A new approach to targeting imaging agents to macrophage-rich sites of interest is disclosed. Compositions of the invention are rHDL and HDL-like liposomal compositions, protein constituents of which, apolipoproteins A-I and/or A-II or fragments thereof are used not only as structural but also as targeting agents. This is achieved by certain controlled chemical or enzymatic modification of apolipoproteins A-I or A-II or fragments thereof. Such modification converts these apolipoproteins to substrates for macrophage scavenger receptors and results in the improvement of contrast agent-(HDL/modified apolipoprotein)-particle association with macrophages and/or absorption (uptake) by macrophages when compared to that of the contrast agent-(HDL/apolipoprotein)-particle constructed with non-modified naturally occurring apo A-I. The compositions can be used for noninvasive specific in vivo molecular detection and localization of macrophage-rich sites of interest using imaging techniques such as computed tomography (CT), gamma-scintigraphy, positron emission tomography (PET), single photon emission computed tomography (SPECT), magnetic resonance imaging (MRI).

The present invention relates to new molecular design that allows micelles to report their activation and disassembly by an enzymatic trigger. The molecular design is based on introduction of a labeling moiety selected from a fluorescent dye, a dark quencher, combinations of dyes or dyes/quenchers, and a fluorinated moiety (a .sup.19F-magenetic resonance (MR) probe for turn ON/OFF of a .sup.19F-MR signal) through covalent binding to the focal point of amphiphilic polymer-dendron hybrids with the labeling moiety. At the assembled micellar state, the dyes are closely packed and hence the probability for intermolecular interactions increases significantly, leading to alteration of the fluorescent properties (signal quench or shift) or the .sup.19F-MR signal (OFF state) of the micelles. Upon enzymatic cleavage of the hydrophobic end-groups from enzyme-responsive dendron, the polymers become hydrophilic and disassemble. This structural change is then translated into a spectral change as dye-dye interactions are halted and the dyes regain their intrinsic fluorescent properties, or alternatively by turn ON the .sup.19F-MR signal. The high modularity of the design allows the introduction of various types of dyes and thus enables rational adjustment of the spectral response. Two major types of responses are described: Turn-On/Off and spectral shift, depending on the type of labeling dye. The present invention further provides methods of use of the hybrid delivery system and to a kit comprising the same.

The present invention provides a method of detecting microbubbles in a vessel of an affected part, comprising aggregates the microbubbles, acquiring phase-contrast magnetic resonance images and analyzing the phase-contrast magnetic resonance images. Thus, we can detect or monitor the size and location of the microbubbles in vessels of any part of body.

Disclosed is a conjugated polymer-based nanoprobe, including a fluorescent conjugated polymer, a surface ligand, a target molecule, a near-infrared fluorescent dye and optionally a gadolinium-containing magnetic resonance contrast agent. This application also discloses a method for preparing the conjugated polymer-based nanoprobe, including: adding raw materials to an organic solvent followed by ultrasonication to obtain a mixture; and adding the mixture to ultrapure water and continuously ultrasonicating the reaction mixture. The conjugated polymer-based nanoprobe can be applied in a combined molecular imaging technique of near infrared fluorescence imaging, photoacoustic imaging and magnetic resonance imaging to effectively recognize metastatic lymph nodes and normal lymph nodes, and it can be retained in the metastatic lymph nodes for a long time, meeting the requirements for long-term observation. Moreover, the near-infrared fluorescent conjugated polymer-based nanoprobe can generate reactive oxygen under irradiation, which is suitable for the photodynamic treatment of tumors.

Provided herein are nanoparticle-lipid composite carriers as theranostic agents, particularly for diagnosis and/or treatment of cancers and related diseases and conditions. In particular embodiments, the carrier composites comprise a lipid core and an outer shell of functionalized nanoparticles (fNPs).

The invention relates to an antitumor composition based on hydrophobized hyaluronan and inorganic nanoparticles stabilized by oleic acid. The hydrophobized hyaluronan in the form of an acylated hyaluronan serves in the composition as a carrier of inorganic nanoparticles. Out of the group of inorganic nanoparticles, the composition may comprise superparamagnetic nanoparticles, nanoparticles of ZnO and moreover, upconversion nanoparticles. Said composition is selectively cytotoxic with respect to both suspension and adherent tumor cell lines, especially with respect to tumor cell lines of colorectum carcinoma and adenocarcinoma, lung carcinoma, hepatocellular carcinoma and breast adenocarcinoma. The highest cytotoxic effects were observed in case of the composition based on an oleyl derivative of hyaluronan with SPIONs. The composition of acylated hyaluronan with SPIONs may also be advantageously used for an in vivo detection of accumulation of the composition in the body, preferably in a tumor or in liver. Said composition is sterilizable in the final package.

A new approach to targeting imaging agents to macrophage-rich sites of interest is disclosed. Compositions of the invention are rHDL and HDL-like liposomal compositions, protein constituents of which, apolipoproteins A-I and/or A-II or fragments thereof are used not only as structural but also as targeting agents. This is achieved by certain controlled chemical or enzymatic modification of apolipoproteins A-I or A-II or fragments thereof. Such modification converts these apolipoproteins to substrates for macrophage scavenger receptors and results in the improvement of contrast agent-(HDL/modified apolipoprotein)-particle association with macrophages and/or absorption (uptake) by macrophages when compared to that of the contrast agent-(HDL/apolipoprotein)-particle constructed with non-modified naturally occurring apo A-I. The compositions can be used for noninvasive specific in vivo molecular detection and localization of macrophage-rich sites of interest using imaging techniques such as computed tomography (CT), gamma-scintigraphy, positron emission tomography (PET), single photon emission computed tomography (SPECT), magnetic resonance imaging (MRI).

The present invention provides amphiphilic telodendrimers that aggregate to form nanocarriers characterized by a hydrophobic core and a hydrophilic exterior. The nanocarrier core may include amphiphilic functionality such as cholic acid or cholic acid derivatives, and the exterior may include branched or linear poly(ethylene glycol) segments. Nanocarrier cargo such as hydrophobic drugs and other materials may be sequester in the core via non-covalent means or may be covalently bound to the telodendrimer building blocks. Telodendrimer structure may be tailored to alter loading properties, interactions with materials such as biological membranes, and other characteristics.

The subject invention pertains to a modified MC1R peptide ligand comprising a peptide that is a melanocortin 1 receptor (MC1R) ligand and a functionality or linker, such as a click functionality, for conjugation to a surface or agent. The modified MC1R peptide ligand can be coupled, e.g., via a click reaction with a complementary click functionality attached, to a moiety to form an MC1R-targeted agent. Drugs, contrast agents, polymers, particles, micelles, surfaces of larger structures, or other moieties can be targeted to the MC1R. The subject invention also pertains to a MC1R peptide ligand-micelle complex comprising a peptide that is a melanocortin 1 receptor ligand connected via a click reaction product to a micelle. The micelle is stable in vivo and can target melanoma tumor cells by association of the peptide ligand with the MC1R or the tumor and selectively provide a detectable and/or therapeutic agent (such as an imageable contrast agent and/or anti-cancer agent) selectively to the tumor cell.

Disclosed is a conjugated polymer-based nanoprobe, including a fluorescent conjugated polymer, a surface ligand, a target molecule, a near-infrared fluorescent dye and optionally a gadolinium-containing magnetic resonance contrast agent. This application also discloses a method for preparing the conjugated polymer-based nanoprobe, including: adding raw materials to an organic solvent followed by ultrasonication to obtain a mixture; and adding the mixture to ultrapure water and continuously ultrasonicating the reaction mixture. The conjugated polymer-based nanoprobe can be applied in a combined molecular imaging technique of near infrared fluorescence imaging, photoacoustic imaging and magnetic resonance imaging to effectively recognize metastatic lymph nodes and normal lymph nodes, and it can be retained in the metastatic lymph nodes for a long time, meeting the requirements for long-term observation. Moreover, the near-infrared fluorescent conjugated polymer-based nanoprobe can generate reactive oxygen under irradiation, which is suitable for the photodynamic treatment of tumors.