Magnetic particle actuating systems may include a magnet system configured to generate a magnetic field that includes a field-free region. A corresponding control system can be configured to control the magnet system to create a field-free region at least partially matching a target region. An excitation system can be configured to generate an excitation field to cause actuation of magnetic nanoparticles in an actuation region.

Magnetic particle actuating systems may include a magnet system configured to generate a magnetic field that includes a field-free region. A corresponding control system can be configured to control the magnet system to create a field-free region at least partially matching a target region. An excitation system can be configured to generate an excitation field to cause actuation of magnetic nanoparticles in an actuation region.

Described are methods for the improvement of neural communication between implanted and existing tissue. Methods herein use synchronous low frequency magnetic or electric stimulation of both regions to enhance communication and facilitate regeneration of nerve fibers across the tissue interface.

Described are methods for the improvement of neural communication between implanted and existing tissue. Methods herein use synchronous low frequency magnetic or electric stimulation of both regions to enhance communication and facilitate regeneration of nerve fibers across the tissue interface.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to a patient comprising a head mount for disposition on the head of a patient, and a plurality of magnet assemblies for releasable mounting on the head mount. The magnet assemblies comprises a magnet for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents for modifying the natural electrical activity of the brain of the patient. The number of magnet assemblies mounted, their individual positioning, and their selective provision of a rapidly changing magnetic field is selected to allow spatial, strength and temporal characteristics of the magnetic field to be tailored for the patient, to provide patient-specific IMS therapy, assist in diagnosis, or map out brain function. The magnet assembles can comprise magnets for provide a rapidly changing magnetic field of at least 500-600 Tesla/second corresponding to a magnet movement speed of no less than 400 Hertz.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to a patient comprising a head mount for disposition on the head of a patient, and a plurality of magnet assemblies for releasable mounting on the head mount. The magnet assemblies comprises a magnet for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents for modifying the natural electrical activity of the brain of the patient. The number of magnet assemblies mounted, their individual positioning, and their selective provision of a rapidly changing magnetic field is selected to allow spatial, strength and temporal characteristics of the magnetic field to be tailored for the patient, to provide patient-specific IMS therapy, assist in diagnosis, or map out brain function. The magnet assembles can comprise magnets for provide a rapidly changing magnetic field of at least 500-600 Tesla/second corresponding to a magnet movement speed of no less than 400 Hertz.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to an individual, wherein the apparatus comprises: a head mount for disposition on the head of an individual; and a plurality of magnet assemblies for releasable mounting on the head mount, wherein each of the magnet assemblies comprises a permanent magnet, and at least one of (i) a movement mechanism for moving the permanent magnet and/or (ii) a magnetic shield shutter mechanism, for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents in the brain of an individual so as to modify the natural electrical activity of the brain of the individual; wherein the number of magnet assemblies mounted on the head mount, their individual positioning on the head mount, and their selective provision of a rapidly changing magnetic field is selected so as to allow the spatial, strength and temporal characteristics of the magnetic field to be custom tailored for each individual, whereby to provide individual-specific TMS therapy, to assist in diagnosis or to map out brain function in neuroscience research.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to an individual, wherein the apparatus comprises: a head mount for disposition on the head of an individual; and a plurality of magnet assemblies for releasable mounting on the head mount, wherein each of the magnet assemblies comprises a permanent magnet, and at least one of (i) a movement mechanism for moving the permanent magnet and/or (ii) a magnetic shield shutter mechanism, for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents in the brain of an individual so as to modify the natural electrical activity of the brain of the individual; wherein the number of magnet assemblies mounted on the head mount, their individual positioning on the head mount, and their selective provision of a rapidly changing magnetic field is selected so as to allow the spatial, strength and temporal characteristics of the magnetic field to be custom tailored for each individual, whereby to provide individual-specific TMS therapy, to assist in diagnosis or to map out brain function in neuroscience research.

Described are methods for the improvement of neural communication between implanted and existing tissue. Methods herein use synchronous low frequency magnetic or electric stimulation of both regions to enhance communication and facilitate regeneration of nerve fibers across the tissue interface.

Described are methods for the improvement of neural communication between implanted and existing tissue. Methods herein use synchronous low frequency magnetic or electric stimulation of both regions to enhance communication and facilitate regeneration of nerve fibers across the tissue interface.