Hydrogel nanoparticles and microparticles are prepared by a water-in-oil method from natural polymers that are water miscible, a hydrophobic polyol and a crosslinking agent. The hydrogel nanoparticles are auto fluorescent and can be used for imaging of cells and a biological entity. The hydrogel nanoparticles and microparticles can include magnetic nanoparticles and carry desired bioactive entities. The hydrogel nanoparticles and microparticles are useful for diagnostics and as therapeutics purposes including drug delivery, imaging of drug migration, and selectivity by the tagging or binding of the hydrogel nanoparticles and microparticles with appropriate antibodies or antigens.

Novel compounds carrying ligands capable of binding to counter receptors on relevant target cells are disclosed. The compounds possess a number of advantageous features, rendering them very suitable for a wide range of applications, including use as detection systems, detection of relevant target cells as well as a number of other methods. In particular, novel MHC complexes comprising one or more MHC molecules are disclosed. The affinity and specificity of the MHC-peptide complexes are surprisingly high. The possibility of presenting to the target cells a plurality of MHC-peptide complexes makes the MHC complexes according to the present invention an extremely powerful tool e.g. in the field of therapy and diagnosis. The invention generally relates to the field of therapy, including therapeutic methods and therapeutic compositions. Also comprised by the present invention is the sample-mounted use of MHC complexes and MHC multimers.

The present invention relates to reverse-micellar systems comprising at least an active agent, an acylglycerol, a sterol, lecithin, ethanol and water, for use in chelation and/or sequestering of a radionuclide and/or a metal in a patient. The invention also relates to the reverse-micellar systems and to pharmaceutical compositions comprising said reverse-micellar systems.

The disclosure provide hollow nanospheres and methods of making and using the same. The methods and compositions of the disclosure are useful for drug delivery and gene transfer.

An electromagnetic device, such as an actuator for electrovalves or injectors, particularly for endothermal engines includes a coil winding of an electric wire covered with an insulating layer made of overmoulded plastic material. In order to prevent the electric wire from breaking at the ends thereof connected to the electric terminals, a protective insert is applied prior to the plastic moulding step. The insert is also made of thermoplastic material, so that it can melt locally together with the cover material, thereby ensuring a stable and effective union during the moulding process. The invention also relates to a process for manufacturing the device.

Boron-doped graphene quantum dots, methods for making the boron-doped graphene quantum dots, and methods for magnetic resonance imaging using the boron-doped graphene quantum dots.

The present disclosure, among other things, provides a composition including a nanoscale core; a plurality of capping agent entities associated on the core; an outer encapsulant layer; and a plurality of dopant entities distributed at locations selected from the group consisting of: on or within the nanoscale core, on or between capping agent entities, on or within the encapsulating layer, and combinations thereof. Provided technologies can achieve unprecedented levels of dopant entity density and/or surface localization, which, for a SE(R)RS-active agent dopant, results in dramatically improved signal intensity and/or imaging sensitivity.

A biocompatible curable composition and a method of detecting a border of a tumor, a tissue of interest, or both including injecting the biocompatible curable composition and contacting the border of a tumor or a tissue, the biocompatible curable composition crosslinks to form a three-dimensional cured nanocomposite, and imaging the three-dimensional (3D) cured nanocomposite, and imaging the 3D cured nanocomposite by at least one of MRI, CT, ultrasound, and X-ray, to detect the border of the tumor or the tissue of interest or track tumor motion during radiotherapy treatment. The biocompatible curable composition comprising an organic polymer having a hydrolysable functional group, a metallic nanoparticle, and a polar or a non-polar solvent. A brachytherapy strand consisting of a biocompatible curable composition and a radio-isotope seed. The biocompatible curable composition is shaped into an elongated cylinder and forms a 3D cured nanocomposite with a radio-isotope seed embedded.

A method has been invented for intravenously inserting a tumor reduction radiation emitter into the body of a patient suffering from a cancerous tumor. The emitter is very small, yet detectable by medical imaging techniques and guidable by use of magnetism. The emitter is guided through the body by use of a magnet until it is adjacent or in in the tumor itself. The emitter can be oriented in various desired directions by the magnet. The emitter is then wirelessly powered by electrical induction, causing the radiation of a desired wavelength to be directed to tumor cells, causing tumor reduction.

The present disclosure provides a method for the treatment or prevention of Chemotherapy-Induced Peripheral Neuropathy (CIPN) in a cancer patient treated with, or to be treated with, a CIPN causing chemotherapeutic agent, the method comprising: administering a therapeutically effective amount of a composition containing a peptide amphiphile lipid micelle (PALM) nanoparticle to the cancer patient, the PALM nanoparticle comprising a PALM containing the CIPN causing chemotherapeutic agent, and wherein the PALM comprises a peptide, and a lipid component comprising sphingomyelin and one or more additional phospholipids.