WO2020228559A1 - Radioactive particle, preparation method therefor, and use thereof - Google Patents

Abstract

Provided is a radioactive particle, comprising a porous silicon dioxide particle and at least one type of radionuclide precipitate accommodated in the pores of the porous silicon dioxide particle. Said porous silicon dioxide particle is hydrophilic, and said radionuclide precipitate is formed by reacting positive ions with negative ions, said positive ions and/or negative ions containing radionuclides. The radioactive particle has a stable structure, is easy and practical, and can carry radionuclide precipitates containing different radionuclides. In addition, the release rate of the radionuclides is low, and the present invention has a wide application prospect. Also provided are a preparation method for the radioactive particle, and uses of the radioactive particles or the radioactive particles prepared using the preparation method therefor in medications for treating tumors.

Description

Radioactive particles and their preparation method and application

This application claims the priority of the Chinese patent application filed with the Chinese Patent Office on May 13, 2019, with the application number 201910393721.6 and the invention title of "Radioactive Particles and Their Preparation Methods and Applications", the entire content of which is incorporated into this application by reference in.

Technical field

The invention belongs to the technical field of radiopharmaceutical preparation, and particularly relates to a radioactive particle and a preparation method and application thereof.

Background technique

Malignant tumors have the characteristics of high morbidity and mortality, and are one of the major diseases that seriously threaten people's lives. Tumor radiotherapy (radiotherapy) is a local treatment method that uses radiation to treat tumors. Its role and position in tumor treatment are increasingly prominent; but radiotherapy generally belongs to "full-line killing", which kills tumors and normal tissues at the same time . Tumor radiotherapy includes external radiation and internal radiation; for some tumors that are far away from the skin tissue and grow in the body, through internal radiation, the radiation directly reaches the tumor tissue, and the normal tissues around the tumor receive a small amount of radiation, which can be obtained Better treatment effect. For example, the recently developed Selective Internal Radiation Therapy (SIRT) technology involves injecting radioisotope-containing drugs into the body or placing devices close to or inserted into target tissues for radiotherapy. Radioactive materials are selectively The radiation dose delivered to the tumor tissue is very large, while the amount of radioactive substances in the surrounding normal tissues is small, and the damage to the normal tissues is small.

However, most of the existing drugs containing radioisotopes are based on glass or resin as a matrix loaded with radionuclides such as yttrium (Y)-90, phosphorus (P)-32 and other radioactive microspheres, these radioactive glass microspheres or resin microspheres There are some shortcomings in the ball. For example, the density of glass in radioactive glass microspheres is relatively high (2.0cm/g-2.7cm/g), and glycerol needs to be introduced to the tumor site, which will affect the therapeutic effect; at the same time, radioactive glass microspheres must be irradiated with a reactor. However, after neutron irradiation, the impurities in the glass raw materials will produce nuclides that release gamma rays, which will cause unnecessary radiation damage to the patient; and the preparation process of radioactive glass microspheres is complicated and the reaction conditions are harsh. As for the radioactive resin microspheres, most of the radionuclides loaded on the surface of the radioactive resin microspheres have a small force between the resin microspheres and easily fall off the surface of the resin microspheres and enter the human blood, causing harm to the human body. However, exchanging radionuclides into the resin and fixing them in the resin by coating methods can easily cause the radionuclide release rate to be high and cannot meet the requirements of treatment. In addition, radioactive resin microspheres also have the problem of limited resin exchange capacity and long preparation process.

Therefore, the development of a radioactive particle with a safe and stable structure, convenient and practical, and simple and efficient preparation process is of great significance for tumor radiotherapy.

Summary of the invention

In order to solve the above problems, the present invention provides a radioactive particle and its preparation method and application. The radioactive particle has a stable structure, is convenient and practical, can carry radionuclide precipitation including various radionuclides, and the release rate of the radionuclide Low, has broad application prospects.

In the first aspect, the present invention provides a radioactive particle comprising porous silica particles and at least one radionuclide precipitate contained in the porous pores of the porous silica particles; the porous silica particles With hydrophilicity, the radionuclide precipitate is generated by the reaction of cations and anions, and the cations and/or the anions contain radionuclides.

The radionuclide in the present invention refers to an unstable atomic nucleus, which can spontaneously emit radiation (such as alpha rays, beta rays, etc.), and form stable nuclides through decay. The radionuclide may be a metal radionuclide and/or a non-metal radionuclide. The radionuclide may be a man-made radionuclide or a natural radionuclide.

In the present invention, the shape of the porous silica particles includes one or more of spherical and non-spherical. Further, the shape of the porous silica particles includes one or more of spherical, quasi-spherical, square, rod-like, flake-like and irregular shapes.

In the present invention, the cation and/or the anion include a radionuclide, including the following three embodiments:

In the first embodiment of the present invention, the radionuclide precipitate is generated by the reaction of a cation and an anion, the cation contains a radionuclide, and the anion does not contain a radionuclide.

In the second embodiment of the present invention, the radionuclide precipitate is generated by the reaction of a cation and an anion, the anion contains a radionuclide, and the cation does not contain a radionuclide.

In the third embodiment of the present invention, the radionuclide precipitate is generated by the reaction of cations and anions, and both the cations and anions contain radionuclides.

Optionally, the cation contains at least one of metal radionuclides.

Further, optionally, the radionuclide contained in the cation may include, but is not limited to, at least one of strontium (Sr-90), yttrium-90 (Y-90) and nickel-63 (Ni-63). Kind. For example, the cation is at least one of strontium-90 ion ( ⁹⁰ Sr ²⁺ ), yttrium-90 ion ( ⁹⁰ Y ³⁺ ), and nickel-63 ion ( ⁶³ Ni ²⁺ ).

Optionally, the anion includes at least one of non-metallic radionuclides.

Further, optionally, the radionuclide contained in the anion may include, but is not limited to, phosphorus-32 (P-32), sulfur-35 (S-35), iodine-131 (I-131), and iodine. -At least one of 125 (I-125). For example, the acid radical anions include phosphorus-32 ⁽³² PO ₄ ^3-), a sulfur acid radical -35 ⁽³⁵ SO ₄ ^2-), iodine-131 ions ⁽¹³¹ I ^-) ions and iodine-125 ⁽¹²⁵ I ^-) in At least one of.

Optionally, when the anion does not include the radionuclide, the anion includes phosphate (PO ₄ ^3- ), carbonate (CO ₃ ^2- ), sulfate (SO ₄ ^2- ), alginate , hydroxide (OH ^-) and at least one silicate (SiO ₃ ^2-) in the.

Optionally, when the cation does not include the radionuclide, the cation includes at least one of silver ion, calcium ion, and magnesium ion.

In the present invention, the radionuclide precipitation refers to a solid substance that is hardly soluble in water, and almost no radionuclide-containing cations or anions are released in an aqueous solution. In addition, the radionuclide precipitate of the present invention is stably contained in the porous pores of porous silica, has a wide application range for temperature and pH, and is very stable in the human body temperature and pH range.

In the present invention, the radionuclide deposits contained in the porous holes can be one type, or two or more types of radionuclide deposits. Each of the radionuclide precipitates may contain one type of radionuclide or two or more types of radionuclide.

For example, in one embodiment of the present invention, the radionuclide precipitation is a radionuclide precipitation containing Sr-90, a radionuclide containing Y-90 or a radionuclide containing Ni-63; another of the present invention In an embodiment, the porous hole contains two kinds of radionuclide precipitates, one of which contains Y-90 in the radionuclide precipitate; the other contains Sr-90 in the radionuclide precipitate; in other embodiments, the The radionuclide precipitate may contain two radionuclides at the same time, for example, the radionuclide precipitate contains Sr-90 and Y-90 at the same time.

Specifically, the radionuclide precipitation can be, but not limited to, selected from yttrium phosphate-90 ( ⁹⁰ YPO ₄ ), strontium phosphate-90 ( ⁹⁰ Sr ₃ (PO ₄ ) ₂ ), nickel carbonate-63 ( ⁶³ NiCO ₃ ), At least one of iodine-125 silver (Ag ¹²⁵ I), iodine-131 silver (Ag ¹³¹ I), and calcium phosphorus-32 acid (Ca ₃ ( ³² PO ₄ ) ₂ ).

For example, the radionuclide precipitate can also be yttrium-90 ( ⁹⁰ Y ³² PO ₄ ) or strontium-90 ( ⁹⁰ Sr ₃ ( ³² PO ₄ ) ₂ ).

In the present invention, the shape of the radioactive particles includes one or more of spherical and non-spherical. Further, the shape of the radioactive particles includes one or more of spherical, quasi-spherical, square, rod-like, flake-like and irregular shapes. For example, in one embodiment of the present invention, the shape of the radioactive particles is spherical.

Optionally, the porous pores of the porous silica particles further include a second precipitate formed by the reaction of a non-radioactive metal cation and the anion, and the non-radioactive metal cation includes strontium ion ( One or more of Sr ²⁺ ), yttrium ion (Y ³⁺ ), nickel ion (Ni ²⁺ ), calcium ion (Ca ²⁺ ), silver ion (Ag ⁺ ) and magnesium ion (Mg ²⁺ ) .

Optionally, the anion that reacts with the non-radioactive metal cation to form a precipitate may or may not include a radionuclide. In one embodiment of the present invention, when the anion does not contain the radionuclide, the anion includes at least one of phosphate, carbonate, sulfate, alginate, hydroxide, and silicate. When the anion includes a radionuclide, the radionuclide included in the anion may include, but is not limited to, at least one of phosphorus-32, sulfur-35, iodine-131, and iodine-125.

Further, optionally, the non-radioactive metal cation and the cation that reacted to generate the radioactive precipitate may be isotopes of each other. For example, in one embodiment of the present invention, when the cation that reacts to generate the radionuclide precipitate is yttrium-90 ion, the non-radioactive metal cation is yttrium 89 ion. In another embodiment of the present invention, when the cation that reacts to generate the radionuclide precipitate is nickel-63 ion, the non-radioactive metal cation is nickel 58 ion.

Optionally, when the cations that react to produce the radionuclide precipitate do not have a corresponding stable isotope, the non-radioactive metal cation may be selected from at least one of calcium ion and magnesium ion.

On the one hand, the second precipitate of the present invention can participate in the adjustment of the radioactive activity of the radionuclide per unit mass of the radioactive particles. On the other hand, the second precipitation can also improve the formation of the radionuclide precipitation to a certain extent by adjusting the concentration of the non-radioactive metal cations and anions forming itself. The second precipitate of the present invention is also stably contained in the porous pores of porous silica, and the second precipitate and the radionuclide precipitate can mutually enhance the stability of each other in the porous pores.

Optionally, the porous pores of the porous silica particles further include water and a soluble metal salt, and the soluble metal salt includes sodium chloride, potassium chloride, sodium phosphate, potassium phosphate, sodium sulfate, and potassium sulfate , Sodium carbonate, potassium carbonate, sodium alginate, potassium alginate, sodium silicate and potassium silicate one or more.

Optionally, the porous pore size of the porous silica particles is 0.1 nm to 600 nm.

Further, optionally, the porous pore size of the porous silica particles is 0.1 nm-50 nm.

Further, optionally, the porous pore size of the porous silica particles is 0.1 nm-20 nm.

In the present invention, the porous pore size of the porous silica particles is nanometer and very small, and the radionuclide precipitate can be embedded in the porous pores of the porous silica particles, and the structure is stable. After testing, the radionuclide release rate of the radioactive particles of the present invention is extremely low, and the radionuclide hardly separates from the porous silica particles.

Optionally, the particle size of the porous silica particles is 0.05 μm-600 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-500 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-300 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-100 μm.

Further, optionally, the particle size of the porous silica particles is 30 μm-80 μm.

Further, optionally, the particle size of the porous silica particles is 30 μm-60 μm. For example, the particle size of the silica particles may be, but not limited to, 30 μm, or 35 μm, or 40 μm, or 45 μm, or 50 μm, or 55 μm, or 60 μm.

In the radioactive particles of the present invention, the mass of the radionuclide precipitation in the porous pores of the porous silica particles per unit mass can be adjusted according to actual requirements. Correspondingly, the radioactivity of the radionuclide in the radioactive particles can also be adjusted according to actual needs.

Optionally, the radioactivity of the radionuclide per gram of the radioactive particles is 0.1GBq-50GBq. Further, optionally, the radioactivity of the radionuclide per gram of the radioactive particles is 0.1 GBq-30 GBq.

In the second aspect, the present invention also provides a method for preparing radioactive particles, including:

Preparing a first solution, the first solution containing at least one cation;

Preparing a second solution, the second solution contains at least one anion, the cation and/or the anion contains a radionuclide, and the anion can react with the cation to generate a radionuclide precipitate;

Take a certain amount of hydrophilic porous silica particles, first slowly drop the first solution into the porous silica particles, and fully stir the first solution to enter the porous silica particles The second solution is slowly added dropwise to the porous silica particles, stirring the second solution into the porous holes, the anions in the second solution and the The metal cations in the first solution react in the porous pores to generate the radionuclide precipitate, and the radionuclide precipitate is placed in the porous pores, and then radioactive particles are collected.

In the present invention, the cation and/or the anion include a radionuclide, including the following three embodiments:

In the first embodiment of the present invention, both the cations in the first solution and the anions in the second solution contain radionuclides.

In the second embodiment of the present invention, the cation in the first solution contains a radionuclide, and the anion in the second solution does not contain a radionuclide.

In the third embodiment of the present invention, the anion in the second solution contains a radionuclide, and the cation in the first solution does not contain a radionuclide.

Optionally, the cation in the first solution contains at least one metal radionuclide.

Optionally, the cations in the first solution may, but are not limited to, include at least one of strontium-90 ions, yttrium-90 ions, and nickel-63 ions;

Optionally, the radionuclide contained in the anion in the second solution may include, but is not limited to, at least one of phosphorus-32, sulfur-35, iodine-131, and iodine-125.

In the present invention, the radionuclide-containing cations in the first solution and the radionuclide-containing anions in the second solution may both be derived from corresponding commercially available medical grade radionuclides-containing cations. Vegetarian solution.

Further, when the anion does not contain a radionuclide, the anion includes at least one of phosphate, carbonate, sulfate, hydroxide, alginate, and silicate.

Optionally, the first solution further includes a non-radioactive metal cation, and the non-radioactive metal cation can react with the anion in the second solution to form a second precipitate; the non-radioactive metal cation includes strontium ion , Yttrium ion, nickel ion, calcium ion, silver ion and magnesium ion.

Optionally, the anion generated by the reaction to generate the second precipitate may or may not include a radionuclide.

Further, optionally, the non-radioactive metal cation in the first solution and the cation in the first solution may be isotopes of each other. For example, in an embodiment of the present invention, when the cation in the first solution is yttrium-90 ion, the non-radioactive metal cation is yttrium-89 ion. In another embodiment of the present invention, when the cation in the first solution is nickel-63 ion, the non-radioactive metal cation is nickel-58 ion.

Optionally, when the radionuclide-containing cation does not have a corresponding stable isotope, the metal cation may be selected from at least one of calcium ion, magnesium ion and silver ion.

In the present invention, the first solution and the second solution are both solutions without precipitation and suspended particles. For example, in one embodiment of the present invention, the first solution includes a first soluble salt, and the first soluble salt includes a cation containing a radionuclide. The anion of the first soluble salt may, but is not limited to, a halogen ion, such as chloride ion.

In one embodiment of the present invention, the second solution includes a second soluble salt, and the cation in the second soluble salt may be, but is not limited to, sodium ion and/or potassium ion. When the anion of the second soluble salt does not contain a radionuclide, the anion of the second soluble salt includes at least one of phosphate, carbonate, sulfate, alginate, hydroxide, and silicate . For example, the second soluble salt includes sodium phosphate, potassium phosphate, sodium carbonate, potassium carbonate, sodium sulfate, potassium sulfate, sodium hydroxide, sodium alginate ((C ₆ H ₇ O ₆ Na) _n ) and sodium silicate One or more of.

Further, the first solution further includes a third soluble salt, and the third soluble salt includes a non-radioactive metal cation; the anion in the third soluble salt may but is not limited to a halogen ion; for example, a chloride ion.

Further, optionally, the anion in the third soluble salt and the anion in the first soluble salt may be the same or different. For example, in one embodiment of the present invention, the anion in the third soluble salt is the same as the anion in the first soluble salt. The anions in the first solution are derived from the anions of the first soluble salt and the third soluble salt.

In the preparation method of the present invention, when the cation in the first solution contains a radionuclide, the anion in the second solution is excessive relative to the cation in the first solution; The anions in the second solution can completely precipitate the cations in the first solution. Further, the anions of the second solution of the present invention can also completely precipitate the non-radioactive metal cations in the first solution.

In the preparation method of the present invention, when the anion in the second solution contains a radionuclide, the cation in the first solution is excessive relative to the anion in the second solution; The cations in the first solution can completely precipitate the anions in the second solution.

Further, when the anions in the second solution include radionuclides, the second solution may also include non-radioactive anions, and the cations in the first solution may also completely precipitate the second The non-radioactive anion in solution. For example, the anion in the second solution is ³² PO ₄ ^3- , the second solution may also contain PO ₄ ^3- , the first solution may contain a large amount of Ca ²⁺ , and the first solution Ca ^{2+ in} one solution can completely precipitate ³² PO ₄ ^3- and PO ₄ ^3- in the second solution.

For example, the non-radioactive anion in the second solution may be an anion dissolved in a fourth soluble salt in the second solution, and the non-radioactive anion may be phosphate, carbonate, sulfate, or alginate. , At least one of hydroxide and silicate.

Optionally, the porous pores of the porous silica particles further contain water and a soluble metal salt, and the soluble metal salt includes sodium chloride, potassium chloride, sodium phosphate, potassium phosphate, sodium sulfate, potassium sulfate, and carbonate. One or more of sodium, potassium carbonate, sodium alginate, potassium alginate, sodium silicate, and potassium silicate.

In the present invention, the soluble metal salt includes the unreacted second soluble salt, and the soluble secondary salt generated by the reaction between the second solution and the first solution. The soluble secondary salt generated by the reaction between the second solution and the first solution refers to the salt formed by the anion in the first solution and the cation in the second solution. Optionally, the salt formed by the anion in the first solution and the cation in the second solution may include, but is not limited to, at least one of sodium chloride and potassium chloride.

Optionally, in the preparation method, the process of collecting radioactive particles may be directly collecting the radioactive particles. The process of collecting radioactive particles may also be indirectly collecting the radioactive particles. For example, the radioactive particles are collected after deionized washing, filtration, and drying steps.

In the present invention, the water and soluble metal salt in the porous pores in the radioactive particles collected after washing with deionized water, filtering, and drying can be removed.

For example, the radioactive particles are collected after washing with deionized water, filtration, and drying, and the porous pores of the radioactive particles only contain the radionuclide precipitate and the second precipitate.

In the present invention, when the soluble metal salt in the porous pores of the radioactive particles has no additional harmful side effects to the human body, the radioactive particles can be directly collected. For example, the soluble metal salt may be, but is not limited to, sodium chloride, potassium chloride, or phosphate, or the amount of the soluble metal salt is extremely small and not enough to cause harm to the human body.

Optionally, the pH range of the first solution is 6.0-8.0. Further, the pH range of the first solution is 6.5-7.5.

Optionally, the pH range of the second solution is 6.0-12.0. Further, the pH range of the second solution is 6.5-10.

In the preparation method of the present invention, the total volume of the first solution and the second solution is less than or equal to the total water absorption of the porous silica particles.

Further, the total volume of the first solution and the second solution is less than the total water absorption of the porous silica particles.

In the present invention, the porous silica particles are hydrophilic materials with porous pores, and the porous silica particles also have a certain amount of water absorption. The total water absorption of the porous silica particles refers to the maximum water absorption volume per unit mass of the porous silica particles in a powder state (or a monodispersed state) under normal temperature and pressure. The unit of water absorption of the porous silica particles may be expressed in volume units, such as mL.

In addition, the total water absorption of the porous silica particles can also be obtained by converting the mass of the porous silica and the water absorption of the porous silica particles. The water absorption of the porous silica particles in the present invention refers to the ratio (%) of the mass of the largest aqueous solution that the porous silica particles can absorb in powder form to the dry weight of the porous silica particles.

In the present invention, since the total volume of the first solution and the second solution is less than or equal to the total water absorption of the certain amount of porous silica particles, in the preparation process of the radioactive particles, the first solution And the second solution will all enter the porous pores of the porous silica particles, and the prepared radioactive particles are in a dispersed powder form.

In the present invention, the volume of the first solution or the second solution can be adjusted according to the concentration of the solute in the respective solution; in order to realize that the anions in the second solution can be completely precipitated out of the first solution The cation containing the radionuclide or the cation of the first solution can completely precipitate the anion containing the radionuclide in the second solution.

Optionally, the volume ratio of the first solution to the second solution is 1: (0.1-10).

Further, optionally, the volume ratio of the first solution to the second solution is 1: (0.5-2). For example, in one embodiment of the present invention, the volume ratio of the first solution to the second solution is 1:1.

Optionally, after the first solution is slowly dripped, the porous silica particles are fully stirred before the second solution is slowly dripped. Wherein, the stirring speed of the full stirring process may be 60-100 revolutions per minute, and the stirring time may be 1-10 minutes. By fully stirring the porous silica particles, the first solution can be more uniformly dispersed, and the first solution can more completely enter the porous pores of the porous silica particles.

Further, optionally, after stirring the second solution to enter the porous pores, the porous silica particles to which the first solution and the second solution have been dropped are fully stirred. Wherein, the stirring speed of the full stirring process may be 60-100 revolutions per minute, and the stirring time may be 1-10 minutes.

By fully stirring the porous silica particles to which the first solution and the second solution have been dropped, the second solution can be dispersed more uniformly, and the second solution can enter more completely In the porous pores of the porous silica particles; more importantly, it can promote the anion in the second solution and the cation containing the metal radionuclide to more fully form a radionuclide precipitation.

In the preparation method of the present invention, the particle size of the porous silica particles is 0.05 μm-600 μm.

Further, optionally, the particle size of the porous silica particles is 0.05 μm-600 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-500 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-300 μm.

Further, optionally, the particle size of the porous silica particles is 10 μm-100 μm.

Further, optionally, the particle size of the porous silica particles is 30 μm-80 μm.

In the present invention, the porous silica particles may pass through a particle size screening process before being used to prepare the radioactive particles. The particle size screening process can be passed through a conventional screening device, for example, a classification device such as a screen with a certain aperture.

Because the traditional preparation method of radioactive particles is cumbersome and complicated, time-consuming, high cost, and even environmental pollution. Therefore, compared with the traditional preparation method, the preparation method of the radioactive particles developed by the present invention is simpler and easier to operate; and the entire preparation process takes extremely short time, and is especially suitable for preparing radioactive particles of metal radionuclides with a short half-life. In addition, the preparation method of the invention is environmentally friendly and has low cost.

In the third aspect, the present invention also provides an application of the radioactive particles according to the first aspect of the present invention or the radioactive particles prepared by the preparation method according to the second aspect of the present invention in the preparation of drugs for treating tumors.

Because the radioactive particles of the present invention have the characteristics of stable structure, low release rate of radionuclides, high safety and low cost, the radioactive particles of the present invention have broad application prospects in the field of preparing drugs for treating tumors. .

For example, the present invention also provides a preparation for radiotherapy, including the radioactive particles and pharmaceutically acceptable excipients.

The pharmaceutically acceptable excipient in the present invention refers to an adjuvant that does not cause side effects. Optionally, the excipient may include, but is not limited to, diluents, binders, fillers, coating polymers, plasticizers, glidants, disintegrants, lubricants, and release rate regulators.

In one embodiment of the present invention, the excipient may be physiological saline. Because the radioactive particles of the present invention are hydrophilic; therefore, the radioactive particles can be uniformly distributed in the physiological saline.

The radioactive particles of the present invention may contain at least one radionuclide, and the radioactive activity of the radioactive particles can be controlled by adjusting and controlling the precipitation content of the radionuclide; and the structure of the radioactive particles is stable, and the release rate of the radionuclide Low, with a particle size range of 0.05-600 μm; can be used to prepare most medical radiotherapy preparations; the preparation can be widely used in radiotherapy drugs for the treatment of various tumors and other diseases.

In one embodiment of the present invention, the preparation can reach the tumor site by perfusion, and the radionuclide precipitates in the porous pores of the radioactive particles contained in the preparation can emit beta rays to kill the tumor and achieve the purpose of treatment; The preparation for radiotherapy can also effectively control tumor invasion and metastasis, and has a strong killing effect on tumor cells, but has very low damage to normal cells around the tumor.

The preparation of the present invention can be used in radiotherapy of liver cancer by arterial perfusion embolization, and can also be used in radiotherapy of other malignant tumors, such as breast cancer, lung cancer, kidney cancer or tongue cancer.

The beneficial effects of the present invention include:

(1) The radioactive particles of the present invention include porous silica particles and at least one radionuclide precipitate contained in the porous pores of the porous silica particles; the structure of the radioactive particles is stable, and the radionuclide release rate The particle size of the radioactive particles, the type and activity of the radionuclide in the radionuclide precipitation can be adjusted, the safety is high, and it has broad application prospects.

(2) The preparation method of the radioactive particles of the present invention is simple and easy to operate, and the entire preparation process takes extremely short time, and can be used to prepare radioactive particles containing radionuclides with a short half-life; the radioactivity in the preparation method of the present invention The nuclide utilization rate is extremely high, environmental protection, low cost, and can be applied to industrialized mass production.

(3) The radioactive particles of the present invention have broad application prospects in the field of preparing drugs for the treatment of tumors. They have the characteristics of high safety and low cost. The radioactivity and particle size of the radioactive particles can be It can be adjusted according to actual needs, and can be used for radiotherapy preparations for various malignant tumors.

Description of the drawings

Figure 1 is a schematic flow chart of a method for preparing radioactive particles in an embodiment of the present invention;

Figure 2 is a scanning electron micrograph of the radioactive particles prepared in Example 1 of the present invention;

3 is a scanning electron micrograph of porous silica particles used in Example 1 of the present invention.

Detailed ways

The following are the preferred embodiments of the present invention. It should be pointed out that for those of ordinary skill in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications are also considered This is the protection scope of the present invention.

Unless otherwise specified, the chemical reagents used in the preparation method are all commercially available reagents.

Please refer to Figure 1. Figure 1 is a schematic flow chart of a method for preparing radioactive particles according to an embodiment of the present invention, including the following steps:

S10. Prepare a first solution, and the first solution contains at least one cation;

S20. Prepare a second solution, the second solution contains at least one anion, the cation and/or the anion contains a radionuclide, and the anion can react with the cation to generate a radionuclide precipitate;

S30. Take a certain amount of hydrophilic porous silica particles, first slowly add the first solution dropwise to the porous silica particles, and fully stir to make the first solution enter the porous dioxide The second solution is slowly added dropwise to the porous silica particles, and the second solution is stirred to make the second solution enter the porous holes, and the anions in the second solution and The metal cations in the first solution react in the porous pores to generate the radionuclide precipitate, and the radionuclide precipitate is placed in the porous pores, and then collected to obtain radioactive particles.

Optionally, in the preparation method of the radioactive particles, the first solution and/or the second solution may be prepared before the preparation. When the half-life of the radionuclide is very short, it can be temporarily configured during the preparation process.

The following further describes the embodiments of the present invention in multiple embodiments.

Control group 1 (cold experiment)

The control group 1 in this embodiment is strictly implemented according to the steps of the preparation method of the radioactive particles of the present invention. The difference is that the radionuclide Y-90 solution is replaced with its non-radioactive stable isotope Y-89 solution. It is to facilitate the detection of ion concentration and reduce the damage of radionuclides to detection personnel and equipment.

A preparation method of non-radioactive particles containing yttrium phosphate (Y-89), including:

Weigh calcium chloride and yttrium chloride hexahydrate, dissolve in deionized water, mix thoroughly, prepare 1L of calcium chloride containing 1mol/L and 10 ^-6 mol/L (about 89ppm) of yttrium chloride. Solution

Weigh sodium phosphate, dissolve it with deionized water, mix well, and prepare 1L second solution containing 0.7mol/L sodium phosphate;

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add 10 mL of the first solution dropwise to the medium, and stir the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip 10 mL of the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is completed; and then collecting non-radioactive particles containing yttrium phosphate.

Example 1

A method for preparing radioactive particles containing yttrium-90 includes:

Weigh 10 mL of the medical radioactive yttrium chloride-90 solution, use a radioactivity meter to measure its radioactivity to be 10GBq; add about 1.11g anhydrous calcium chloride to the solution, mix well, and prepare a solution containing 0.01mol chlorination The first solution of calcium and 10GBq yttrium chloride-90.

Weigh sodium phosphate, dissolve it in deionized water, and prepare 1L of a second solution containing 0.7mol/L sodium phosphate;

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip 10 mL of the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is complete; and then collect radioactive particles containing yttrium-90.

In the preparation process of Example 1, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 35 minutes to finally receive the radioactive particles containing yttrium-90. Weigh out 1g of prepared radioactive particles containing yttrium-90, and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.25GBq.

The radioactive particles prepared and the porous silica particles used were characterized respectively, and the results are shown in Figures 2 and 3. The comparison experiment results show that the surface shapes of the radioactive particles and porous silica particles prepared in Example 1 There is no obvious difference in appearance. It can be seen that the yttrium-90-containing radionuclide precipitates are contained in the porous pores of the radioactive particles.

Example 2

A method for preparing radioactive particles containing yttrium-90 includes:

Weigh 25mL of medical radioactive yttrium chloride-90 solution, use a radioactivity meter to measure its radioactivity to be 50GBq; add about 2.78g anhydrous calcium chloride to the solution, mix well, and prepare a solution containing 0.025mol chlorination The first solution of calcium and 50GBq yttrium chloride-90.

Weigh sodium phosphate, dissolve it in deionized water, and prepare 1L of a second solution containing 0.7mol/L sodium phosphate;

Weigh 50g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 60μm. The total water absorption of the porous silica particles is about 50mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drop 25 mL of the second solution into the container, stirring while dropping, and stirring for another 10 minutes after the dropwise addition; then collect radioactive particles containing yttrium-90.

In the preparation process of Example 2, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 43 minutes to finally receive the radioactive particles containing yttrium-90. Weigh out 1g of prepared radioactive particles containing yttrium-90 and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.50GBq.

Example 3

A method for preparing radioactive particles containing yttrium-90 includes:

Weigh 25mL of the medical radioactive yttrium chloride-90 solution, use a radioactivity meter to measure its radioactivity to be 50GBq; add about 7.6g of yttrium chloride hexahydrate solid to the solution, mix well, and prepare to obtain 0.025mol chlorine The first solution of yttrium oxide and 50GBq yttrium chloride-90.

Weigh sodium phosphate, dissolve it in deionized water, and prepare 1L of a second solution containing 1.1mol/L sodium phosphate;

Weigh 50g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 30μm. The total water absorption of the porous silica particles is about 50mL. Slowly add about all of the first solution dropwise to the medium, stirring the porous silica particles while dropping; after the addition, stir for 10 minutes to fully disperse the porous silica particles. Then slowly drop 25 mL of the second solution into the container, stirring while dropping, and stirring for another 10 minutes after the dropwise addition; then collect radioactive particles containing yttrium-90.

In the preparation process of Example 3, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 44 minutes to finally receive the radioactive particles containing yttrium-90. Weigh out 1g of prepared radioactive particles containing yttrium-90 and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.50GBq.

Example 4

A method for preparing radioactive particles containing yttrium-90 includes:

Weigh 25mL of medical radioactive yttrium chloride-90 solution, use a radioactivity meter to measure its radioactivity to be 50GBq; add about 2.38g magnesium chloride to the solution, mix well, and prepare to obtain 0.025mol magnesium chloride and 50GBq yttrium chloride -90 of the first solution.

Weigh sodium phosphate, dissolve it in deionized water, and prepare 1L of a second solution containing 1.0mol/L of sodium phosphate;

Weigh 50g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 30μm. The total water absorption of the porous silica particles is about 50mL. Slowly add all the first solution dropwise in the medium, stirring the porous silica particles while dropping; after the dropwise addition, transfer the porous silica particles to a dispersing machine, and disperse for 5 minutes under the condition of 100 revolutions/min. Then slowly drop 25mL of the second solution into the container, stirring while dropping, transfer the porous silica particles to the dispersing machine after the dropping, and disperse for 5 minutes under the condition of 100 revolutions/minute; Radioactive particles of yttrium-90.

In the preparation process of Example 4, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 40 minutes to finally receive the radioactive particles containing yttrium-90. Weigh out 1g of prepared radioactive particles containing yttrium-90 and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.50GBq.

Example 5

A preparation method of strontium-90-containing radioactive particles includes:

Weigh 10 mL of medical radioactive strontium chloride-90 solution, use a radioactivity meter to measure its radioactivity to be 16GBq; add about 1.11g anhydrous calcium chloride to the solution, mix well, and prepare a solution containing 0.01mol chlorination The first solution of calcium and 16GBq strontium chloride-90.

Weigh sodium phosphate, dissolve it in deionized water, and prepare 1L of a second solution containing 0.7mol/L sodium phosphate;

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip 10 mL of the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is completed; then, the radioactive particles containing strontium-90 are collected.

In the preparation process of Example 5, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 35 minutes to finally receive the radioactive particles containing strontium-90. Weigh out 1g of prepared radioactive particles containing strontium-90, and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.40GBq.

Example 6

A method for preparing radioactive particles containing nickel-63, including:

Weigh 10 mL of medical radioactive nickel-63 ion solution, use a radioactivity meter to measure its radioactivity to be 16GBq; add about 1.11g anhydrous calcium chloride to the solution, mix well, and prepare to obtain 0.01mol calcium chloride And the first solution of 16GBq nickel-63 ions.

Weigh sodium phosphate, dissolve it with deionized water, and prepare 1L second solution containing 1.1mol/L sodium carbonate;

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip 10 mL of the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is completed; then, the radioactive particles containing nickel-63 are collected.

In the preparation process of Example 6, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 35 minutes to finally receive the radioactive particles containing nickel-63. Weigh 1g of the prepared radioactive particles containing nickel-63, and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.40GBq.

Example 7

A preparation method of phosphorus-32-containing radioactive particles includes:

Weigh anhydrous calcium chloride, add deionized water, mix thoroughly, and dilute to 10 mL to prepare a first solution containing 0.015 mol of calcium chloride.

Weigh 10 mL of medical radioactive phosphate-32 sodium solution, use a radioactivity meter to measure its radioactivity to be 10GBq; add about ordinary sodium phosphate solid to the solution, mix well, and prepare to obtain about 0.007mol sodium phosphate and 10GBq A second solution of sodium phosphorus-32.

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip all the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is completed; then collect the radioactive particles containing phosphorus-32.

In the preparation process of Example 7, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 35 minutes to finally receive the radioactive particles containing phosphorus-32. Weigh out 1g of prepared radioactive particles containing phosphorus-32 and test with a radioactivity meter. The measured radioactivity of 1g of radioactive particles is 0.25GBq.

Example 8

A method for preparing radioactive particles containing iodine-125, including:

Weigh silver nitrate, add deionized water, mix thoroughly, and dilute to 10 mL to prepare a first solution containing 0.012 mol of silver nitrate.

Weigh 10 mL of a medical radioactive iodine-125 sodium solution, use a radioactivity meter to measure its radioactivity to be 10GBq; add sodium chloride solid to the solution, mix well, and prepare a solution containing about 0.01mol sodium chloride and 10GBq A second solution of sodium iodine-125.

Weigh 20g of monodispersed porous silica particles and place them in a wide-mouthed container. The particle size of the porous silica particles is about 50μm. The total water absorption of the porous silica particles is about 20mL. Slowly add all the first solution dropwise to the medium, stirring the porous silica particles while dropping; stir for 10 minutes after the dropwise addition to fully disperse the porous silica particles. Then slowly drip all the second solution into the container, stirring while dripping, and stirring for another 10 minutes after the dripping is finished; then collecting radioactive particles containing iodine-125.

In the preparation process of Example 8, the second solution was prepared in advance, the preparation of the first solution started timing, and it took about 35 minutes to finally receive the radioactive particles containing iodine-125. Weigh out 1g of prepared radioactive particles containing iodine-125 and test with a radioactivity meter. The measured activity of 1g of radioactive particles is 0.25GBq.

Effect Example One

Radioactivity detection

Weigh 1g each of the radioactive particles prepared in Examples 1-8, and name them as experimental group 1 to experimental group 8. To the radioactive particles in each group, 20 mL of 10% physiological saline was added and sealed. Then placed in a 50 degrees Celsius incubator, placed for 24 hours, centrifuged to collect the filtrate, and tested the filtrate with a radioactivity meter. The results are shown in Table 1.

Table 1 Test data table of radioactivity in experimental group

test group	Radioactivity (GBq)
Experimental group 1	0
Experimental group 2	0
Experimental group 3	0
Experimental group 4	0
Experimental group 5	0
Experimental group 6	0
Experimental group 7	0
Experimental group 8	0

It can be seen from the test data that the radioactive particles prepared in Examples 1-8 of the present invention all show good structural stability. After long-term immersion, the radioactivity is detected, and the release rate of radionuclides is close to 0. %, indicating that the radionuclide in the radioactive particles worthy of the preparation method of the present invention will not have the risk of leakage.

Effect embodiment two

Ion concentration detection

3 g of non-radioactive particles containing yttrium 89 were prepared by the preparation method described in control group 1, and 20 mL of 10% physiological saline was added and sealed. Then it was placed in a 50°C thermostat, taken out and shaken for 5 minutes every day, and left for 14 days. After 14 days, the filtrate was collected by centrifugation, and the concentration of yttrium ion in the filtrate was measured by ICP (inductively coupled plasma spectrometer).

Among them, the ICP test results show that the yttrium ion concentration in the filtrate is less than 0.02mg/L (below the detection limit, that is, no yttrium ion is detected).

Then, weigh 0.3g of non-radioactive particles, add 20mL 10% nitric acid solution, soak for 4 hours, make the volume 50mL, centrifuge to collect the filtrate, and use ICP to test the yttrium ion concentration in the filtrate.

Among them, the ICP test results show that the yttrium ion concentration in the filtrate is 40 ppm.

According to the analysis of the above test data, in the non-radioactive particles containing yttrium 89 prepared by the preparation method of Comparative Group 1, yttrium is contained in the porous pores of the porous silica particles in a precipitated form, and the structure is stable. In the 14-day immersion, there was almost no release of yttrium ions. The release of yttrium ions from the non-radioactive particles can be detected only after the yttrium phosphate precipitate in the porous pores is dissolved with nitric acid.

The above are the preferred embodiments of the present invention. It should be pointed out that for those of ordinary skill in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications are also considered This is the protection scope of the present invention.

Claims (20)

1. A radioactive particle, which comprises porous silica particles and at least one radionuclide precipitate contained in the porous pores of the porous silica particles; the porous silica particles are hydrophilic, so The radionuclide precipitate is generated by the reaction of cations and anions, and the cations and/or the anions comprise radionuclides.
2. The radioactive particle of claim 1, wherein the radionuclide contained in the cation includes at least one of strontium-90, yttrium-90, and nickel-63.
3. The radioactive particle according to claim 1, wherein the radionuclide contained in the anion includes at least one of phosphorus-32, sulfur-35, iodine-131, and iodine-125.
4. The radioactive particle of claim 1, wherein when the anion does not contain the radionuclide, the anion includes at least one of phosphate, carbonate, sulfate, hydroxide, alginate, and silicate. One kind.
5. The radioactive particle according to claim 1, wherein when the cation does not contain the radionuclide, the cation includes at least one of silver ion, calcium ion, and magnesium ion.
6. The radioactive particle of claim 1, wherein the radionuclide precipitate comprises yttrium phosphate-90, strontium phosphate-90, nickel carbonate-63, silver iodide-125, silver iodide-131, and phosphorus-32 acid At least one of calcium.
7. The radioactive particle according to any one of claims 1 to 6, wherein the porous pores of the porous silica particle further comprise a second precipitate, and the second precipitate is composed of a non-radioactive metal cation and the anion Generated by the reaction, the non-radioactive metal cations include one or more of strontium ion, yttrium ion, nickel ion, silver ion, calcium ion and magnesium ion.
8. The radioactive particles according to any one of claims 1 to 6, wherein the particle size of the porous silica particles is 0.05 μm to 600 μm.
9. The radioactive particle according to any one of claims 1 to 6, wherein the porous silica particle has a porous pore size of 0.1 nm to 600 nm.
10. The radioactive particle according to any one of claims 1 to 6, wherein the radioactivity of the radionuclide is 0.1GBq-50GBq per gram weight of the radioactive particle.
11. The radioactive particles according to any one of claims 1-6, wherein the porous pores of the porous silica particles further comprise water and a soluble metal salt, and the soluble metal salt includes sodium chloride, chlorinated One or more of potassium, sodium phosphate, potassium phosphate, sodium sulfate, potassium sulfate, sodium carbonate, potassium carbonate, sodium alginate, potassium alginate, sodium silicate, and potassium silicate.
12. A method for preparing radioactive particles, including:

    Preparing a first solution, the first solution containing at least one cation;

    Preparing a second solution, the second solution contains at least one anion, the cation and/or the anion contains a radionuclide, and the anion can react with the cation to generate a radionuclide precipitate;

    Take a certain amount of hydrophilic porous silica particles, first slowly drop the first solution into the porous silica particles, and fully stir the first solution to enter the porous silica particles The second solution is slowly added dropwise to the porous silica particles, stirring the second solution into the porous holes, the anions in the second solution and the The metal cations in the first solution react in the porous pores to generate the radionuclide precipitate, and the radionuclide precipitate is placed in the porous pores, and then radioactive particles are collected.
13. The preparation method of claim 12, wherein the cations in the first solution include at least one of strontium-90 ions, yttrium-90 ions, and nickel-63 ions; and the cations in the second solution The radionuclide contained in the anion includes at least one of phosphorus-32, sulfur-35, iodine-131, and iodine-125.
14. The preparation method according to claim 12, wherein, when the anion does not contain the radionuclide, the anion includes at least one of phosphate, carbonate, sulfate, hydroxide, alginate, and silicate. One kind.
15. The preparation method according to claim 12, wherein, when the cation does not contain the radionuclide, the cation includes at least one of silver ion, calcium ion, and magnesium ion.
16. The preparation method of claim 12, wherein the particle size of the porous silica particles is 0.05 μm to 600 μm; and the porous pore size of the porous silica particles is 0.1 nm to 600 nm.
17. The preparation method according to any one of claims 12-16, wherein the first solution further comprises a non-radioactive metal cation, and the non-radioactive metal cation can react with the anion in the second solution to generate The second precipitation; the non-radioactive metal cations include one or more of strontium ion, yttrium ion, nickel ion, calcium ion, silver ion and magnesium ion.
18. The preparation method of claim 12, wherein the total volume of the first solution and the second solution is less than or equal to the total water absorption of the porous silica particles.
19. The preparation method according to claim 12, wherein the radioactivity of the radionuclide per gram of the radioactive particles is 0.1GBq-50GBq.
20. An application of the radioactive particles according to any one of claims 1-11 or the radioactive particles prepared by the preparation method according to any one of claims 12-19 in the preparation of drugs for treating tumors.

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