Disclosed are peptides and peptidomimetics that in some embodiments include the amino acid sequence KRGARST or (SEQ ID NO: 1), AKRGARSTA or (SEQ ID NO: 2), or CKRGARSTC (SEQ ID NO: 3). Also disclosed are conjugates and compositions that include the peptides and/or peptidomimetics, methods for directing a moiety to tumor lymphatic vasculature, methods for imaging tumor lymphatic vasculature, methods for reducing or inhibiting tumor metastasis, methods for reducing the number of tumor lymphatic vessels, methods for treating cancer, methods for treating a disease or disorder associated with a gC1q/p32 receptor biological activity, methods for detecting the presence of a gC1q/p32 receptor, methods for detecting interactions between gC1q/p32 receptors and the presently disclosed conjugates and compositions, methods for delivering the presently disclosed conjugates and compositions to gC1q/p32 receptors, methods for assessing gC1q/p32 receptor levels in cells, methods for identifying subjects having diseases associated with gC1q/p32 receptor biological activities, and methods for screening for compounds that interact with gC1q/p32 receptors.

A liposomal nanocarrier delivery system for targeting an active CD44 molecule, preparation method therefor, and uses therof. The surface of the liposome is partially modified by a targeting ligand, wherein the targeting ligand is a ligand that can be specifically combined with the active CD44 molecule. The liposomal nanocarrier delivery system can be used for diagnosing, preventing, and treating vulnerable plaque or diseases related to vulnerable plaque.

A polymer-metal oxide complex, comprising a metal oxide particle located at the core and a polymer modified on the surface of the metal oxide particle, the polymer being provided with functional groups capable of bonding with a metal in the metal oxide, the density of the binding sites of the polymer and the surface of the metal oxide particle being greater than two sites/square nanometer. Also disclosed are a preparation method for the polymer-metal oxide complex, and applications of the polymer-metal oxide complex as a nuclear magnetic resonance contrast agent and as an iron supplement. The polymer-metal oxide complex has a significantly extended in vivo circulation time and effectively overcomes the defect that existing contrast agents cause hypersensitivity, which in addition to the superparamagnetic and iron metabolism participation functions of the complex, enables the complex to be applied as a magnetic resonance imaging contrast agent and as an iron supplement treating iron-deficiency anaemia.

A biocompatible magnetic material containing an iron oxide nanoparticle and one or more biocompatible polymers, each having formula (I) below, covalently bonded to the iron oxide nanoparticle:

##STR00001##

in which each of variables R, L, x, and y is defined herein, the biocompatible magnetic material contains 4-15% Fe(II) ions relative to the total iron ions. Also disclosed in a method of preparing the biocompatible magnetic material.

The present invention provides nanocarrier compositions, for example, copper sulfide perfluorocarbon nanocarrier compositions, and methods of making the same. The compositions are useful for imaging, diagnostics, therapy and for other uses.

Multifunctional nanoparticles can include two or more different populations of nanocrystals that impart a combination of properties arising from the constituent populations in a single, multifunctional nanoparticle.

Synthesis and characterization of starch based pH-responsive nanoparticles for controlled drug delivery are described. Polymethacrylic acid grafted starch (PMAA-g-St) nanoparticles with various molar ratio of starch to MAA were synthesized by a new one-pot method that enabled simultaneous grafting of PMAA and nanoparticle formation in an aqueous medium. NMR data showed that polysorbate 80 was polymerized into the graft polymer. Nanoparticles were relatively spherical with narrow size distribution and porous surface morphology and exhibited pH-dependent swelling in physiological pH range. The particle size and magnitude of volume phase transition were dependent on PMAA content and formulation parameters such as surfactant levels, cross-linker amount, and total monomer concentration. The results showed that the new pH-responsive nanoparticles possessed useful properties for controlled drug delivery.

Radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of using the radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of manufacturing radiopaque monomers, polymers, and microspheres are disclosed herein.

Described herein are particle-driven radiogenomics systems and methods that can be used to identify imaging features for prediction of intratumoral and interstitial nanoparticle distributions in cancers (e.g., in low grade and/or high-grade brain cancers (e.g., gliomas, e.g., primary gliomas)). In certain embodiments, the systems and methods described herein extract and combine quantitative multi-dimensional data generated from structural, functional, and/or metabolic imaging. In certain embodiments, the combined multidimensional data is linked to intratumoral and interstitial nanoparticle distributions. For example, this linked data can be used to determine quantitative functional-metabolic multimodality particle-based imaging features and to predict treatment efficacy. These techniques provide an improved quantitative ability to measure treatment response and determine tumor progressions compared to traditional size-based imaging methods.

Negatively charged nanoparticulate compositions are used to deliver therapeutic, prophylactic or diagnostic agents to macrophages or other phagocytic cells in the brain and central nervous system. The negative charge of the nanoparticles increases circulation, increases internalization by macrophage or other phagocytic cells, increases release within the macrophage or other phagocytic cells, or a combination thereof, relative to charge-neutral or charge-positive nanoparticles.