The disclosure relates to nanoparticle drug conjugates (NDC) that comprise ultrasmall nanoparticles, folate receptor (FR) targeting ligands, and linker-drug conjugates, and methods of making and using them to treat cancer.

A tracer detection device includes an enclosed body, and a plurality of tracer sensors, a battery, a memory, and a transmitter, each disposed within the enclosed body. The plurality of tracer sensors is configured to detect measurement values at a surface and underneath the surface of a gastrointestinal tract. The battery is configured to power the plurality of tracer sensors. The memory is configured to receive measurement values detected by the plurality of tracer sensors. The transmitter is configured to transmit measurement values detected by the plurality of tracer sensors to an external device after the enclosed body has passed through the gastrointestinal tract. The enclosed body includes a steering feature that ensures the enclosed body is oriented in an intended direction. The plurality of tracer sensors triggers release of a drug. The plurality of tracer sensors estimate distances to gastrointestinal walls for normalizing signals.

Provided are targeted nanoparticles. In certain embodiments, the targeted nanoparticles comprise a nanoparticle and a myeloid cell (MC) targeting moiety stably associated with the outer surface of the nanoparticle. According to some embodiments, the MC targeting moiety is an immunosuppressive myeloid cell (isMC) targeting moiety. In certain embodiments, the targeted nanoparticles further comprise a detectable label (e.g., an in vivo imaging agent), a drug, or both. Also provided are compositions comprising the targeted nanoparticles of the present disclosure. Methods of using the targeted nanoparticles to image MCs (e.g., isMCs) and/or to modulate and/or disrupt MCs (e.g., isMCs) are also provided.

In one aspect, methods of targeted nanoparticles and cell delivery are described herein. In some embodiments methods described herein comprise coupling nanoparticles and cells to a carrier cell to form a nanoparticle-cell conjugate or cell-cell conjugate, disposing the nanoparticle-cell or cell-cell conjugate in a biological environment, and delivering the nanoparticles and cells to target cells or tissues located within the biological environment. The nanoparticles comprise a biodegradable photoluminescent polymer, and the nanoparticle-cell conjugate is formed using one or more click chemistry reaction products.

Gas vesicles, protein variants and related compositions methods and systems for singleplexed and/or multiplexed ultrasound imaging of a target site in which a gas vesicle provides contrast for the imaging which is modifiable by application of a selectable acoustic collapse pressure value of the gas vesicle.

The invention relates to novel biocompatible hybrid nanoparticles of very small size, useful in particular for diagnostics and/or therapy. The purpose of the invention is to offer novel nanoparticles which are useful in particular as contrast agents in imaging (e.g. MRI) and/or in other diagnostic techniques and/or as therapeutic agents, which give better performance than the known nanoparticles of the same type and which combine both a small size (for example less than 20 nm) and a high loading with metals (e.g. rare earths), in particular so as to have, in imaging (e.g. MRI), strong intensification and a correct response (increased relaxivity) at high frequencies. Thus, the nanoparticles according to the invention, with diameter d.sub.1 between 1 and 20 nm, each comprise a polyorganosiloxane (POS) matrix including gadolinium cations optionally associated with doping cations; a chelating graft C.sup.1 DTPABA (diethylenetriaminepentaacetic acid bisanhydride) bound to the POS matrix by an —Si—C— covalent bond, and present in sufficient quantity to be able to complex all the gadolinium cations; and optionally another functionalizing graft Gf* bound to the POS matrix by an —Si—C— covalent bond (where Gf* can be derived from a hydrophilic compound (PEG); from a compound having an active ingredient PA1; from a targeting compound; from a luminescent compound (fluorescein). The method for the production of these nanoparticles and the applications thereof in imaging and in therapy also form part of the invention.

A particulate material comprising porous polymeric particles is described. The porous polymeric particles have an average pore diameter of from 2 to 50 nm and a volume mean particle diameter D[4,3] of less than 100 μm. The material is obtained or obtainable by spray-drying a polymer solution. The particles find use as a solubility-enhancing carrier for active pharmaceutical compounds. Methods of manufacturing the particulate material and pharmaceutical compositions including the particulate material loaded with one or more active pharmaceutical compounds are also described.

Described herein are peptides, compositions, and methods for diagnosing, detecting, imaging, monitoring, preventing, treating, or ameliorating diseases or disorders including cancer, inflammatory disorder, and autoimmune disease.

The present invention relates to providing fluorescent silica nanoparticles having high luminance even when many fluorescent dyes are contained in silica particles. Fluorescent silica nanoparticles according to the present invention is fluorescent silica nanoparticles including silica nanoparticles and fluorescent dyes contained in the silica nanoparticles, in which a total volume of the fluorescent dyes is 5% or more with respect to a total volume of the fluorescent silica nanoparticles, and an emission quantum yield of the fluorescent silica nanoparticles is 10% or more.

An upconversion single molecule probe is provided that includes a core having a nanoparticle seed crystal, where the nanoparticle seed crystal is an upconversion seed crystal, a first shell enveloping the core, and a second shell enveloping the first shell.