered and dried to obtain yttrium-added zircouore particles P 4 having hydroxyl groups immobilized on the surface.
- the particles P 4 were hydrophilic.
- the specific surface area of particle P 4 was 0.02 m 2 Zg, the density was 6 g / cm 3 , and the particle size was about 5 (the difference between the particle size of particle P 4 and the particle size of zircoia particle p 4) Is within the range of measurement error).
- the particles prepared in Example 5 are yttrium-doped zirconia particles P 5 with avidin immobilized thereon.
- Jirukoyua particles p 5 made of Nitsukato Corporation.
- the particle p 5 had a particle size of 50 / xm and a specific surface area of 0.02 m 2 / gs density S gZcm 3 .
- 10 g of the particle p 5 were dispersed in pure water 25 g, while stirring the resulting dispersion, further addition of 3-glycidoxypropyl trimethoxysilane down 3 g having an epoxy group to the dispersion at the end Stir for 4 hours.
- the particles were washed with acetone, and then subjected to vacuum drying to obtain yttrium-doped zirconia particles having an epoxy group.
- an aqueous solution in which 10 Omg of avidin was dissolved in 10 mM PBS solution (pH 7.2) 2 Oml was provided to 20 Omg of the obtained particles and stirred for one hour. Thereafter, the particles were washed with 1 OmMPBS solution (pH 7.2) and water, and then subjected to vacuum drying to obtain yttrium-added dinoleconia particles P 5 with avidin immobilized thereon.
- the obtained particle P 5 had a specific surface area of 0.02 m 2 g, a density of 6 g / cm 3 , and a particle size of about 50 jam (the particle size of particle P 5 and the zirconia particles p 5 The difference from the particle size is within the measurement error range).
- Particles prepared in Example 6 are alumina particles P 6 which avidin is immobilized.
- the raw material particles and the preparation method are different from those in Example 5.
- alumina particles P 6 made of Taimei Chemicals were prepared. Powerful particles p 6 had a particle size of 200 ⁇ , a specific surface area of 0.008 m 2 Zg, and a density of 3.6 g / cm 3 . Disperse 1 g of particles p 6 in toluene, and add 0.5 g of 1,3,5,7-tetramethylcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600) to the resulting dispersion. It was. After the dispersion was evaporated to evaporate toluene, the particles were left in a vacuum desiccator at 50 ° C for 4 hours. Was then heated particles p 6 1.
- the resulting particles were dispersed in water and heated to 80 ° C. 1 Omg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C for 4 hours. Next, the particles were washed with water, and then a dispersion obtained by supplying 1 Oml of 10 wt% ethanolamine to the particles was stirred at room temperature for 12 hours. Next, the particles were subjected to washing, filtration and drying to obtain alumina particles having glacial groups immobilized on the surface. Such particles were hydrophilic.
- Alumina particles P 6 with avidin immobilized thereon were obtained by subjecting the particles to vacuum drying.
- the obtained particle P 6 had a specific surface area of 0.008 m 2 nog, a density of 3.6 g / cm 3 , and a particle size of about 200 ⁇ (particle size of particle ⁇ 6 and zirconium oxide particle ⁇ The difference from the particle size of 6 is within the measurement error range).
- the particles prepared in Example 7 are copper particles 7 on which avidin is immobilized.
- the raw material particles are different from Example 6.
- Hitachi Metals copper particles! 7 were prepared. 7 had a particle size of 50 !! 1, a specific surface area of 0.013 m 2 Zg, and a density of 8.9 g / cm 3 . 1 ⁇ particles 7 were dispersed in toluene, and 0.5 g of 1, 3, 5, 7-tetramethylcyclotetratrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600) was added to the resulting dispersion. . After evaporation of the dispersion and evaporation of the toluene, the particles were left in a vacuum desiccator for 4 hours at 50 ° C. Was then heated particles p 7 1.
- the particles were subjected to washing, filtration, and drying to obtain copper particles having hydroxyl groups immobilized on the surface.
- the profitable particles were hydrated individuals.
- an aqueous solution in which 10 Omg of avidin was dissolved in 20 ml of 10 mMPB S solution (pH 7.2) was added to 20 Omg of the obtained particles, and the mixture was stirred overnight.
- 1 OmMPB S solution (pH 7. 2) was added to 20 Omg of the obtained particles, and after the particles were washed with water, by subjecting the particles to vacuum drying to obtain copper particles P 7 which Abijin is immobilized.
- the specific surface area of the obtained particle P 7 was 0.013 m 2 Zg, the density was 8.9 g / cm 3 , and the particle size was about 50 ⁇ (the particle size of the particle P 7 and the zirconia particle p 7 The difference from the particle size is within the measurement error range). (Example 8)
- Example 8 The particles prepared in Example 8 are yttrium-added zircoure particles P 8 on which avidin is immobilized.
- the raw material particles are different from those in Example 6 and Example IV.
- Example 8 is the same as Example 5 in that the raw material particles are made of yttrium-added zirconia, but Example 8 uses yttrium-added ginoleconia having physical properties different from those of Example 5.
- Such particles 1> 8 had a particle size of 30 ⁇ , a specific surface area of 0.03 mVgs density, e gZcm 3 .
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid and 0.5 g of light ester made by Kyoeisha Chemical Co. were added to the resulting dispersion and stirred at 80 ° C. for 4 hours. Next, the particles were washed with water, and then a dispersion obtained by supplying 1 Owt% ethanolamine 1 Oml to the particles was stirred at room temperature for 12 hours. Next, the particles were subjected to washing, filtration and drying to obtain yttrium-doped zirconia particles having hydroxyl groups immobilized on the surface. Such particles were hydrophilic.
- the obtained particle p 8 had a specific surface area of 0.03 m 2 Zg, a density of 6 g / cm 3 , and a particle size of about 3 O / xm (the particle size of particle P 8 and the zirconia particles p The difference from the particle size of 3 is within the measurement error range). (Example 9)
- the particles prepared in Example 9 are yttrium-doped zircouore particles P 9 in which avidin is immobilized.
- Example 9 uses yttrium-added ginoleconia having physical properties different from those of Examples 5 and 8.
- yttrium-added zirconia particles 9 manufactured by Nellen Co., Ltd. were prepared. Such particles; 9 had a particle size of 15; um, a specific surface area of 0.04 m 2 / g, and a density of 6 ⁇ ⁇ ⁇ 3 .
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid and 0.5 g of light ester made by Kyoeisha Chemical Co. were added to the resulting dispersion and stirred at 80 ° C. for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 1 Oml% ethanolamine to the particles was stirred for 12 hours at room temperature. Next, the particles were subjected to washing, filtration, and drying to obtain yttrium-doped zirconia particles P9 having hydroxyl groups immobilized on the surface. Powerful particles were hydrophilic.
- the specific surface area of the obtained particle P 9 was 0.04 m 2 / g, the density was 6 g / cm 3 , and the particle size was about 15 / m (the particle size of the particle P 9 and the zirconium particles the difference between the particle size of the p 9 within the measurement 3 ⁇ 4m difference range).
- Example 10 The particles prepared in Example 10 are polystyrene-coated zirconium particles having an epoxy group immobilized thereon. It is. Such particles are characterized in that a polymer is deposited on at least a part of the particle body.
- the zirconium oxide particles p 10 had a particle size of 30 / zm, a specific surface area of 0.03 m 2 / g, and a density of eg / cm 3 . 3 g of Zircoyu particles p 1.
- the zirconium oxide particles p 10 had a particle size of 30 / zm, a specific surface area of 0.03 m 2 / g, and a density of eg / cm 3 .
- 3 g of Zircoyu particles p 1. was dispersed in a water / alcohol mixed solution, 0.13 g of methacrylic xylopyrtrimethoxysilane was added, and the mixture was stirred at 35 ° C. for about 30 minutes. Then, nitrogen was bubbled for 30 minutes, p-sodium styrenesulfonate 0.
- the particles prepared in Example 11 are polystyrene-coated zirconia particles 1 on which avidin is immobilized. It differs from the particle 0 of Example 10 in that avidin is immobilized instead of the epoxy group.
- the obtained particle 1 had a specific surface area of 0.05 m 2 Zg, a density of 5.5 g / cm 3 , and a particle size of about 30 / im (the particle size of the particle x and the zirconia particle p The difference from the particle size of 0 is within the measurement error range).
- the ratio table of the obtained particles P The area is larger than the specific surface area of the raw material particles P 10 , and this is thought to be one of the causes, as in Example 10, because some of the polymers were deposited in a linear manner.
- the particles prepared in Example 12 are crosslinked polystyrene-coated zircoure particles 2 in which an epoxy group is immobilized.
- the difference between the particles of Example 10 is that the polystyrene of the deposited polymer ⁇ ⁇ is crosslinked.
- the particles prepared in Example 13 are polystyrene-coated magnetic zirconia particles 3 having an epoxy group immobilized thereon. Particles of Example 10 in that the particles Pi 3 have magnetism. Is different.
- yttrium-doped zirconia particles pi 3 manufactured by Nitsukato Co., Ltd. were prepared.
- the particles p 13 had a particle size of 30 ⁇ , a specific surface area of 0.03 m 2 / g, and a density of 6 g / cm 3 .
- 1 g of particles p 3 was dispersed in water, the silane cutlet pulling agent to the resultant dispersion (available from Shin-Etsu Chemical Co., KBM-903) depending on the addition of the surface to a silane coupling agent particles p 13 was deposited.
- particles added by Shipley Farist p d catalyst C ata 1 yst-6 F! Mecky nuclei were generated on the surface of i 3 .
- Example 10 After washing the resulting particles with 1.2 N hydrochloric acid, a nickel plating layer is formed on the surface of the particles using Okuni Pharmaceutical's nickel plating liquid top Nicolon LPH, and the particles are washed and filtered. It was attached to. Thereafter, the same treatment as in Example 10 was performed to obtain “polystyrene-coated magnetic zircore particles Pl 3 having epoxy groups immobilized thereon.
- the specific surface area of the obtained particles 3 was 0. .05m 2 Zg had a density of 6.5 g / cm 3 and a particle size of 32 ⁇ .
- the saturation magnetization of this particle Pi a was measured and found to be 6.5 A ⁇ m 2 / kg.
- the force that the specific surface area of the obtained particle Pi 3 is larger than the specific surface area of the raw material particle Pi 0 is one of the causes because part of the polymer was deposited in the same manner as in Example 10. Is considered.
- the particles prepared in Example 14 are yttrium-added zircore particles Pi 4 on which “anti-human CRP monoclonal antibody 6404” is immobilized.
- yttrium-doped zirconia particles 4 manufactured by Nitsukato Co., Ltd. were prepared.
- the powerful particles P l 4 had a particle size of 50, a specific surface area of 0.02 m 2 / g, and a density of 6 gZcm 3 .
- the obtained particles were dispersed in water and heated to 80 ° C. 1 Omg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 1 Oml of 10 wt% ethanolamine to the particles was stirred at room temperature for 12 hours. Next, the particles were subjected to washing / filtration / drying to obtain yttrium-doped zirconia particles 4 , having hydroxyl groups immobilized on the surface. Such particles 4 were hydrophilic.
- Tosicle mouthride was added to the particles 4 'and stirred. The obtained particles were washed to obtain tosyl group active zirconia particles.
- Anti-human CRP monoclonal antibody 6404 (manufactured by Medix Biotech) was immobilized on the tosyl group-activated zirconia particles.
- the specific surface area of the particles 4 obtained by the above operation was 0.02 m 2 / g, the density was 6 g / cm 3, and the particle size was 50 m.
- the particles prepared in Example 15 are yttrium-doped zirconia particles Pi 5 in which a hydroxyl group is immobilized.
- the method for preparing the particles is different from that in Example 1.
- yttrium-added zircoyu particles 5 manufactured by Nitsukato Co., Ltd. were prepared.
- the particle p 15 has a particle size The density was 6 g / cm 3 .
- 1 g of particles 5 were dispersed in water, and a solution obtained by mixing KBE-402 (manufactured by Shin-Etsu Chemical Co., Ltd.) with ethanol was added dropwise to the resulting dispersion. Aqueous ammonia was added thereto, and the mixture was stirred at room temperature for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 10 wt% ethanolamine 1 Om 1 to the particles was stirred at room temperature for 12 hours.
- Such particles P! 5 was hydrophilic.
- the specific surface area of particle P 5 was 0.02 in 2 Zg, the density was 6 gZcm 3 , and the particle size was about 5 O / xm (the particle size of particle P 5 and the particle size of zircoyu particles p x 5 The difference is within the measurement error range).
- the particles prepared in Example 16 are yttrium-doped zirconia particles Pi 6 in which avidin is immobilized on the particles of Example 1.
- the above-mentioned examples include an example using a silane coupling agent having an epoxy group, but the silane coupling agent has a mercapto group, a functional group having a double bond, and the like. Note that you can use things. ,
- the particles prepared in Comparative Example 1 are crosslinked acrylic particles having a hydroxyl group immobilized thereon.
- cross-linked acrylic particles made by Soken Chemical Co., Ltd. were prepared. Powerful particles have a particle size of 30 ⁇ and a specific surface area of 0.03 The density was 1.19 g / cm 3 . 1 g of particles r is dispersed in toluene, and the resulting dispersion is
- 1, 3, 5, 7-tetramethylcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-860 0) was added in 1 g. After the dispersion was evaporated to evaporate toluene, the particles were left in a vacuum desiccator for 4 hours at 50 ° C. The particles were then heated for 1.5 hours in a constant temperature bath at 150 ° C. By virtue of the intensive process, the particles r changed to hydrophobic, and we confirmed that the particles were coated with 1, 3, 5, 7-tetramethylcyclotetrasiloxane.
- the resulting particles were dispersed in water and heated to 80 ° C.
- the obtained dispersion Thus, the addition of Kyoeisha Chemical Co. Lai Toesuteru of 20111 ⁇ of chloroplatinic acid Oyopi 1 g, and stirred for 4 hours at 80 ° C.
- the particles were washed with water, and then the dispersion obtained by supplying 20 ml 1 of 10 wt% ethanolamine to the particles was stirred for 12 hours at room temperature. Thereafter, the particles were subjected to washing, filtration, and drying to obtain crosslinked acrylic particles 1 ⁇ having hydroxyl groups immobilized on the surface.
- Such particles R 1 were hydrophilic.
- Particle R 1 has a specific surface area of 0.033 m 2 zog, a density of 1.19 gZcm 3 , and a particle size of about 3 O ⁇ um (particle size of 1 ⁇ and zirconia particles r! The difference from the particle size is the measurement error range ⁇ ).
- the particles prepared in Comparative Example 2 are porous zeolite particles R 2 in which avidin is immobilized.
- zeolite particles (HSZ-700) r 2 manufactured by Tosoh Corporation were prepared.
- the particle r 2 had a particle size of 18 m, a specific surface area of 170 m 2 Zg, and a density of 2.3 g / cm 3 .
- 1 g of the particles r 2 were dispersed in toluene, and to the resulting dispersion I, 3, 5, 7 - tetramethylcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., LS- 86 00) was added 2 g.
- the obtained particles were dispersed in water and heated to 80 ° C. 2 Omg of chloroplatinic acid and 2 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C for 4 hours. Then, the particles were washed with water, and then the dispersion obtained by supplying 1 Owt% ethanolamine 2 Om 1 to the particles was stirred at room temperature for 12 hours. Thereafter, the particles were washed, filtered and dried to obtain porous zeolite particles r 2 having hydroxyl groups immobilized on the surface. Such particles r 2 was hydrophilic.
- the particles prepared in Comparative Example 3 are silica particles R 3 with avidin immobilized thereon.
- the raw material particles are different from those of Comparative Example 2.
- silica particles r 3 made of two Tsu Pung techno cluster.
- the particles r 3 had a particle size of 3.0 ⁇ 111, a specific surface area of 1.2 m 2 Zg, and a density of 1.96 gZcm 3 .
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C. for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 10 ml of 10 wt% ethanolamine to the particles was stirred at room temperature for 12 hours. Then, by subjecting the particles to wash 'filtration' drying, hydroxyl group to obtain a silica particle silica particles r 3 which is immobilized on the surface. Such particles r 3 was found to be hydrophilic.
- an aqueous solution in which 10 Omg of avidin was dissolved in 20 ml of 10 mMPB S solution (pH 7.2) was added to 20 Omg of the obtained particles, and stirred for a while. Thereafter, the particles were washed with 1 OmMPBS solution (pH 7.2) and water, and then subjected to vacuum drying to obtain Siri-force particles R 3 with avidin immobilized thereon.
- the resulting particle R 3 had a specific surface area of 1.2 m 2 Zg, a density of 1.96 g / cm 3 and a particle size of about 3.0 // m (the particle R 3 the difference between the particle size of the zirconyl two ⁇ particles r 3 is in the range of measurement error).
- the particles prepared in Comparative Example 4 are tandasten particles R 4 in which avidin is immobilized.
- the raw material particles are different from those of Comparative Examples 2 and 3.
- tungsten particles r 4 made of Hitachi Metals. Powerful particles r 4 particles-diameter 100 , Density 1 9. 1 ⁇ 70111 3 g 1 g particles! ⁇ 4 was dispersed in toluene, and 0.5 g of 1,3,5,7-tetramethylcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600) was added to the resulting dispersion. After the dispersion was evaporated to evaporate toluene, the particles were left in a vacuum desiccator at 50 ° C for 4 hours. Thereafter, the particles were heated in a thermostat at 150 ° C for 1.5 hours. By such processing, the particles r 4 is changed to hydrophobic, particles r 4 is 1, 3, 5, 7 - to confirm that coated with tetramethylcyclotetrasiloxane.
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid opiate 0.5 g of Kyoeisha Chemical Co., Ltd. Light ester was added and stirred at 80 ° C for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 1 Ow ° / o ethanolamine 1 Oml to the particles was stirred at room temperature for 12 hours. Then, by subjecting the particles to washing. Filtered 'drying, hydroxyl groups on the surface to obtain a tungsten particles r 4 immobilized. Forces hunt particles r 4 was found to be hydrophilic.
- the obtained particle R 4 had a specific surface area of 0.003 m 2 Zg, a density of 19.1 g / cm 3 , and a particle size of about 100 jum (the particle R 4 particle size and zirconia particles the difference between the particle size of the r 4 is the measurement 3 ⁇ 4m difference range).
- Particles prepared in Comparative Example 5 is a zirconate Your particles R 5 with avidin with immobilized porous structure.
- the raw material particles are different from those of Comparative Examples 2 to 4.
- ZirChrom porous zirconia particles (ZirChrom-PHASE) r 5 were prepared.
- the particle r 5 had a particle size of 25 / zm, a specific surface area of 30 m 2 Zg, and a density of 6 gZ cm 3 . Disperse 1 g of particles r 5 in toluene and
- the obtained particles were dispersed in water and heated to 80 ° C. 10 mg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C. for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by applying 10 ml of 1 Owt% ethanolamine to the particles was stirred for 12 hours at room temperature. Next, wash the particles.
- the particles prepared in Comparative Example 6 are porous Siri force particles R 6 in which avidin is immobilized.
- the raw material particles are different from those of Comparative Examples 2 to 5.
- porous silica particles (SanSweair L-121) r 6 manufactured by Asahi Glass S-Itech were prepared.
- the particle r 6 had a particle size of 11.5 m, a specific surface area of 336 m 2 / g, and a density of 2. O gZcm 3 .
- 1 g of particles r 6 are dispersed in toluene, and 1, 3, 5, 7-tetramethylolcyclotetrasiloxane (manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600) is added to the resulting dispersion.
- 1, 3, 5, 7-tetramethylolcyclotetrasiloxane manufactured by Shin-Etsu Chemical Co., Ltd., LS-8600
- the particles were left in a vacuum desiccator for 4 hours at 50 ° C. Thereafter, the particles were heated in a thermostat at 150 ° C for 1.5 hours. It was confirmed that the particle r 6 changed to hydrophobicity by the intensive treatment, and the particle r 6 was coated with 1, 3, 5, 7-tetramethylcyclotetracyclohexane.
- the obtained particles were dispersed in water and heated to 80 ° C. 1 Omg of chloroplatinic acid and 0.5 g of Kyoeisha Chemical Light Ester were added to the resulting dispersion and stirred at 80 ° C for 4 hours. Next, the particles were washed with water, and then the dispersion obtained by supplying 1 Owt% ethanolamine 1 Om 1 to the particles was stirred at room temperature for 12 hours. Then, by subjecting the particles to washed, filtered and dried to obtain a porous silica particles r 6 avidin on the surface is fixed. Such particles r 6 was hydrophilic.
- Particles prepared in Comparative Example 7 is a cross-linked acrylic particles R 7 in which the epoxy group is immobilized. This is different from Comparative Example 1 in terms of the functional group to be immobilized.
- a cross-linked acrylic particles r 7 manufactured by Soken Chemical & Engineering Co., Ltd..
- the powerful particles r 7 had a particle size of 30 zm, a specific surface area of 0.03111 2 8 and a density of 1. lO gZcm 3 . 10 g of the particle r 7 were dispersed in pure water 25 g of relative resulting dispersion, were added and stirred 3 Dali Sid trimethoxysilane 3 g having an epoxy group at the terminal 4 hours. Then, by subjecting the particles to wash 'filtration' drying, epoxy group was obtained immobilized crosslinked acrylic particles R 7 on the front surface.
- the resulting specific surface area of the particles R 7 a 0 ⁇ 03 m 2 / g, density of 1. 19 / cm 3, the particle size of a particle size of about 3 0 mu m (particles R 7 and Atariru the difference between the particle size of the particles r 7 measurement error within range).
- the force Cal particles R 7 was hydrophilic.
- the particles prepared in Comparative Example 8 were porous zeolite particles R with avidin immobilized.
- zeolite particles (HSZ-700) r 8 manufactured by Tosoh Corporation were prepared.
- the particle r 8 had a particle size of 18 / xm, a specific surface area of 17 Om 2 / g, and a density of 2.3 g / cm 3 .
- the 10 g of the particle r 8 were dispersed in pure water 25 g, and against the dispersion obtained was stirred with addition of 3-Dali Sid alkoxy prop Honoré trimethoxysilane 3 g having an epoxy group at the terminal 4 hours . Then, depending on subjecting the particles to washed, filtered and dried, epoxy groups on the surface to obtain a porous Zeoraito particles r 8 immobilized.
- the Power Chikararu particles r 8 was hydrophilic. Subsequently, 10 Omg of avidin was dissolved into 20 ml of 1 OmMPB S solution (pH 7.2) to 20 Omg of the obtained particles. ⁇ Added aqueous solution and stirred for 1 B. After washing the particles with 10 mM PBS solution (p H 7. 2) and water, by subjecting the particles to vacuum drying to obtain Jirukoyua particles R 8 where completion avidin is immobilized.
- the obtained particle R 8 had a specific surface area of 170 m 2 / g, a density of 2.3 gZcm 3 , and a particle size of about 18 ⁇ (the particle size of the particle R 8 and that of the Atalinole particle r 8 The difference from the diameter is within the measurement error range).
- This particle R 9 is prepared by adding anti-human CRP monoclonal antibody 6404 (Medix Biotech) to Dyn abeads M-280 To sylactivated particle (Dynal), stirring, washing with magnetic separation, and anti-human CRP monoclonal.
- Antibody 6404 manufactured by Medix Biotech
- the anti-human CRP monoclonal antibody 6404 was immobilized on the particle surface based on the color developed by the HRP-Rabbit-Anti 1 Mo use IgG2a secondary antibody.
- the obtained particle R 9 had a specific surface area of 6 m 2 Zg, a density of 1.3 g / cm 3 , and a particle size of 2.8 ⁇ .
- the natural sedimentation rate of the particles of the high density example is generally ⁇ 1
- the separation speed of the particles of the present invention is faster than the separation speed of the particles of the comparative example, and the target substance can be separated from the sample faster by using the particles of the present invention.
- the particle separation speed can be increased for magnetic particles by performing magnetic separation operation in addition to natural sedimentation.
- Confirmation test of surface condition of raw material particles >>
- Example 1 The surface state of the raw material particles used in Example 1 and Comparative Example 6 was observed using a Hitachi scanning electron microscope (SEM, model S-4500). The results are shown in Figs. A electron microscopic photograph of Ittoriumu added Jirukonia particles pi used in FIG 2 and Figure 3 Example 1, Ru micrographs der porous silica particles r 6 Figure 4 and 5 were used in Comparative Example 6 . As is clear from FIGS. 2 to 5, the particles of Example 1 are non-porous particles, and the particle surface is smooth with no irregularities, whereas the particles of Comparative Example 6 are porous particles. As a result, the surface irregularities are greatly bumpy.
- the specific surface area is significantly different, that is, the specific surface area of the particles of the present invention is smaller. 2 and 3, it can be understood that the particle of the present invention “the particle body does not have a through hole”. ⁇ Specificity of particles ⁇ Confirmation test for non-specific binding properties>
- Example 5 and Example 11 Particles P 5 and Particles P ii, P 6 obtained in 1 and Particles R 2 , Particles R 4 , Particles R obtained in Comparative Examples 2, 4, 5, 6 and 8 5, using a particle R 6 and particles R 8, confirming the specificity 'non-specific binding properties of the particles (P 5, P lls P 16 , R 2, R 4 s R 5, R 6, a).
- the target substance two kinds of substances, HRP and piotinylated HRP, were used (both enzyme activities are substantially equivalent).
- Avidin immobilized on the particle specifically binds to biotinylated HRP, but not specifically to HRP.
- piotinylated HRP binds specifically (preferentially) to the particles, while HRP can be adsorbed on the pore region of the particles and binds nonspecifically to the particles.
- the particle 5 charged in each tube was washed with 400 ⁇ l of 1 OmMP BS buffer (pH 7.2) and centrifuged. This washing and centrifugation was performed 4 times. After removing PBS buffer ( ⁇ 7. 2), by standing by adding 200 mu 1 of ⁇ the respective tubing that contains particles [rho 5 (tetramethylbenzidine) 30 minutes, the particle [rho 5 The color was developed. Then, 200 ⁇ 1 of 1N sulfuric acid was added to stop the reaction. Then, the absorbance (450 nm) was measured with a TE CAN plate reader Infinite 200 to determine the color development amount of the particles P 5 charged in each tube.
- the particles of the present invention can obtain a sufficient separation speed only by the moving speed by natural sedimentation. At the same time, it was found that non-specific binding of substances other than the target substance can be suppressed. Further, from the “confirmation test of the surface state of the raw material particles”, it was confirmed that the particles of the present invention are non-porous particles and that the “particle body does not have through holes” — ''
Abstract
Description
Claims
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US12/281,596 US20090029482A1 (en) | 2006-04-28 | 2007-04-27 | Functional particle, and method for separation of target substance using the same |
JP2008513338A JPWO2007126151A1 (ja) | 2006-04-28 | 2007-04-27 | 機能性粒子およびそれを用いた標的物質の分離方法 |
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WO2020218317A1 (ja) * | 2019-04-26 | 2020-10-29 | キヤノン株式会社 | 粒子、アフィニティー粒子、検査試薬、及び検出方法 |
WO2023112953A1 (ja) * | 2021-12-14 | 2023-06-22 | 関東電化工業株式会社 | ZrO2分散液 |
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US20120061608A1 (en) * | 2010-09-10 | 2012-03-15 | Hitachi Maxell, Ltd. | Functional particle with rough-surfaced polymer coating |
TWI573863B (zh) * | 2010-12-28 | 2017-03-11 | 聖高拜陶器塑膠公司 | 包括氧化鋯顆粒的拋光漿料以及使用這種拋光漿料之方法 |
US20200056132A1 (en) * | 2018-08-18 | 2020-02-20 | James E. Spooner | Solid non-reactive particle inclusions to accelerate aging in wine or spirits |
CN114045284B (zh) * | 2021-11-11 | 2023-12-15 | 中国农业科学院农业质量标准与检测技术研究所 | 一种提取生物组织样品中核酸的方法 |
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