Described herein are nanoparticle compositions that can be used to target specific regions of the blood brain barrier (BBB). Such nanoparticle compositions can be used to deliver therapeutics to or across the BBB or to image the BBB or the permeability thereof.

Modified viruses and methods for preparing the modified viruses are provided. Vaccines that contain the viruses are provided. The viruses can be used in methods of treatment of diseases, such as proliferative and inflammatory disorders, including cancer, and as anti-tumor and/or antiangiogenic agents. The viruses also can be used in diagnostic methods.

Polyvalent nanoconjugates address the critical challenges in therapeutic use. The single-entity, targeted therapeutic is able to cross the blood-brain barrier (BBB) and is thus effective in the treatment of central nervous system (CNS) disorders. Further, despite the tremendously high cellular uptake of nanoconjugates, they exhibit no toxicity in the cell types tested thus far. This property is critical for therapeutic agent delivery applications for reducing off-target effects.

The present invention provides nanoparticles including a metallic core having a length along each axis of from 1 to 100 nanometers and a coating disposed on at least part of the surface of the metallic core, wherein the coating comprises polydopamine, along with methods for making and using such nanoparticles. The metallic core may be gold, silver or iron oxide and the polydopamine coating may have other substances bound to it, such as silver, targeting ligands or antibodies, or other therapeutic or imaging contrast agents. The disclosed nanoparticles can be targeted to cells for treating cancer or bacterial infections, and for use in diagnostic imaging.

A vaginal preparation for the diagnosis of human female uterotubal patency and function, comprising particles having a nucleus absorbable by the tissues of the human body, and a coating for the nucleus which is dissolvable and non-absorbable by the tissues of the human body, inert and innocuous, the nucleus comprising at least one marker that can be released by the human body through an organic fluid, the coating being dissolvable and sensitive, for the purpose of the dissolution thereof, to time and/or changes in pH and/or temperature and/or another chemical/physical parameter along the route from the vaginal area to the tubal and pelvic area, the particles having a size, weight and ovoid shape corresponding approximately to those of spermatozoa.

The invention relates to a conjugate which comprises an MRI contrast agent component comprising a nanoparticle, which nanoparticle comprises a metal or a metal compound, and a hypoxia targeting moiety which is conjugated to the MRI contrast agent component, especially wherein said nanoparticle comprises iron oxide and a biocompatible coating and wherein said hypoxia targeting moiety is a nitroimidazole. Also provided is the use of a said conjugate in a method of imaging a subject, a method of de-testing hypoxia, and a method of evaluating the activity of a pharmaceutical. Said conjugate is also of use in diagnosis.

Disclosed herein are complexes of gadolinium metal, ligand and meglumine that are substantially free of non-aqueous solvents. In particular, solvent-free complexes of 1) gadopentetate dimeglumine and 2) gadoterate meglumine are disclosed and methods of their preparation are disclosed. In addition, methods are disclosed for purifying reactants, monitoring and controlling pH, quantifying the free gadolinium content, quantifying the concentration of gadolinium-ligand complex in aqueous solution, and procedures for producing a drug product in one step. The one step process eliminates the need to dry the gadolinium-ligand complex, which is typically highly hygroscopic. The one step process includes purification steps that do not require the use of non-aqueous solvents.

The invention provides a (drug-containing) lipid nanoparticle with: (i) at least one phospholipid; (ii) at least one lysolipid; and (iii) at least one phospholipid comprising a hydrophilic polymer; and (iv) at least one structural lipid of formula (I) which has the following general structure:

##STR00001## wherein R and R are long hydrocarbyl hydrophobic chains, Y is a linker element, and PHG is a polar head group described as large according to its van der Waals radius, and which is different from the phospholipid (i).

The lipid nanoparticle can release a drug (or API) from within the lipid nanoparticle as a result of focused ultrasound (FUS) applied continuously, at least twice, to a desired part of the body to induce hyperthermia (an increase in temperature). FUS is applied after the lipid nanoparticle containing the drug has been administered to the live subject, and causes controlled release of the drug at the desired site of the body. Ultrasound is then halted, and the site of interest allowed to cool. Ultrasound is then applied again. Lipid nanoparticles can be labelled (for MRI, NIRF imaging), enabling real time monitoring of the drug in the human body. Imaging information can be used to direct and guide the nature of the FUS applied to the site of interest.

Provided are a hydrophilic particle, a method for manufacturing the same, and a contrasting agent using the same. More specifically, the hydrophilic particle according to the inventive concept may include a hydrophobic particle, and an amphiphilic organic dye directly absorbed on a surface of the hydrophobic particle. In this case, the hydrophobic particle includes a center particle, and a hydrophobic ligand covering a surface of the center particle, and the amphiphilic organic dye may be combined to the hydrophobic ligand by a hydrophobic interaction. The hydrophilic particle may have a surface zeta potential lower than a surface zeta potential of the amphiphilic organic dye.

The present invention can provide a method of determining the presence, location, quantity, or a combination thereof, of a biological substance, comprising: (a) exposing a sample to a plurality of targeted nanoparticles, where each targeted nanoparticle comprises a paramagnetic nanoparticle conjugated with one or more targeting agents that preferentially bind with the biological substance, under conditions that facilitate binding of the targeting agent to at least one of the one or more biological substances; (b) subjecting the sample to a magnetic field of sufficient strength to induce magnetization of the nanoparticles; (c) measuring a magnetic field of the sample after decreasing the magnetic field applied in step b below a threshold; (d) determining the presence, location, quantity, or a combination thereof, of the one or more biologic substances from the magnetic field measured in step (c).