Patent application number | Description | Published |
20090170131 | Agents for Imaging Apoptosis - Compositions, and methods of using such compositions, having the following Formula (I) or salt, ester, or hydrate thereof, wherein R | 07-02-2009 |
20090263485 | Targeted hollow gold nanostructures and methods of use - Provided are novel nanostructures comprising hollow nanospheres and nanotubes for use as chemical sensors and molecular specific photothermal coupling agents. The nanostructures can be used in laser-induced phototherapy for treatment of cancer and other disorders. The nanostructures can also be used as a sensor that detects molecules. The nanostructures are of particular use in the fields of clinical diagnosis, clinical therapy, clinical treatment, and clinical evaluation of various diseases and disorders, manufacture of compositions for use in the treatment of various diseases and disorders, for use in molecular biology, structural biology, cell biology, molecular switches, molecular circuits, and molecular computational devices, and the manufacture thereof. The hollow gold nanospheres have a unique combination of spherical shape, small size, and strong, tunable, and narrow surface plasmon resonance absorption covering the entire visible to near IR region. | 10-22-2009 |
20100034739 | Fungus-Specific Imaging Agents - The disclosure relates to an imaging composition including a fungus-specific peptide and an imaging material. Another imaging composition includes a fungus-specific peptide and a chelator able to chelate a radionuclide. The disclosure also provides to a method of detecting a fungal infection. The method includes administering an imaging agent to a patient. The imaging agent comprises a fungus-specific peptide and an imaging material. Then one may detect the imaging agent in the patient. Detecting retained imaging agent in a tissue or organ indicates fungal infection of the tissue or organ. | 02-11-2010 |
20100290997 | Imaging Agents and Methods - The disclosure includes a composition including a poly(L-glutamic acid) and a NIRF dye. It also includes a method including providing to a plurality of cells an imaging agent including poly(L-glutamic acid), a NIRF dye and then imaging the cells to detect the imaging agent. It further includes a dual functional contrast agent including an MRI agent conjugated with an optical imaging agent. A method of detecting cancer is provided including injecting a dual functional contrast agent into a patient and performing both an MRI and an optical scan. The presence of the agent may indicate cancer. A method of detecting cancer by injecting PG-DTPA-Gd-NIR813 into a patient, then detecting the presence or absence of Gd in a cell or tissue of the patient and detecting the presence or absence of NIR813 in a cell or tissue of the patient is provided. The presence of Gd and NIR813 may indicate cancer. | 11-18-2010 |
20110165611 | DUAL MODALITY DETECTION OF APOPTOSIS - To image apoptosis in vivo, small, membrane-permeable probes comprising a caspase 3 substrate, a fluorogenic dye and a radionuclide is provided. This dual-modality probe can be cleaved by caspase upon exposure to apoptotic cells, allowing imaging of caspase 3 and 7 activities using both optical and nuclear imaging techniques. The combined use of these methods provides the opportunity for a direct correlation between in vitro and in vivo biological activities and a viable method to treat disease | 07-07-2011 |
20110318415 | Hollow Gold Nanospheres (HAuNSs) and HAuNSs-Loaded Microspheres Useful in Drug Delivery - A near-infrared mediated drug delivery system comprising a plurality of microspheres made of polymeric material, each sphere containing a plurality of hollow gold nanospheres together with drug product, wherein upon NIR irradiation, the drug product is released from the microsphere. | 12-29-2011 |
20120021050 | NANOPARTICLE FORMULATED GLYCOLIPID ANTIGENS FOR IMMUNOTHERAPY - A composition for stimulating NKT cells to produce anti-cancer and anti-viral cytokines without causing anergy of NKT cells includes a glycolipid antigen and a nanoparticle conjugated with the glycolipid antigen. The glycolipid antigen and the nanoparticle are not antigenic in mouse and human being. The composition can further include covalent or non-covalent connection between the glycolipid antigen and the nanoparticle. The glycolipid antigen is alpha-galactosylceramide or an analog of that. The nanoparticle can be a polymer. A production method of the composition includes preparing a nanoparticle and a glycolipid antigen and loading the glycolipid antigen to the nanoparticle. The glycolipid antigen can be coated onto the surface of the nanoparticle or encapsulated within the nanoparticle. A method of stimulating NKT cells to produce anti-cancer and anti-viral cytokines without causing anergy of NKT cells is also provided. | 01-26-2012 |
20120309691 | TUMOR TARGETED DELIVERY OF IMMUNOMODULATORS BY NANOPOLYMERS - Nanoconstructs having three components: (1) biodegradable nanopolymers and nanoparticles, (2) immunodrugs such as CpG, and a (3) tumor binding device, which are actively targeted to tumor cells such as melanoma cells through receptor-mediated uptake and methods of using the same are described. Antitumor immunity is further enhanced by combination of PG-CpG nanoconstructs with agonists of positive costimulatory signals and inhibitors of negative immune regulatory signals. | 12-06-2012 |
20140296836 | GOLD-IN-SILICON NANOASSEMBLY FOR THERMAL THERAPY AND METHODS OF USE - The present invention provides methods and compositions for the nanotechnology-based therapy of one or more mammalian diseases. Disclosed are gold-in-porous silicon nanoassemblies that are effective in the targeted and localized treatment of one or more human hyperproliferative disorders, including, for example, cancer of the breast. Methods of systemic administration of these nanoassembly vectors are disclosed that facilitate direct thermal ablative therapy of selected tissues using a localized application of near-infrared energy to the target site, wherein the gold-in-porous silicon nanoparticles release heat to destroy the surrounding cancerous tissue. | 10-02-2014 |