The invention relates to a novel use of ultrafine nanoparticles, of use as a diagnostic, therapeutic or theranostic agent, characterized by their mode of administration via the airways. The invention is also directed toward the applications which follow from this novel mode of administration, in particular for imaging the lungs, and the diagnosis or prognosis of pathological pulmonary conditions. In the therapeutic field, the applications envisioned are those of radiosensitizing or radioactive agents for radiotherapy (and optionally curietherapy), or for neutron therapy, or of agents for PDT (photodynamic therapy), in particular for the treatment of lung tumors.

The invention relates to a method for synthesizing ultrasmall silica nanoparticles, useful in particular for diagnostics and/or therapy. More specifically, a method for synthesizing silica nanoparticles, said method comprising the mixing of at least one silane which is negatively charged at physiological pH with at least one silane which is neutral at physiological pH, and/or at least one silane which is positively charged at physiological pH, wherein: —the molar ratio A of neutral silane(s) to negatively charged silane(s) is defined as follows: 0≤A≤6, —the molar ratio B of positively charged silane(s) to negatively charged silane(s) is defined as follows: 0≤B≤5, —the molar ratio C of neutral and positively charged silanes to negatively charged silane(s) is defined as follows: 0<C≤8. The invention also relates to the obtained ultrasmall silica nanoparticles.

Provided herein are nanoparticle compositions (e.g., nanoparticle compositions comprising high atomic number ions) that are useful for imaging diseases in a subject as well as radiosensitizing a disease in a subject (e.g., radiosensitizing a cancer in the subject). Methods of imaging a subject, methods of treating cancer, and processes of preparing the nanoparticle compositions are also provided.

The disclosure provides nanoemulsion compositions and methods of making and using thereof to deliver a bioactive agent such as a nucleic acid to a subject. The nanoemulsion composition comprises a hydrophobic core based on inorganic nanoparticles in a lipid nanoparticle that allows imaging as well as delivering nucleic acids. Methods of using these particles for treatment and vaccination are also provided.

A nanoparticle includes a metal-based core, a first coating layer substantially covering the metal-based core to generate a coated metal-based core, and a second coating layer at least partially covering the coated metal-based core, wherein the metal-based core comprises at least one transition metal, and wherein the metal-based core comprises the at least one transition metal substantially in a state of zero oxidation.

The disclosure provides nanoemulsion compositions and methods of making and using thereof to deliver a bioactive agent such as a nucleic acid to a subject. The nanoemulsion composition comprises a hydrophobic core based on inorganic nanoparticles in a lipid nanoparticle that allows imaging as well as delivering nucleic acids. Methods of using these particles for treatment and vaccination are also provided.

The disclosure provides nanoemulsion compositions and methods of making and using thereof to deliver a bioactive agent such as a nucleic acid to a subject. The nanoemulsion composition comprises a hydrophobic core based on inorganic nanoparticles in a lipid nanoparticle that allows imaging as well as delivering nucleic acids. Methods of using these particles for treatment and vaccination are also provided.

The disclosure provides nanoemulsion compositions and methods of making and using thereof to deliver a bioactive agent such as a nucleic acid to a subject. The nanoemulsion composition comprises a hydrophobic core based on inorganic nanoparticles in a lipid nanoparticle that allows imaging as well as delivering nucleic acids. Methods of using these particles for treatment and vaccination are also provided.

A multimodal PET (positron emission tomography)/MRI (magnetic resonance imaging) contrast agent, a process of synthesizing said PET/MRI contrast agent, and a pharmaceutical formulation comprising said PET/MRI contrast agent are disclosed. The PET/MRI contrast agent comprises a magnetic signal generating core, and a coating portion formed at least partially over a surface of said magnetic signal generating core, wherein the coating portion comprises a plurality of layers, including an inner layer having a functionalized surface, and an outer layer in the form of a radionuclide electrolessly plated layer formed on said functionalized surface.

Nanoparticle-sized magnetic absorption enhancers (MAEs) exhibiting a controlled response to a magnetic field, including a controlled mechanical response and an inductive thermal response. The MAEs have a magnetic material that exhibits inductive thermal response to the magnetic field and is embedded in a coating, such that the MAE conforms to a particular shape, e.g., hemisphere, dome or shell, chosen to produce the controlled mechanical response. A targeting moiety for specifically binding the MAE to a pathogen target is also provided. The MAEs can be bound by a flexible linker to promote the desired mechanical response, which includes interactions between MAEs that are not bound to any pathogen target for the purpose of forming spheres, spherical shells, or generally spherical dimers to contain the thermal energy produced and to thus reduce collateral healthy tissue damage during hyperthermic treatment.