Described herein are apparati and methods for growing cells in a manner that mimics the native three-dimensional environment. Cell cultures grown in the apparatus can be screened for inhibition by specific chemotherapeutics or other drugs.

The present invention provides compositions and methods for targeting cells for therapeutic and/or diagnostic purposes, e.g., delivery of therapeutic and/or diagnostic agents to a cell. Nanoparticles and polymers functionalized with capture molecules, reporter molecules, and/or therapeutic agents are provided for the treatment or prevention of disease, including neurological diseases associated with neuroinflammation, and cancer.

The present invention generally relates to yeast cell wall microparticles loaded with nanoparticles for receptor-targeted nanoparticle delivery. In particular, the present invention relates to trapping nanoparticles either on the surface or inside a yeast glucan particles, for example, yeast glucal particles. The present invention further relates to methods of making the yeast cell wall particles loaded with nanoparticles. The present invention also relates to methods of using the yeast cell wall particles loaded with nanoparticles for receptor-targeted delivery of the nanoparticles, e.g., drug containing nanoparticles.

A method for detecting metal ions and chemical/biochemical molecules is provided. The method includes providing a probe, wherein the probe includes: a gold nanocluster; a reducing agent and a chelating agent partially capped on a surface of the gold nanocluster, wherein the probe is formed of reducing gold ions by the reducing agent, and the gold ions and the reducing agent have a molar ratio of 1:0.7 to 1:1.9. The probe may interact with several metal ions of an aqueous solution to produce different changes of fluorescent spectra. Chemical/biochemical molecules can be detected by the fluorescent spectra difference caused by the interaction between the metal ions and the chemical/biochemical molecules.

Described herein are fluid-manipulation-based devices. Fluid manipulations as described herein can be configured to perform assays on biological samples. In an embodiment, the device includes a reaction chamber, which can includes an integrated sample isolation module, a cell lysis module, a biological target purification module, and an assay mixing module, which can include a microbead with a capture molecule coupled thereto and a nanoparticle having a probe molecule coupled thereto via a label, which can be a spectroscopic label. In an embodiment, the capture and probe molecules can be configured to be coupled together via a biological target to form a biological molecule bead complex. Devices and methods as described herein can manipulate and analyze nanoliter volumes of fluid, microliter volumes of fluid, milliliter volumes of fluid, or greater. Embodiments of the present disclosure can enable random biological assays and rapid, simultaneous analysis of multiple biological samples.

Disclosed herein are antibody-nanoparticle conjugates that include two or more nanoparticles (such as gold, palladium, platinum, silver, copper, nickel, cobalt, iridium, or an alloy of two or more thereof) directly linked to an antibody or fragment thereof through a metal-thiol bond. Methods of making the antibody-nanoparticle conjugates disclosed herein include reacting an arylphosphine-nanoparticle composite with a reduced antibody to produce an antibody-nanoparticle conjugate. Also disclosed herein are methods for detecting a target molecule in a sample that include using an antibody-nanoparticle conjugate (such as the antibody-nanoparticle conjugates described herein) and kits for detecting target molecules utilizing the methods disclosed herein.

Gold nanoparticles functionalized with thiolated, bidentate Schiff base ligands. The Schiff base ligands form a ligand monolayer surrounding and binding to the surface of a gold nanoparticle core through AuS linkages. The functionalized gold nanoparticle composites have a spherical shape, an average diameter of 7-15 nm and a narrow particle size distribution. Methods of assessing these functionalized gold nanoparticle composites as fluorescent probes in Fe(III) chemosensing applications, methods of preparing the functionalized gold nanoparticle composites and methods of detecting Fe(III) ions with the same are also provided.

This invention relates to methods for diagnosing cancer, e.g., cancer of epithelial origin, by detecting the presence of tumor cells in a sample, based (at least in some embodiments) on the quantification of levels of four biomarkers, MUC1, EGFR, EpCAM, and HER2. In some embodiments, the methods are performed using diagnostic magnetic resonance (DMR), e.g., with a portable relaxometer or MR imager.

A fiber fluidic system may be used to produce particles (e.g., NPs and/or microparticles). The fiber fluidic system may include a cylinder with a plurality of elongated fibers oriented along a length of the cylinder. The cylinder may have a first opening at or near a first end of the cylinder and a second opening downstream of the first opening. A constrained phase fluid may be provided through the first opening and a free phase fluid may be provided through the second opening to produce particles (e.g., NPs and/or microparticles) through a second end of the cylinder. The fiber fluidic system may be used to continuously produce the particles at high throughput.

A detection method for a specific biological substance uses, as a color former, fluorescent substance-encapsulated nanoparticles which have biological substance-recognizing molecules. The biological substance-recognizing molecules specifically recognize a specific biological substance. The biological substance-recognizing molecules are bonded to the surface of the nanoparticles. Nanoparticles encapsulating no fluorescent substance are used as a blocking agent for preventing the fluorescent substance-encapsulated nanoparticles from being non-specifically adsorbed on a biological substance other than the specific biological substance.