The present invention provides a novel method for removal of gadolinium ions from a solution comprising gadolinium complexed with DOTA. The method of the invention is relatively straightforward and cost-efficient compared with known methods.

The present invention provides preparations of MSCs with important therapeutic potential. The MSC cells are non-primary cells with an antigen profile comprising less than about 1.25% CD45+ cells (or less than about 0.75% CD45+), at least about 95% CD105+ cells, and at least about 95% CD166+ cells. Optionally, MSCs of the present preparations are isogenic and can be expanded ex vivo and cryopreserved and thawed, yet maintain a stable and uniform phenotype. Methods are taught here of expanding these MSCs to produce a clinical scale therapeutic preparations and medical uses thereof.

The present disclosure presents nanoparticle compositions for use in the treatment, prevention, or imaging of a disease (e.g., cancer), methods of treating, preventing, or imaging a disease in a subject in need thereof with the nanoparticle compositions, and methods of preparing the nanoparticle compositions of the disclosure. The nanoparticle compositions can include a magnetic nanoparticle ferric chloride, ferrous chloride, or a combination thereof, and a dextran coating functionalized with one or more amine groups.

The present disclosure relates to the field of nanomedicine, in particular for treating cancers. The present disclosure more specifically provides new methods of treating undesirable M2-polarized macrophages and/or inducing M1 macrophage polarization in a subject in need thereof, comprising administering to said subject a therapeutically effective amount of nanoparticles containing metallic elements.

Silica nanocarriers hybridized with superparamagnetic iron oxide nanoparticles (“SPIONs”) and curcumin through equilibrium or enforced adsorption technique. Methods for dual delivery of SPIONs and curcumin to a target for diagnosis or therapy, for example, for SPION-based magnetic resonance imaging or for targeted delivery of curcumin to a cell or tissue. The technique can be extend to co-precipitation of mixed metal oxide involving Ni, Mn, Co and Cu oxide. The calcination temperature can be varied from 500-900° C. The nanocombination is functionalized with chitosan, polyacrylic acid, PLGA or another agent to increase its biocompatibility in vivo.

Systems, methods and related devices used to produce and collect polarized noble gas to inhibit, suppress, detect or filter alkali metal nanoclusters to preserve or increase a polarization level thereof. The systems can include a pre-sat chamber that has an Area Ratio between 20 and 500.

Systems, methods and related devices used to produce and collect polarized noble gas to inhibit, suppress, detect or filter alkali metal nanoclusters to preserve or increase a polarization level thereof. The systems can include a pre-sat chamber that has an Area Ratio between 20 and 500.

Described herein are particles comprising a crystalline matrix and a dopant, wherein one of the atoms of the matrix is .sup.19F and .sup.31P, or .sup.13C, .sup.15N, .sup.29Si, .sup.16O, .sup.17O, .sup.23Na, .sup.39K, .sup.25Mg, .sup.40Ca, .sup.43Ca or deuterium; and the dopant is a compound involved in a biological process in a mammalian organism; and wherein the dopant is present in an amount of between 0.01% and 20% of the plurality of particles, and wherein when the matrix comprises an atom selected from the group of .sup.13C, .sup.15N, .sup.29Si, .sup.16O, .sup.17O, .sup.23Na, .sup.39K, .sup.25Mg, .sup.40Ca, .sup.43Ca and deuterium, and the dopant is isotopically enriched.

Methods of ex vivo labeling of a biological material for in vivo imaging, methods of labeling a biological material in vivo, methods for preparing a labeling agent, and methods for in vivo imaging of a subject using a biological material labeled with a labeling agent are disclosed. In one non-limiting example, the biological material is selected from cells and the labeling agent is a .sup.89Zr-Desferrioxamine-NCS labeling agent.

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.