The invention relates to a computer-aided simulation tool, in particular to computer-aided simulation methods, for providing assistance in the planning of thermotherapy, and to suitably configured computer equipment. The thermotherapy comprises hyperthermic treatment of a tumour volume within a volume of a human body. The hyperthermic treatment comprises the application of a magnetic field within a treatment volume by means of a magnetic field applicator. In at least one depot volume, thermal energy can be introduced by means of magnetic, paramagnetic and/or superparamagnetic nanoparticles deposited in the body, by power absorption in the applied magnetic field. Field strength values and optionally calculated temperature distributions are provided for assisting the user in the planning of the thermotherapy.

Compositions and methods for treating various cardiovascular disorders include targeted delivery of glutamate for impairing a targeted portion of the autonomic nervous system (ANS). Targeted delivery may be via direct injection into the targeted portion of the ANS or via vascular injection of magnetically-targetable nanoparticles.

Normal or genetically modified cell(s) having magnetic nanoparticle(s) bound (affixed) to their surfaces and methods of delivery to target tissues, e.g. For treatment of disease and/or injury.

With externally applied magnetic fields, we will push and concentrate in vivo diamagnetic Bismuth particles or unipolar magnetic particles as a confined locus, cause the locus to move to a tumor, shape it to the tumor, then use near IR to heat the particles so to destroy the tumor by thermal ablation or hyperthermia treatment. We will then cause the locus to move to other tumors, and repeat the process, so to destroy all tumors and cure the cancer.

The present invention relates to compositions containing nanoparticies and uses of said composition for transferring therapeutically active substances into cells by means of specifically coated nanoparticles. The chemical design of the particles is such that a large amount thereof is absorbed into the cells. No direct bond between nanoparticle and the therapeutically active substance is required for the transfer into the cells. Thanks to said transfer, an increased efficacy of the substance and simultaneously reduced systemic toxicity is achieved, i.e. an increase in the efficacy while the side effects are reduced.

The methods include selectively reducing or expanding T cells according to the antigenic specificity of the T cells. Therefore, the present invention can be used to reduce or eliminate pathogenic T cells that recognize autoantigens, such as beta cell specific T cells. As such, the present invention can be used to prevent, treat or ameliorate autoimmune diseases such as IDDM. Furthermore, the present invention can be used to expand desirable T cells, such as anti-pathogenic T cells to prevent, treat and/or ameliorate autoimmune diseases.

Described herein is a method of inducing vascular inflammation using modified paramagnetic nanoparticles with improved therapeutic loading efficiency and enhanced circulation properties. The method comprises loading lipophilic agent into the fatty acid coatings of a paramagnetic nanoparticle (PMNP). In certain embodiment, the lipophilic agent is lipopolysaccharides (LPS). Described herein is a method of inducing vascular leakiness. In certain embodiment, the method induces a significant enhancement of vascular leakiness in a human body. In certain embodiments, the vascular leakiness allows for enhanced local delivery of nanoparticle and non-nanoparticle based therapeutics, imaging agents and theranostics. Also described herein is a method of using the PMNP for the treatment of diseases. In certain embodiments, the method of treatment is a combination therapy. Described herein are imaging of therapeutic delivery of PMNP and diagnostic methods using the PMNP. Also described herein is a diagnostic kit that comprises the PMNP.

A method for preparing a magnetic chain structure is provided. The method comprises providing a plurality of magnetic particles; dispersing the plurality of magnetic particles in a solution comprising a dopamine-based material to form a reaction mixture; applying a magnetic field across the reaction mixture to align the magnetic particles in the reaction mixture; and polymerizing the dopamine-based material on the aligned magnetic particles to obtain the magnetic chain structure. A magnetic chain structure prepared by the method is also provided.

A composite magnetic nanoparticle drug delivery system provides targeted controlled release chemotherapies for cancerous tumors and inflammatory diseases. The magnetic nanoparticle includes a biocompatible and biodegradable polymer, a magnetic nanoparticle, the biological targeting agent human serum albumin, and a therapeutic pharmaceutical composition. The composite nanoparticles are prepared by oil-in-oil emulsion/solvent evaporation and high shear mixing. An externally applied magnetic field draws the magnetic nanoparticles to affected areas. The biological targeting agent draws the nanoparticles into the affected tissues. Polymer degradation provides controlled time release delivery of the pharmaceutical agent.

A magnetic nanoparticles including a TRPV1 agonist, as well as methods of preparation and use, are described herein. A magnetically responsive pharmaceutical can include a core region having a magnetic nanoparticle (MNPs) and a TRPV1 protein agonist. Further, an exterior coating comprising a polymer can be formed around the core region. The magnetically responsive pharmaceutical can be administered to a recipient and directed to a target region using an external magnetic field.