Abstract: Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Abstract: Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Abstract: Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Abstract: Disclosed herein are compositions and methods for increasing the infrared absorptivity of a therapeutic target. Also disclosed are methods for detecting or ablating a therapeutic target that include providing a nanoparticle composition for increasing the infrared absorptivity of the therapeutic target. Subsequently, the therapeutic target having increased infrared absorptivity is exposed to a therapeutically effective dose of infrared irradiation to effect its detection or ablation. In addition, a method is disclosed for treating a subject suffering from a tumor by providing to the tumor a nanoparticle composition for increasing its infrared absorptivity. The tumor having increased infrared absorptivity is then heated by exposing it to a therapeutically effective dose of infrared irradiation.

Abstract: The present disclosure relates to the product, process, and use of 5 nm Nickel-Nitrilotriacetic acid (Ni-NTA) gold nanoparticles. Applications include diagnostic tests, imaging, therapies, detection technologies, gold conjugation to other molecules, and novel material constructs.

Abstract: The present invention provides methods of using metal nanoparticles 0.5 to 400 nm in diameter to enhance the dose and effectiveness of x-rays or of other kinds of radiation in therapeutic regimes of ablating a target tissue, such as tumor. The metal nanoparticles can be administered intravenously, intra-arterially, or locally to achieve specific loading in and around the target tissue. The metal nanoparticles can also be linked to chemical and/or biochemical moieties which bind specifically to the target tissue. The enhanced radiation methods can also be applied to ablate unwanted tissues or cells ex vivo.

Abstract: The present invention provides compositions, kits, assemblies of articles and methodology for carrying out processes that permit biological enzymes to act directly on metals and metal particles. In particular, the invention concerns using enzymes to selectively deposit metal to the vicinity of a target molecule. The invention also relates to linking of metals to enzyme substrates, control of enzymatic metal deposition and applications of enzymatic metal deposition to sensitively and selectively detect target molecules such as biomarkers in various biological samples, such as chromogenic immunohistochemical (IHC) detection in situ by using microscopy.

Abstract: Described herein are a class of metal oligomers and polymers that contain both metals and organic groups. Said oligomers and polymers have utility in many applications including biomedical imaging, radiation therapy, drug delivery, and in vitro analytical techniques, such as fluorescence and phosphorescence.

Abstract: Described herein are nanoparticles that are coated with a bilayer of molecules formed from surface binding molecules and amphiphatic molecules. The bilayer coating self assembles on the nanoparticles from readily available materials/molecules. The modular design of the bilayer coated nanoparticles provides a means for readily and efficiently optimizing the properties of the bilayer coated nanoparticle compositions. Also described herein are uses of such nanoparticles in medicine, laboratory techniques, industrial and commercial applications.

Abstract: A test agent includes a composite probe having at least one nanoparticle having multiple metal atoms, a directing agent, and an enzyme. The directing agent attaches the probe to a target in a test sample. The test sample and bound probe are then treated with an enzyme substrate. A method of detecting a target in a test sample includes exposing the test sample to the probe, then treating the test sample with an enhancement or development solution to deposit at least one of a fluorophore, a chromogen, or a metal.

Abstract: Disclosed embodiments concern site-specific, enzymatic-directed deposition of elemental metal for in-situ analysis. Enzyme substrates are contacted with metal ions and subsequently direct the deposition of elemental metals. Sensitive and selective detection of target molecules, such as biomarkers in various biological samples, can be obtained using various methods, such as in-situ chromogenic immunohistochemical (IHC) detection with bright field light microscopy.

Abstract: The present invention provides compositions, kits, assembles of articles and methodology for carrying out processes that permit biological enzymes to act directly on metals and metal particles. In particular, the invention relates to use of enzymes to selectively deposit metal to the vicinity of a target molecule. The invention also relates to linking of metals to enzyme substrates, control of enzymatic metal deposition and applications of enzymatic metal deposition to sensitively and selectively detect target molecules such as biomarkers in various biological samples, such as chromogenic immunohistochemical (IHC) detection in situ by using bright field light microscope.

Abstract: The present invention provides methods for the use of enzymes to selectively deposit metal to the vicinity of a target molecule. The invention also relates to applications of enzymatic metal deposition to sensitively and selectively detect target molecules such as biomarkers in various biological samples, such as chromogenic immunohistochemical (IHC) detection in situ by using bright field light microscope.

Abstract: Disclosed are methods and materials for utilizing enzymes to act on metal ions in solution so that the ions are reduced to metal. Additionally disclosed is how to use enzymes to accumulate metal particles. The alteration of metal particles by enzymes interacting with the organic shell of the particles is also described. These methods enable a wide range of applications including sensitive detection of genes and proteins, use as probes for microscopy, nanofabrication, biosensors, and remediation.

Abstract: The present invention provides methods of using metal nanoparticles 0.5 to 400 nm in diameter to enhance the dose and effectiveness of x-rays or of other kinds of radiation in therapeutic regimes of ablating a target tissue, such as tumor. The metal nanoparticles can be administered intravenously, intra-arterially, or locally to achieve specific loading in and around the target tissue. The metal nanoparticles can also be linked to chemical and/or biochemical moieties which bind specifically to the target tissue. The enhanced radiation methods can also be applied to ablate unwanted tissues or cells ex vivo.

Abstract: The present invention provides methods of using metal nanoparticles 0.5 to 400 nm in diameter to enhance the dose and effectiveness of x-rays or of other kinds of radiation in therapeutic regimes of ablating a target tissue, such as tumor. The metal nanoparticles can be administered intravenously, intra-arterially, or locally to achieve specific loading in and around the target tissue. The metal nanoparticles can also be linked to chemical and/or biochemical moieties which bind specifically to the target tissue. The enhanced radiation methods can also be applied to ablate unwanted tissues or cells ex vivo.

Abstract: A test agent includes a composite probe having at least one nanoparticle having multiple metal atoms, a directing agent, and an enzyme. The directing agent attaches the probe to a target in a test sample. The test sample and bound probe are then treated with an enzyme substrate. A method of detecting a target in a test sample includes exposing the test sample to the probe, then treating the test sample with an enhancement or development solution to deposit at least one of a fluorophore, a chromogen, or a metal.

Abstract: Disclosed herein are compositions and methods for increasing the infrared absorptivity of a therapeutic target. Also disclosed are methods for detecting or ablating a therapeutic target that include providing a nanoparticle composition for increasing the infrared absorptivity of the therapeutic target. Subsequently, the therapeutic target having increased infrared absorptivity is exposed to a therapeutically effective dose of infrared irradiation to effect its detection or ablation. In addition, a method is disclosed for treating a subject suffering from a tumor by providing to the tumor a nanoparticle composition for increasing its infrared absorptivity. The tumor having increased infrared absorptivity is then heated by exposing it to a therapeutically effective dose of infrared irradiation.

Abstract: The present invention provides compositions, kits, assembles of articles and methodology for carrying out processes that permit biological enzymes to act directly on metals and metal particles. In particular, the invention relates to use of enzymes to selectively deposit metal to the vicinity of a target molecule. The invention also relates to linking of metals to enzyme substrates, control of enzymatic metal deposition and applications of enzymatic metal deposition to sensitively and selectively detect target molecules such as biomarkers in various biological samples, such as chromogenic immunohistochemical (IHC) detection in situ by using bright field light microscope.

Abstract: The present invention provides methods of using metal nanoparticles 0.5 to 400 nm in diameter to enhance the dose and effectiveness of x-rays or of other kinds of radiation in therapeutic regimes of ablating a target tissue such as tumor. The metal nanoparticles can be administered intravenously, intra-arterially, or locally to achieve specific loading in and around the target tissue. The metal nanoparticles can also be linked to chemical and/or biochemical moieties which bind specifically to the target tissue. The enhanced radiation methods can also be applied to ablate unwanted tissues or cells ex vivo.