Abstract: The disclosure relates polyoxometalate complexes and uses in the management, treatment, or prevention of cancer. In certain embodiments, the polyoxometalate complexes comprise polydentate oxygen bridging ligands such as those of the following formula: [POM{(OCH2)3CX}2], [M6O13{(OCH2)3CX}2], [V6O13{(OCH2)3CX}2], salts, or derivatives thereof wherein POM is a polyoxometalate, M is a metal, and X is defined herein. In certain embodiments, the disclosure relates to pharmaceutical compositions comprising polyoxometalate complexes disclosed herein.

Abstract: The disclosure relates polyoxometalate complexes and uses in the management, treatment, or prevention of cancer. In certain embodiments, the polyoxometalate complexes comprise polydentate oxygen bridging ligands such as those of the following formula: [POM{(OCH2)3CX}2], [M6O13{(OCH2)3CX}2], [V6O13 {(OCH2)3CX}2], salts, or derivatives thereof wherein POM is a polyoxometalate, M is a metal, and X is defined herein. In certain embodiments, the disclosure relates to pharmaceutical compositions comprising polyoxometalate complexes disclosed herein.

Abstract: The disclosure relates polyoxometalate complexes and uses in the management, treatment, or prevention of cancer. In certain embodiments, the polyoxometalate complexes comprise polydentate oxygen bridging ligands such as those of the following formula: [POM{(OCH2)3CX}2], [M6O13{(OCH2)3CX}2], [V6O13{(OCH2)3CX}2], salts, or derivatives thereof wherein POM is a polyoxometalate, M is a metal, and X is defined herein. In certain embodiments, the disclosure relates to pharmaceutical compositions comprising polyoxometalate complexes disclosed herein.

Abstract: This disclosure relates to methods of detecting and quantifying low concentrations of cells in a sample with targeted nanoparticles having Raman reporters using surface-enhanced Raman scattering for detection. In certain embodiments, the sample is a group of cells derived from stem cells that have been differentiated into specific cell types and one is detecting residual stem cells or other progeny in order to quantify the purity of the sample. In certain embodiments, the targeted nanoparticles contain two or more Raman reporters for the purpose of multiplexing. In certain embodiments, purity measurements are used to make quality control determinations.

Abstract: Nanostructures, methods of preparing nanostructures, methods of detecting targets in subjects, and methods of treating diseases in subjects, are disclosed. An embodiment, among others, of the nanostructure includes a metallic gold surface-enhanced Raman scattering nanoparticle, a Raman reporter and a protection structure. The protection structure may include a thiol-polyethylene glycol to which may be attached a target-specific probe.

Abstract: This disclosure relates to methods of detecting and quantifying low concentrations of cells in a sample with targeted nanoparticles having Raman reporters using surface-enhanced Raman scattering for detection. In certain embodiments, the sample is a group of cells derived from stem cells that have been differentiated into specific cell types and one is detecting residual stem cells or other progeny in order to quantify the purity of the sample. In certain embodiments, the targeted nanoparticles contain two or more Raman reporters for the purpose of multiplexing. In certain embodiments, purity measurements are used to make quality control determinations.

Abstract: According to one aspect, a system for intraoperatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In one embodiment, the system includes: a first light source configured to emit a beam of visible light; second light source configured to emit a beam of near-infrared light; a handheld probe optically coupled to the second light source; a second imaging device configured to detect visible light; a third imaging device configured to detect near-infrared light having a first predetermined wavelength; a fourth imaging device configured to detect near-infrared light having a second predetermined wavelength; a display for displaying at least one visual representation of data; and, a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.

Abstract: In certain embodiments, this disclosure relates to nanoparticles for drug-delivery of cytotoxic anti-cancer compounds. In certain embodiments, the nanoparticle comprises a maytansinoid and an acetalated polysaccharide-polyethylene glycol conjugate. This disclosure also relates to methods for treatment of infection and cancer are also claimed, wherein a cytotoxic compound is en capsulated in a nanoparticle is degraded at the intended target, but otherwise stable, releasing the cytotoxic compound. Compositions comprising the nanoparticles and cytotoxic drugs are also considered.

Abstract: A system and method for intra-operatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In embodiments, the system includes multiple light sources configured to emit different frequencies, multiple electronic imaging devices to detect various frequencies of reflected, emitted, or scattered light. The system and method incorporate an optical probe is integral to an endoscopic device or a therapeutic laser system, optically coupled to a light source; a display for displaying at least one visual representation of data; and a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.

Abstract: The disclosure relates to lattice-mismatched core-shell quantum dots (QDs). In certain embodiments, the lattice-mismatched core-shell QDs are used in methods for photovoltaic or photoconduction applications. They are also useful for multicolor molecular, cellular, and in vivo imaging.

Abstract: Embodiments of the present disclosure provide: methods of making a quantum dot, quantum dots, and the like.

Abstract: A nanostructure and methods of synthesizing same. In one embodiment, the nanostructure includes a magnetic iron oxide nanoparticle, a hydrophobic protection structure including at least an amphiphilic copolymer, wherein the hydrophobic protection structure encapsulates the magnetic iron oxide nanoparticle, and at least one amino-terminal fragment (ATF) peptide or epidermal growth factor receptor (EGFR) antibody conjugated to the amphiphilic copolymer.

Abstract: The disclosure relates to devices, systems and methods that address the variability in immunohistochemistry (IHC) tests that can lead to inaccurate diagnosis or misdiagnosis while maintaining important structural information within the specimen. The devices may include a control region having a control unit including a plurality of substantially homogenous samples and a biological sample region.

Abstract: According to one aspect, a system for intraoperatively providing anatomical guidance in a diagnostic or therapeutic procedure is disclosed. In one embodiment, the system includes: a first light source configured to emit a beam of visible light; second light source configured to emit a beam of near-infrared light; a handheld probe optically coupled to the second light source; a second imaging device configured to detect visible light; a third imaging device configured to detect near-infrared light having a first predetermined wavelength; a fourth imaging device configured to detect near-infrared light having a second predetermined wavelength; a display for displaying at least one visual representation of data; and, a controller programmed to generate at least one real-time integrated visual representation of an area of interest and to display the real-time visual representation on the display for guidance during the diagnostic or therapeutic procedure.

Abstract: The present disclosure provides embodiments of a new class of hydroxylated quantum dots. The quantum dots have a hydroxylated coat disposed thereon, and which serves to minimize non-specific cellular binding and to maintain the small size of quantum dot probes. Embodiments of the coated quantum dots of the disclosure are just slightly larger than the diameter of uncoated quantum dots, and are bright with high quantum yields. They are also very stable under both basic and acidic conditions. Embodiments of the hydroxylated quantum dots result in significant reductions in non-specific binding relative to that of carboxylated dots, and to protein and PEG-coated dots. Embodiments of the disclosure are advantageous in a range of biological applications where non-specific binding is a major problem, such as in multiplexed biomarker staining in cells and tissues, detection of biomarkers in body fluid samples (blood, urine, etc.), as well as live cell imaging.

Abstract: The present disclosure provides a method for identifying rare or low-abundant biological entities such as Hodgkin's and Reed-Sternberg cells, circulating tumor cells in peripheral blood, circulating fetal cells, stem cells, somatic cells, HIV-infected T cells, bacteria or viruses in water, adenoviruses, enteroviruses, hepatitis A and E, dengue, Swine Flu, bovine diarrhea, and protozpa/helminthes. The method uses a suite of nanoparticle-conjugated agents to mark biological targets of interest for subsequent fluorescence imaging. In certain embodiments, the nanoparticle-conjugated agents are fluorescent semiconductor nanocrystals conjugated with antibodies with affinity for CD15, CD30, CD45, and Pax5. In certain embodiments, a method is developed to differentiate Hodgkin's and Reed-Sternberg (HRS) cells from amongst surrounding immune cells such as T and B lymphocytes with greater specificity and precision than traditional immunohistochemistry (IHC) for the diagnosis of Hodgkin's lymphoma.

Abstract: This disclosure relates to methods and compositions for treating cancer with platinum particles. In certain embodiments, the disclosure relates to platinum particle coated with a polysaccharide, such as a heparin or modified heparin, conjugated to a polypeptide that has affinity for a cell surface cancer marker and uses related thereto.

Abstract: An alloyed semiconductor quantum dot comprising an alloy of at least two semiconductors, wherein the quantum dot has a homogeneous composition and is characterized by a band gap energy that is non-linearly related to the molar ratio of the at least two semiconductors; a series of alloyed semiconductor quantum dots related thereto; a concentration-gradient quantum dot comprising an alloy of a first semiconductor and a second semiconductor, wherein the concentration of the first semiconductor gradually increases from the core of the quantum dot to the surface of the quantum dot and the concentration of the second semiconductor gradually decreases from the core of the quantum dot to the surface of the quantum dot; a series of concentration-gradient quantum dots related thereto; in vitro and in vivo methods of use; and methods of producing the alloyed semiconductor and concentration-gradient quantum dots and the series of quantum dots related thereto.

Abstract: A nanostructure and methods of synthesizing same. In one embodiment, the nanostructure includes a nanospecies, a hydrophobic protection structure including at least one compound selected from a capping ligand, an amphiphilic copolymer, and combinations thereof, wherein the hydrophobic protection structure encapsulates the nanospecies, and at least one histidine-tagged peptide or protein conjugated to the hydrophobic protection structure, wherein the at least one histidine-tagged peptide or protein has at least one binding site.

Abstract: The disclosure relates to lattice-mismatched core-shell quantum dots (QDs). In certain embodiments, the lattice-mismatched core-shell QDs are used in methods for photovoltaic or photoconduction applications. They are also useful for multicolor molecular, cellular, and in vivo imaging.