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 capacitive element of the shape memory catheterization device and a detection circuit for generating transformation data based on a capacitance of the at least one capacitive element, wherein the transformation data indicates a shape transformation of the shape memory catheterization device from a catheterization shape to a transformed shape.

Magnetic nanoparticles for use in a magnetic hyperthermia therapeutic treatment, prophylactic treatment or diagnosis method, wherein the magnetic nanoparticles are administered to a body part of an individual and the body part is exposed to a magnetic field oscillating at a high frequency and at a medium and/or low frequency, wherein the high frequency is 1 MHz at the most, the medium frequency is lower than the high frequency, and the low frequency is lower than the high frequency and lower than the medium frequency when it is present.

Methods, apparatuses, systems, and implementations for inductive heating of a foreign metallic implant are disclosed. A foreign metallic implant may be heated via AMF pulses to ensure that the surface of the foreign metallic implant heats in a uniform manner. As the surface temperature of the foreign metallic implant rises, acoustic signatures may be detected by acoustic sensors that may indicate that tissue may be heating to an undesirable level approaching a boiling point. Once these acoustic signatures are detected, the AMF pulses may be shut off for a time period to allow the surface temperature of the implant to cool before applying additional AMF pulses. In this manner, the surface temperature of a foreign metallic implant may be uniformly heated to a temperature adequate to treat bacterial biofilm buildup on the surface of the foreign metallic implant without damaging surrounding tissue. The AMF pulse treatment can be combined with an antibacterial/antimicrobial treatment regimen to reduce the time and/or antibacterial dosage amount needed to remove the biofilm from the metallic implant.

Disclosed are methods of altering the electric impedance to an alternating electric field in a target site of a subject, comprising introducing a nanoparticle to a target site in the subject; and applying an alternating electric field to the target site of the subject, wherein the electric impedance in the target site of the subject to the alternating current is altered. Disclosed are methods for improving transport of a nanoparticle across a cell membrane of a cell, the method comprising applying an alternating electric field to the cell for a period of time, wherein application of the alternating electric field increases permeability of the cell membrane; and introducing the nanoparticle to the cell, wherein the increased permeability of the cell membrane enables the nanoparticle to cross the cell membrane. Disclosed are methods of imaging a cancer cell, the method comprising applying a first alternating electric field at a first frequency to the cancer cell for a first period of time, wherein application of the first alternating electric field at the first frequency to the cancer cell for the first period of time increases permeability of cell membranes of the cancer cell; introducing a nanoparticle to the cancer cell, wherein the increased permeability of the cell membranes enables the nanoparticle to cross the cancer cell membrane; and imaging the cancer cell.

An apparatus and method for magnetic particle manipulation enables the particle to be rotated and translated independently using magnetic fields and field gradients, which produce the desired decoupled translational and rotational motion. The apparatus and the method for manipulation may be implemented in parallel, involving many particles. The rotational magnetic field used to induce rotational motion may be varied to induce particle motion, which is either in phase or out of phase with the rotational magnetic field. The magnetic fields and gradients described herein may be generated with permanent magnets, electromagnets, or some combination of permanent magnets and electromagnets.

An induction coil and method for heating susceptors within a portion of a living body, include an effective diameter that is determined based on a cross-sectional area of the induction coil, a length determined along an axis of the induction coil that is orthogonal to the cross-sectional area, and a ratio of the length to the effective diameter that ranges between 0.25 and 0.75, such that a magnetic field is generated that ranges between 1 kA/m and 40 kA/m with an input frequency that ranges between 50 kHz and 1 MHz.

A method for the treatment of tumor(s), tumor cell(s), cancer(s) in a subject by the generation of heat. The latter is produced by chains of magnetosomes extracted from whole magnetotactic bacteria and subjected to an alternating magnetic field. These chains of magnetosomes yield efficient antitumoral activity whereas magnetosomes unbound from the chains or kept within the whole bacteria produce poor or no antitumoral activity. The introduction of various chemicals such as chelating agents and/or transition metals within the growth medium of the bacteria improves the heating properties of the chains of magnetosomes. Moreover, the insertion of the chains of magnetosomes within a lipid vesicle is also suggested in order to favor their rotation in vivo and hence to improve their heating capacity. The vesicle can contain an antitumoral agent together with the chains of magnetosomes, and the agent is released within the tumors by heating the vesicle.

Cancer treatment methods using thermotherapy and/or enhanced immunotherapy are disclosed herein. In one embodiment, the method comprising the steps of administering a plurality of nanoparticles to target a tumor in a patient, the nanoparticles being coated with an antitumor antibody, cell penetrating peptides (CPPs), and a polymer, and the nanoparticles containing medication and/or gene, and a dye or indicator in the polymer coating, at least some of the nanoparticles attaching to surface antigens of tumor cells so as to form a tumor cell/nanoparticle complex; exciting the nanoparticles using an ultrasound source generating an ultrasonic wave so as to peel off the polymer coating of the nanoparticles, thereby releasing the dye or indicator into the circulation of the patient and the medication and/or gene at the tumor site; and imaging a body region of the patient so as to detect the dye or indicator released into the circulation of the patient.

A method for the treatment of tumor(s) or tumor cell(s) or cancer(s) in a subject in need by the generation of heat. The latter is produced by chains of magnetosomes extracted from whole magnetotactic bacteria and subjected to an alternating magnetic field. These chains of magnetosomes yield efficient antitumoral activity whereas magnetosomes unbound from the chains or kept within the whole bacteria produce poor or no antitumoral activity. The introduction of various chemicals such as chelating agents and/or transition metals within the growth medium of the bacteria improves the heating properties of the chains of magnetosomes. Moreover, the insertion of the chains of magnetosomes within a lipid vesicle is also suggested in order to favor their rotation in vivo and hence to improve their heating capacity. The vesicle can contain an antitumoral agent together with the chains of magnetosomes. In this case, the agent is released within the tumors by heating the vesicle.

Devices, systems, and methods for implanting and locating traceable markers in a region of a patient's body such as a lung, and in particular lung nodules which may be difficult to locate using traditional means. Further embodiments describe devices, systems, and methods that may be used to treat regions in the lung such as lung nodules with various treatment modalities including heating, microwave irradiation, chemical treatment, and which may be used in conjunction with embodiments of the traceable markers described herein.