Disclosed is a composition including magnetic nanoparticles for use in the treatment of a tissue volume including pathological cells in an individual, wherein a portion only of the tissue volume is occupied by the magnetic nanoparticles upon administration of the composition to the individual and the magnetic nanoparticles are excited by radiations.

Systems, methods and devices for creating an effect using microwave energy to specified tissue are disclosed herein. A system for the application of microwave energy to a tissue can include, in some embodiments, a signal generator adapted to generate a microwave signal having predetermined characteristics, an applicator connected to the generator and adapted to apply microwave energy to tissue, the applicator comprising one or more microwave antennas and a tissue interface, a vacuum source connected to the tissue interface, a cooling source connected to said tissue interface, and a controller adapted to control the signal generator, the vacuum source, and the coolant source. The tissue may include a first layer and a second layer, the second layer below the first layer, and the controller is configured such that the system delivers energy such that a peak power loss density profile is created in the second layer.

An implant includes a shape-memory material having a transformation temperature. The implantable element is configured to be implanted, and to perform a first therapeutic function when the shape-memory material is in a first shape. An energy applicator is configured to change the shape-memory material from the first shape to a second shape by raising a temperature of the shape-memory material to the transformation temperature by radiating energy to the implant from outside the body. The implant is configured to perform a second therapeutic function while the shape-memory material is in the second shape, the second therapeutic function being qualitatively different from the first therapeutic function. Other embodiments are also described.

Provided is a cancer treating device including a signal generator, a temperature sensor electrically connected to the signal generator, and a pair of electrodes which receive an AC voltage from the signal generator, wherein the signal generator is configured to generate an electric field between the electrodes so as to change orientations of ferroelectric particles inside a cancer cell, the temperature sensor measures a temperature around the cancer cell, and the signal generator may be configured to change the intensity of the electric field on the basis of the measured temperature.

Products, compositions, systems, and methods for modifying a target structure which mediates or is associated with a biological activity, including treatment of conditions, disorders, or diseases mediated by or associated with a target structure, such as a virus, cell, subcellular structure or extracellular structure. The methods may be performed in situ in a non-invasive manner by placing a nanoparticle having a metallic shell on at least a fraction of a surface in a vicinity of a target structure in a subject and applying an initiation energy to a subject thus producing an effect on or change to the target structure directly or via a modulation agent. The nanoparticle is configured, upon exposure to a first wavelength .sub.1, to generate a second wavelength .sub.2 of radiation having a higher energy than the first wavelength .sub.1. The methods may further be performed by application of an initiation energy to a subject in situ to activate a pharmaceutical agent directly or via an energy modulation agent, optionally in the presence of one or more plasmonics active agents, thus producing an effect on or change to the target structure. Kits containing products or compositions formulated or configured and systems for use in practicing these methods.

Apparatus and methods are described for use with a heating device (26) configured to heat at least a portion of a subject's body. A nanoparticle (22) is configured to be administered to the subject, the nanoparticle including at least one inner core (30) that includes a magnetic material having a Curie temperature; a phase-change-material layer (31) that surrounds the inner core and that comprises a phase-change material that is configured to absorb latent heat of fusion by undergoing a phase change selected from the group consisting of: solid to liquid, and gel to liquid, the phase-change occurring at a phase-change temperature that is lower than the Curie temperature; and an outer layer (32) disposed around the phase-change-material layer, the outer layer comprising a plurality of nano-subparticles (34) that are separated from one another, such as to form a segmented layer. Other applications are also described.

Methods and devices (e.g., for nerve modulation) may include at least one thermistor and a balloon having a balloon wall. In one or more embodiments, the medical device is configured and arranged to transfer heat to the medical device surroundings. In one or more embodiments, the at least one thermistor is a portion of a thermistor array disposed on the balloon wall, the thermistor array including a plurality of thermistors and operatively engaged with a source of electric current. In one or more embodiments, the device includes at least one flexible circuit mounted on the outer surface of the expandable balloon, the at least one flexible circuit including at least one temperature-sensing device that includes at least one thermistor, wherein at least a portion of a conductive layer is electronically coupled to the thermistor, with the proviso that no electrode is associated with the conductive layer.

A system for deploying a shape memory catheterization device within a patient, includes a catheter for endovascular insertion of the shape memory catheterization device. A heat source heats the shape memory catheterization device above the transition temperature. A transformation data generator includes a circuit driver for driving a circuit that includes at least one resistive element of the shape memory catheterization device and a detection circuit for generating transformation data based on a resistance of the at least one resistive element, wherein the transformation data indicates a shape transformation of the shape memory catheterization device from a catheterization shape to a transformed shape.

Methods and systems for providing dosed and calibrated thermal stimulation using an implantable stimulation device are disclosed. Aspects of the disclosure provide bioheat models based on physiological and thermal properties of target anatomy and thermopole algorithms that interact with the bioheat models to derive thermal stimulation parameters for providing dosed and calibrated thermal stimulation. Also, graphical user interfaces (GUIs) are disclosed for configuring and targeting heat delivery into specific targets.

Methods are disclosed for treating cell components, cells, organelles, organs, and/or tissues with acoustic energy, electromagnetic energy, static or alternating electric fields, and/or static or alternating magnetic fields in the presence or absence of exogenous particulate agents for therapeutic applications.