In one aspect, compositions comprising a population of core-shell nanoparticles are described herein. In some cases, the population of core-shell nanoparticles comprises a core component and a shell component encapsulating or surrounding the core component. Additionally, one or more radiosensitizers are disposed in or dispersed throughout the core component, or an interior region of the core component. Similarly, one or more chemotherapeutic agents are disposed in or dispersed throughout the shell component, or an interior region of the shell component. Moreover, in some cases, the core component is formed from one or more biodegradable polymers. Further, in some instances, the shell component is formed from one or more stimuli responsive polymers, such as a temperature-responsive polymer and/or pH-responsive polymer.

A method of preparing a coated nanoparticle can include decomposing a compound to produce a nanoparticle, oxidizing the nanoparticle to produce an oxidized nanoparticle, and coating the oxidized nanoparticle with a zwitterionic ligand to produce the coated nanoparticle. The coated nanoparticle or the nanoparticle can be used in magnetic resonance imaging.

Disclosed in the present disclosure is a biodegradable amphiphilic polymer containing disulfide in the side chain, a self-crosslinked polymeric vesicle thereof and an application in the targeted therapy of lung cancer. The polymer is obtained by an activity-controllable ring-opening polymerization based on a cyclic carbonate monomer containing a functional group of dithiolane ring, which has a controllable molecular weight and a narrow molecular weight distribution, and does not require processes of protection and deprotection; the polymer obtained by the ring-opening polymerization of the cyclic carbonate monomer of the present disclosure has biodegradability and can be used to control the drug release system, the prepared lung cancer-targeted reduction-sensitive reversibly-crosslinked polymeric vesicle as a nanomedicine carrier supports stable long circulation in vivo. However, it is highly enriched in lung cancer tissues, enter cells efficiently, and rapidly decrosslinks in the cells to release drugs, so as to kill cancer cells with high potency and specificity and inhibit the growth of tumor effectively without causing toxic and side effects.

A method of preparing a crystalline contrast agent for magnetic resonance imaging from a zwitterionic carboxylic pyridyl ligand includes mixing metal ion and the pyridyl ligand and obtaining crystals therefrom. The crystalline contrast agent includes a manganese-organic or gadolinium-organic 3D framework. The crystalline contrast agent is employed in a kit and a pharmaceutically acceptable composition. The method allows for preparing crystalline contrast agents with superior properties with easily available starting materials and with an economic and efficient process. The method allows for preparing crystalline contrast agents with exceptional water-stability and water-solubility, which exhibit high longitudinal relaxivities and with excellent stabilities under physiological conditions and low cytotoxicity. Further provided is a method for in vivo imaging of a subject, in particular a human, comprising administering the crystalline contrast agent to the subject.

The purpose of the present invention is to provide composite particles for imaging that have high biodegradability after imaging. To achieve the above purpose, the composite particles for imaging according to the present invention are configured such that the ratio (long-term residual amount/short-term residual amount) of a long-term residual amount, which is the average value of the contrast rate after six days in a cell and the contrast rate after 11 days in a cell of the same type, and a short-term residual amount, which is the contrast rate after two days in a cell of the same type, is less than 99%.

The present disclosure provides functionalized magnetic nanoparticles (MNPs) comprising a functional group that binds to -amyloid deposits and/or neurofibrillary tangles. The present disclosure provides compositions comprising the functionalized MNPs, and methods of using the functionalized MNPs in imaging -amyloid deposits and neurofibrillary tangles.

Methods of and systems for making a hyperpolarized fluid are provided, which include exposing a fluid and parahydrogen to a catalyst. The hyperpolarized fluid can be introduced to a subject. The hyperpolarized fluid can be included in methods of imaging a subject. Also provided are methods that use the hyperpolarized fluids for detecting protein ligand interactions and for enhancing the NMR signals of biopolymers having chemically exchangeable protons.

The present invention provides a .sup.19F-MR/fluorescence multi-mode molecular imaging and drug loading diagnosis-treatment integrated nanoprobe, and a preparation method and an application. The nano-probe is a nanoparticle formed by coating a mixture of a surfactant containing a molecular targeting treatment drug and a fluorescent dye with a Perfluorocarbon (PFC) carrier; and by uniformly dispersing a mixed solution into water and glycerol, processing ultrasonically, removing a component which is not effectively coated, and purifying, the drug-loading nanoparticle capable of being used for 19 F-MR imaging may be prepared. The nano-probe may implement in-vivo 19F-MR molecular imaging; a carried molecular targeting treatment drug can implement targeted binding and targeted treatment; and by virtue of a characteristic that PFC in a nucleus may carry and release oxygen massively, an anaerobious microenvironment in the tumor is improved, a chemosensitization effect is achieved, and thus the diagnosis-treatment integration of the tumor is implemented finally.

Intravenous ferumoxytol is used to effectively label mesenchymal stem cells (MSCs) in vivo and is used for in vivo tracking of stem cell transplants with magnetic resonance (MR) imaging. The method eliminates risk of contamination and biologic alteration of MSCs associated with ex-vivo-labeling procedures.

A system and method for locating magnetic material. In one embodiment the system includes a magnetic probe; a power module in electrical communication with the magnetic probe to supply current to the magnetic probe; a sense module in electrical communication with the magnetic probe to receive signals from the magnetic probe; and a computer in electrical communication with the power module and the sense module. The computer generates a waveform that controls the supply of current from the power module and receives a signal from the sense module that indicates the presence of magnetic material. The magnetic probe is constructed from a material having a coefficient of thermal expansion of substantially 10.sup.6/ C. or less and a Young's modulus of substantially 50 GPa or greater. In one embodiment magnetic nanoparticles are injected into a breast and the lymph nodes collecting the particles are detected with the probe and deemed sentinel nodes.