The invention relates to liposomes containing nanoparticles, wherein the nanoparticles are selected from magnetic, zparamagnetic, superparamagnetic and/or fluorescent and/or functionalized nanoparticles, and the liposomal sleeve contains lipid-derivatized bisphosphonic acid. The liposomes are suitable for preparing a solution for the diagnosis of pathological tissue degeneration or conversion processes on the bone and in the bone marrow, in particular for the treatment and diagnosis of bone tumors and bone metastases and disorders in the bone marrow (proliferative diseases of the blood-producing and lymphoreticular system).

The present disclosure relates to a process for the preparation of core-shell particles by the coacervation method encapsulating contrast agents for multimodal imaging. The process consists in: a. Providing a water in oil emulsion of a biocompatible polyelectrolyte polymer. b. Providing an aqueous solution of a biocompatible polyelectrolyte polymer having opposite charges of the polyelectrolyte of step a). c. Adding a crosslinking agent to the primary emulsion and the secondary solution. d. Adding at least a tracer independently to the primary emulsion or the secondary solution or emulsion. e. Adding the secondary aqueous solution to the primary emulsions and occurring of the complex coacervation leading to the separation of the coacervate particles. f. Optionally absorb a further tracer into the nanoparticles The disclosure also relates to the coacervates obtained by the above described process and their use as probe for multimodal imaging in the diagnostic field.

Disclosed herein is a composition comprising a plurality of liposomes having an average diameter of less than 400 nanometers, wherein the plurality of liposomes comprise: a first lipid or phospholipid; a second lipid or phospholipid which is derivatized with a polymer; and a sterically bulky excipient capable of stabilizing the liposomes; a third lipid or phospholipid derivatized with a polymer terminated with an integrin targeting component; DSPE or a fourth lipid or phospholipid derivatized with a group binding a contrast enhancing agent wherein the plurality of liposomes optionally encapsulates a payload component consisting of one or more bioactive agents.

Pain factors are labeled with targeted agents or markers delivered into the body. The labeled pain factors are imaged with appropriate imaging tools in a manner allowing selective identification and localization of areas of pain source or transmission. The labeled pain factors allow spatial differentiation in the imaging sufficient to specify the location of the pain so as to drive therapeutic decisions and techniques in order to treat the pain. Pain factors labeled and imaged in this manner may include one or more of nerve factors, blood vessel factors, cellular factors, and inflammation factors. Labeled markers may include for example radioactive materials (e.g. tritiated or iodinated molecules) or other materials such as metal (e.g. gold) nanoparticles. Intermediary binding materials may be used, such as for example bi-specific antibodies. Therapeutic components of the system and method include for example localized energy delivery or ablation treatments, or local drug or other chemical delivery. Locations containing pain factor selectively bound by targeted agents are selectively treated with directed energy into a region containing the targeted agent bound to the pain factor.

Disclosed are methods, compositions of matter, and protocols useful for the detection of altered cells in a patient. Immune cells capable of clonal expansion are engineered to produce a soluble signal upon activation and/or clonal expansion. The cells may possess a suicide gene, inducible upon administration pharmacological or light/radiation activatable, so as to eliminate the cells from body when desired. In another embodiment, immune cells produce a localized marker, the marker being visible with imaging technology. In other embodiments cells capable of non-clonal expansion are utilized. The disclosure provides means of utilizing the immunosurveillance properties of immune cells to diagnose and localize diseases associated with alteration of host cells.

Disclosed is a tumor-specific antibody and fluorophore conjugate for detecting, localizing and imaging of various tumors. Also disclosed are methods for detecting, localizing and imaging a solid tumor before or during a tumor resection surgery using the antibody-fluorophore conjugate.

Aspects of the disclosure provide compositions and methods for treating cancer characterized by surface expression of plectin-1. In some embodiments, the disclosure provides anti-plectin-1 antibodies. In some embodiments, the anti-plectin-1 antibodies are conjugated to a targeted moiety (e.g., a therapeutic moiety or a detectable label).

An improved method for diagnosing and characterizing peripheral nerve lesions to permit early identification and characterization of peripheral nerve injuries that will require surgical intervention.

A nanotherapeutic supported by a hierarchical silica composite with dual imaging capability (e.g. fluorescence and magnetic resonance imaging), a method of preparing the nanotherapeutic, and a method of treating cancer. Also disclosed is a method of oxidatively dehydrogenating ethane using a catalytic system supported by a hierarchical silica composite.

A chelating compound of formula (I) or a pharmaceutically acceptable salt thereof and its complexes with metals or radioisotopes thereof. The invention further relates to the preparation of such ligand and complexes as well as to their use as diagnostic or therapeutic agents.

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