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Core-Excited Nanoparticles and Methods of Their Use in the Diagnosis and Treatment of Disease

a nanoparticle and core-excited technology, applied in the field of core-excited nanoparticles, can solve the problems of limited practical clinical value of nir for most cancers, limited light emission efficiency, and large amount of heat generation, and achieves minimal side effects, low cost, and practical

Inactive Publication Date: 2013-08-01
TERSIGNI SAMUEL HARRY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0028]This technology provides practical, cost-effective methods and nanomaterial compositions for diagnosis and hyperthermia treatment of disease or disorders. The technology should be effective to treat disease that has spread throughout the body, such as metastatic cancers (known as stage IV, in the case of cancer), even when the disease is in such small amounts or locations in the body that it is not detectable. The materials and methods can also be used for imaging, with detection resulting from either the X-ray absorption or the generation of heat. The technology is practical, effective, and non-invasive, with minimal side-effects, and should be usable with existing medical hardware now widely deployed in hospitals around the world.

Problems solved by technology

However, NIR is of limited practical clinical value for most cancers because of the inability of safe amounts of NIR to penetrate more than a few centimeters into the human body.
. . used for the purpose of light emission, for example, produce heat and therefore the light emission efficiency is limited.”
These particles do not generate a significant amount of heat, nor do they use shell materials that facilitate heating, as heating would suggest inefficiency in emitting radiation from these radioimmunotherapy nanoparticles.
While methodologies for selectively delivering nanoparticles to target cells are known, existing nanoparticles cannot be sufficiently heated to kill cells.

Method used

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  • Core-Excited Nanoparticles and Methods of Their Use in the Diagnosis and Treatment of Disease
  • Core-Excited Nanoparticles and Methods of Their Use in the Diagnosis and Treatment of Disease
  • Core-Excited Nanoparticles and Methods of Their Use in the Diagnosis and Treatment of Disease

Examples

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example 1

Targeting Breast Cancer

[0150]The following CENT treatment approach is based on a core-shell nanoparticle designed on the basis of X-ray excited persistent luminescence and the maximum safe dose of X-ray radiation the patient may tolerate. As a reference point for the therapeutic dosages of X-ray radiation needed, the patient is 180 cm in height and 80 Kg in weight.

[0151]First, nanoparticles of SrAl2O4:Eu:Dy of approximately 60 nm in diameter, prepared by solid state reaction methods, are used as the core in a core-shell nanoparticle material design. The X-ray luminescence spectrum of this material has a maximum at approximately 510 nm, similar to the non-doped SrAl2O4 material, as shown in FIG. 7. A nanoshell of gold is grown over the nanocore material. Gold nanoparticles have the absorbance spectrum typical of that shown in FIGS. 3 and 4; additional Mie theory calculations allow design for maximum spectral overlap (FRET) between core and shell. The nanoparticle is then coated with ...

example 2

Treatment of Colon Cancer

[0153]The following CENT treatment approach is based on a core-shell nanoparticle designed on the basis of X-ray excited persistent luminescence and the maximum safe dose of computed tomography (CT) radiation the patient may tolerate. As a reference point for the therapeutic dosages of X-ray radiation needed, the patient is 180 cm in height and 80 Kg in weight.

[0154]First, nanoparticles of BaFBr:Eu2+, Mn2+ of 20 nm in diameter are prepared as the core material as outlined in Chen and Zhang, J. Nanoscience and Nanotechnology 6, 1159-1166, 2006. The X-ray luminescence spectrum of this material has a maximum at approximately 400 nm, as shown in FIG. 6A. A nanoshell of silver then is grown over the nanocore material. Silver nanoparticles have the absorbance spectrum typical of that shown in FIG. 4; additional Mie theory calculations allow design for maximum spectral overlap (FRET) between core and shell. The nanoparticle is then coated with polyethylene glycol (...

example 3

Treatment of Colon Cancer Using Nanoparticles Containing a Radionucleotide in the Nanoparticle Core

[0159]The following CENT treatment approach is based on a core-shell nanoparticle designed to a typical geometry of a 100-nm diameter core of Pd-103 and a 20-nm thick encasing layer of LaPO4:Ce, Tb and a 20-nm thick shell of gold. The radionuclide Pd-103 is an Auger electron emitter, with a 17-day half-life, that excites the Ce- and Tb-doped LaPO4 encasing layer to emit 543-nm green light, with a quantum yield of approximately 80%. The green light is absorbed by the gold shell (See FIG. 3) and heats the nanoparticle region that contains the targeted elements of the treatment, which are colon cancer cells in blood, lymph and tissue (tumors). The maximum dose of these nanoparticles that can be safely infused is administered to the patient. As a reference point for the therapeutic dosages, the patient is 180 cm in height and 80 Kg in weight.

[0160]First, nanoparticles of Pd-103 of 100-nm i...

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Abstract

Core-excited nanoparticle thermotherapy (CENT) represents a new paradigm in thermotherapy. The CENT method employs core-shell nanoparticles. The core of the nanoparticles is formed from one or more core-exciting, energy absorbing materials which absorbs core-exciting energy, either from an external energy source or from an energy source within the nanoparticle core (e.g., one or more radionuclides which undergo decay). Upon excitation by the core-exciting energy, the one or more core-exciting, energy absorbing materials reemit energy. A shell surrounds the particle nanoparticle core. The energy reemitted by the one or more core-exciting, energy absorbing materials is absorbed by the nanoparticle shell, so as to heat the shell of the nanoparticle. The heated nanoparticle then heats the surrounding region, to a temperature sufficient to detect, affect, damage or destroy the targeted cell or material. These core-shell nanoparticles can be administered to a patient in need thereof to treat diseases or disorders, including cancer. CENT nanoparticles can be optionally be bound to targeting agents that deliver them to the region of the diseased cell.

Description

FIELD OF THE INVENTION[0001]The present invention is generally in the field of core-shell nanoparticles, especially metal and ceramic core nanoparticles, for use in diagnosis and treatment of disease.BACKGROUND OF THE INVENTION[0002]Generation of heat in the range of temperature from about 40° C. to about 46° C. (hyperthermia) can cause irreversible damage to diseased cells, whereas normal cells are not similarly affected. Three widely investigated methods for inducing hyperthermia, including radio-frequency waves (U.S. Pat. No. 7,510,555 to Kanzius), magnetic fields and near infrared radiation, have been utilized. As mentioned in U.S. Pat. No. 7,074,175 to Handy, “Hyperthermia may hold promise as a treatment for cancer because it induces instantaneous necrosis (typically called thermo-ablation) and / or a heat-shock response in cells (classical hyperthermia), leading to cell death via a series of biochemical changes within the cell. One particularly advantageous property is that, in ...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): A61K41/00A61N5/10
CPCA61K41/0052A61K51/1244A61B18/04A61N2005/1098A61N5/10A61N5/1001Y10S977/904A61P35/00
Inventor TERSIGNI, SAMUEL HARRY
Owner TERSIGNI SAMUEL HARRY
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