38results about "Neutron capture therapy" patented technology

Stable isotope labeling and neutron activation to measure biological functions are provided, as are the use and method of adding a chemical monitor to correct for neutron flux to sample vials prior to the addition of sample is presented, and the use of stable isotopes as a chemical bar code for vials and other items. Methods are provided also for measuring glomerular filtration rate and glomerular sieving function in a subject, and for measuring other physiological functions.

The present invention discloses a methodology for the characterization and determination of mixed-field dosimetry for 252Cf Applicator Tube (AT)-type medical sources, utilizing ionization chambers, GM counters, and Monte Carlo methods. Unlike the previous methodologies, the present invention discloses a specification of dose to muscle, rather than dose to water, for clinical dosimetry of 252Cf medical sources. A dosimetry protocol, similar to that utilized for ICRU-45, with parameters determined specifically for 252Cf brachytherapy is disclosed. Neutron isodose distributions and data necessary for clinical implementation of 252Cf AT sources are also disclosed herein. Additionally, novel methods for the encapsulation, storage, and delivery / implantation of 252Cf radionuclide sources are disclosed.

Described is a method of using gadolinium-containing compounds as agents for neutron capture therapy to treat neoplastic cell growth. The subject is exposed to a gadolinium-containing compound for a time sufficient to allow the compound to accumulate in neoplastic cells. The subject is then exposed to a thermal and / or epithermal neutron flux, thereby initiating a neutron capture reaction in the gadolinium atoms that results in specific death of neoplastic cells.

Described is a method of using gadolinium-containing compounds as agents for neutron capture therapy to treat neoplastic cell growth. The subject is exposed to a gadolinium-containing compound for a time sufficient to allow the compound to accumulate in neoplastic cells. The subject is then exposed to a thermal and / or epithermal neutron flux, thereby initiating a neutron capture reaction in the gadolinium atoms that results in specific death of neoplastic cells.

The invention relates to an amphiphilic graphene-gold thermal radiotherapy nano drug which comprises amphiphilic graphene, nano gold particles loaded on the surface of amphiphilic graphene, and tumor targeted molecules connected on amphiphilic graphene. The invention also provides a preparation method of the amphiphilic graphene-gold thermal radiotherapy nano drug, which comprises the following steps: modified diisocyanate on the surface of graphene oxide, and then adding a polymer containing carboxyl to enable carboxyl to react with diisocyanate, so as to obtain amphiphilic graphene; carrying out in-situ growth of gold nano particles on the surface of amphiphilic graphene; and finally, adding tumor targeted molecules containing amino groups and coupling agents into the product to enable the tumor targeted molecules containing amino groups to react with carboxyl of amphiphilic graphene, so as to obtain the amphiphilic graphene-gold thermal radiotherapy nano drug. The invention also provides the application of the amphiphilic graphene-gold thermal radiotherapy nano drug serving as an anti-tumor drug. The prepared nano drug can be compounded with protons / neutrons for treating through thermal therapy and has a relatively strong killing effect on tumor cells.

According to an aspect, a magnesium fluoride sintered compact includes a disc-shaped magnesium fluoride sintered compact having a through hole passing through a center axis of the disc-shaped magnesium fluoride sintered compact. The magnesium fluoride sintered compact has a relative density of 95% or higher.

The present invention discloses a methodology for the characterization and determination of mixed-field dosimetry for 252Cf Applicator Tube (AT)-type medical sources, utilizing ionization chambers, GM counters, and Monte Carlo methods. Unlike the previous methodologies, the present invention discloses a specification of dose to muscle, rather than dose to water, for clinical dosimetry of 252Cf medical sources. A dosimetry protocol, similar to that utilized for ICRU-45, with parameters determined specifically for 252Cf brachytherapy is disclosed. Neutron isodose distributions and data necessary for clinical implementation of 252Cf AT sources are also disclosed herein. Additionally, novel methods for the encapsulation, storage, and delivery / implantation of 252Cf radionuclide sources are disclosed.

A composition for neutron capture therapy and a method of preparing the same are provided. The composition includes at least one nanodiamond particle and at least one neutron capture element, in which the at least one neutron capture element is embedded into the at least one nanodiamond particle by using an ion implantation system.

The invention provides MRI detectable species of formula (I): Dp-Sn-Nm, wherein D is a MRI detectable moiety; S is a spacer; N is a molecule of a nutrient or pseudo-nutrient; n is 0 or an integer, m is an integer and p is an integer. These compounds are useful for internalising into tumor cells an amount of the MRI detectable moiety that is distinguishably higher than the amount internalised in normal healthy cells thus allowing the diagnosis of tumors. The internalisation of the MRI detectable moiety involves the nutrients or pseudo-nutrients transporting system. Preferred compounds of formula (I) are those wherein D is the chelated complex of a paramagnetic metal ion.

A neutron capture therapy system capable of eliminating amyloid β-protein includes a neutron capture therapy device and a compound capable of specifically binding to the amyloid β-protein having a nuclide with a large thermal neutron capture cross section. The neutron capture therapy device includes a neutron source, a beam shaping assembly and a collimator, the neutrons released by the neutron source pass through the beam shaping assembly and are slowed into a neutron beam within a certain energy range. The neutron beam irradiates the compound, and the energy generated by the reaction thereof can destroy the structure of the amyloid β-protein. The neutron capture therapy system can specifically eliminate the amyloid β-protein, and reduce the damage to the tissues surrounding the amyloid β-protein.

Systems and methods including a material that emits high energy beta particles to destroy cancer cells contained in cancerous tumor or tissue. Electronic neutron generators produce neutrons with energies that have a high probability to interact with the material yttrium-89 to produce yttrium-90. Yttrium-90 emits beta radiation with a maximum energy of about 2.25 MeV and a half-life of about 64 hours, which decays to stable zirconium. Stable yttrium-89 can be directly placed in or around cancerous tissue and irradiated with neutrons in the 0.1-15 KeV energy range to produce significant amounts of yttrium-90. The beta radiation emitted by yttrium-90 will primarily destroy the more radiation sensitive cancer cells within the range of the beta particles. The resulting zirconium isotope is not radioactive such that no further radiation is released. A low probability gamma is also created that will assist in cancer cell destruction.

The invention provides MRI detectable species of formula (I): Dp-Sn-Nm, wherein D is a MRI detectable moiety; S is a spacer; N is a molecule of a nutrient or pseudo-nutrient; n is 0 or an integer, m is an integer and p is an integer. These compounds are useful for internalizing into tumor cells an amount of the MRI detectable moiety that is distinguishably higher than the amount internalized in normal healthy cells thus allowing the diagnosis of tumors. The internalization of the MRI detectable moiety involves the nutrients or pseudo-nutrients transporting system. Preferred compounds of formula (I) are those wherein D is the chelated complex of a paramagnetic metal ion.

A pharmaceutical, wherein the formulation is a conjugate of a saccharide with one or a plurality of isotopic boron-10 atoms or gadolinium, and having a utility in the binary form of low energy neutron therapy (i.e. boron neutron capture therapy). Further, that the therapy has an indicated use for the selective targeting and killing of oxygenated and hypoxic cells in tumors, and that the pharmaceutical is preferentially taken up by cancer cells. The inclusion of any of a family of saccharides, its derivatives or analogues, including sulfur linkage saccharides as a delivery carrier for boron-10 atoms or the rare element gadolinium is a strategy to take advantage of the hallmark of cancer cells, that being an increased requisite for glucose to sustain a rate of uncontrollable cell division and proliferation. A cancer cell facilitates an increase in availability of molecular glucose by overexpression of glucose transporter proteins on membrane surfaces. The use of a saccharide attached with one or more of isotopic boron-10 atoms or gadolinium is to utilize this known amplification of glucose transport to achieve significantly greater quantities of isotopic boron-10 atoms or gadolinium taken up cancer cells than deposited into healthy cells.Tissues of malignant tumors are not homogeneous, but consist of oxygenated and hypoxic cells. Oxygen deprivation causes cancer cells to be resistant to radiation and to chemotherapeutic agents. It is further noted that the etiology of metastasis is hypoxia induced tumor cells, where oxygen deprivation stimulates activation of genes, and that one gene is responsible for programming oxygen-starved cancer cells to migrate to distant and specific host organs.A saccharide with a ring sulfur atom can participate more readily in biological processes than a sugar with a ring oxygen atom, and such thiosaccharides possess unique physiochemical properties that include penetration of a viscous lipid bilayer membrane of a cancer cell, and resistance to reduction by enzymes, enabling retention of the conjugate within cytoplasm, mitochondria and nuclei of cancer cells. Therefore, an objective is the use of a conjugated boron-10 or gadolinium thiosaccharide as a pharmaceutical for low energy neutron therapy to participate in a boron-10 interception of a passing slow (thermal) neutron to produce an α-particle, high energy Li-7 ion and low energy gamma (γ) rays that are damaging to a cell. The pharmaceutical, when in combination with exposure of a subject to low energy neutrons, is a method of treatment for a subject diagnosed with a cancer, so as to cause a regression of tumors, to inhibit metastasis, and to extend life.

Systems and methods including a material that emits high energy beta particles to destroy cancer cells contained in cancerous tumor or tissue. Electronic neutron generators produce neutrons with energies that have a high probability to interact with the material yttrium-89 to produce yttrium-90. Yttrium-90 emits beta radiation with a maximum energy of about 2.25 MeV and a half-life of about 64 hours, which decays to stable zirconium. Stable yttrium-89 can be directly placed in or around cancerous tissue and irradiated with neutrons in the 0.1-15 KeV energy range to produce significant amounts of yttrium-90. The beta radiation emitted by yttrium-90 will primarily destroy the more radiation sensitive cancer cells within the range of the beta particles. The resulting zirconium isotope is not radioactive such that no further radiation is released. A low probability gamma is also created that will assist in cancer cell destruction.

This invention provides a process for producing a radioactive arsenic-containing compound, comprising the steps of: (i) subjecting an arsenic-containing compound to a neutron irradiation treatment, said arsenic-containing compound being selected from a group consisting of As2O3, As2S3, As2S2, and a combination thereof, such that the arsenic element contained in the arsenic-containing compound is converted to a radioactive arsenic isotope; and (ii) recovering the resultant product from step (i). This invention also provides a pharmaceutical composition comprising a therapeutically effective amount of the radioactive arsenic-containing compound and a pharmaceutically acceptable carrier. The pharmaceutical composition can be used in the treatment of tumors / cancers such as hematological malignancies and solid tumors.

Provided is a pharmaceutical composition including O-(5-amino-2-phenylbenzoxazole-7-yl)methyl-3,5-dichloro-L-tyrosine, or a pharmaceutically acceptable salt thereof, for use in treatment of a disease such as an allergic disease, an autoimmune disease, or an inflammatory disease in a subject, the pharmaceutical composition being administered to the subject having a Non-Rapid (Slow and / or Intermediate) type NAT2 gene.

The present invention relates to a composition that includes gadolinium particles encapsulated in microsphere shells. The composition is suitable for use as a contrast agent with a plurality of imaging modalities, including, for example, ultrasound, magnetic resonance imaging, and computed temography. The compositions also are useful for therapeutic applications, including neutron capture therapy.

Provided is a pharmaceutical composition containing O-(5-amino-2-phenylbenzoxazole-7-yl)methyl-3,5-dichloro-L-tyrosine, or a pharmaceutically acceptable salt thereof, for use in treatment of a cancerous disease in a subject, the pharmaceutical composition being administered to the subject having a Non-Rapid (Slow and / or Intermediate) type NAT2 gene.

Alkylphosphocholine analogs incorporating a chelating moiety that is chelated to gadolinium are disclosed herein. The alkylphophocholine analogs are compounds having the formula:or a salt thereof. R1 includes a chelating agent that is chelated to a gadolinium atom; a is 0 or 1; n is an integer from 12 to 30; m is 0 or 1; Y is —H, —OH, —COOH, —COOX, —OCOX, or —OX, wherein X is an alkyl or an arylalkyl; R2 is —N+H3, —N+H2Z, —N+HZ2, or —N+Z3, wherein each Z is independently an alkyl or an aroalkyl; and b is 1 or 2. The compounds can be used to detect solid tumors or to treat solid tumors. In detection / imaging applications, the gadolinium emits signals that are detectable using magnetic resonance imaging. In therapeutic treatment, the gadolinium emits tumor-targeting charged particles when exposed to epithermal neutrons.

A process for treating highly localized carcinoma cells that provides precise positioning of a therapeutic source of highly ionizing but weakly penetrating radiation, which can be shaped so that it irradiates essentially only the volume of the tumor. The intensity and duration of the radiation produced by the source can be activated and deactivated by controlling the neutron flux generated by an array of electrically controlled neutron generators positioned outside the body being treated. The energy of the neutrons that interact with the source element can be adjusted to optimize the reaction rate of the ionized radiation production by utilizing neutron moderating material between the neutron generator array and the body. The source device may be left in place and reactivated as needed to ensure the tumor is eradicated without exposing the patient to any additional radiation between treatments. The source device may be removed once treatment is completed.

A neutron capture therapy system capable of eliminating amyloid β-protein includes a neutron capture therapy device and a compound capable of specifically binding to the amyloid β-protein having a nuclide with a large thermal neutron capture cross section. The neutron capture therapy device includes a neutron source, a beam shaping assembly and a collimator, the neutrons released by the neutron source pass through the beam shaping assembly and are slowed into a neutron beam within a certain energy range. The neutron beam irradiates the compound, and the energy generated by the reaction thereof can destroy the structure of the amyloid β-protein. The neutron capture therapy system can specifically eliminate the amyloid β-protein, and reduce the damage to the tissues surrounding the amyloid β-protein.

A radioactive or radioactivable nanostructure has a core, the core including at least two atoms, at least one of which being radioactive or radioactivable, and a shell encapsulating the core and selected among a selected material so that at the most, 20% of the radioactive radiation produced by the core are stopped or absorbed by the shell and the manufacturing method thereof.The various uses of such a nanostructure, and more specifically the use thereof in the medical field, and more specifically in targeted radiotherapy are also disclosed.