A method and system for noninvasively treating a neurodegenerative disorder, can involve determining characteristics indicative of physical attributes of a central nervous system, the characteristics including parameters for diminishing adverse impacts of a magnetothermal stimulation treatment for a neurodegenerative disorder with respect to the central nervous system, and applying as a part of the magnetothermal stimulation treatment and based on the characteristics of the physical attributes of the central nervous system, a magnetic field to the brain for a thermal stimulation of neuron cells within the brain.

A method and system for noninvasively treating a neurodegenerative disorder, can involve determining characteristics indicative of physical attributes of a central nervous system, the characteristics including parameters for diminishing adverse impacts of a magnetothermal stimulation treatment for a neurodegenerative disorder with respect to the central nervous system, and applying as a part of the magnetothermal stimulation treatment and based on the characteristics of the physical attributes of the central nervous system, a magnetic field to the brain for a thermal stimulation of neuron cells within the brain.

A device is provided for generating a very-low-frequency pulsed magnetic field carried by a very-low-frequency alternating magnetic field and intended to be applied to a region of the human body. The device comprises a plurality of pairs of angular magnet sectors of opposite polarity. The pairs of angular magnet sectors being centered on one same axis of rotation, angularly spaced apart from one another, and set in rotation at a predetermined speed about the axis of rotation so as to generate an alternating magnetic field at a predefined frequency. At least one conductive wire coil centered on the axis of rotation of the angular magnet sectors and supplied with a pulsed electric current so as to generate a pulsed magnetic field superimposed over the alternating magnetic field generated by the setting in rotation of the angular magnet sectors.

A device is provided for generating a very-low-frequency pulsed magnetic field carried by a very-low-frequency alternating magnetic field and intended to be applied to a region of the human body. The device comprises a plurality of pairs of angular magnet sectors of opposite polarity. The pairs of angular magnet sectors being centered on one same axis of rotation, angularly spaced apart from one another, and set in rotation at a predetermined speed about the axis of rotation so as to generate an alternating magnetic field at a predefined frequency. At least one conductive wire coil centered on the axis of rotation of the angular magnet sectors and supplied with a pulsed electric current so as to generate a pulsed magnetic field superimposed over the alternating magnetic field generated by the setting in rotation of the angular magnet sectors.

There is described a bone implant comprising at least one means for providing at least one bone stimulation dynamic interaction to at least one area of a bone-implant interface formed when the implant is inserted into bone, wherein the bone stimulation is one or more of bone growth, bone strengthening, bone densification and/or osseointegration between bone and the bone-implant interface.

Helmets for applying a magnetic field to the head of a subject, comprising: a housing comprising a concave surface configured to receive a portion of the head of the subject; a motor coupled to one or more of: a first permanent magnet via a first axle along a first axis of rotation, wherein the first axle drives movement of the first magnet; a second magnet via a second axle along a second axis of rotation wherein the second axle drives movement of the second magnet; and a third magnet via a third axle along the third axis of rotation wherein the third axle drives movement of the third magnet, wherein the axes are parallel; and a fit mechanism comprising a adjuster coupled to the first magnet, wherein movement of the adjustor moves the first magnet independently of the second or the third magnet.

Helmets for applying a magnetic field to the head of a subject, comprising: a housing comprising a concave surface configured to receive a portion of the head of the subject; a motor coupled to one or more of: a first permanent magnet via a first axle along a first axis of rotation, wherein the first axle drives movement of the first magnet; a second magnet via a second axle along a second axis of rotation wherein the second axle drives movement of the second magnet; and a third magnet via a third axle along the third axis of rotation wherein the third axle drives movement of the third magnet, wherein the axes are parallel; and a fit mechanism comprising a adjuster coupled to the first magnet, wherein movement of the adjustor moves the first magnet independently of the second or the third magnet.

A method of affecting a biological, cellular or biochemical function or structure in a targeted subcortical location in a brain of a patient using a TRPMS apparatus placed on a head of the patient includes positioning two or more of a plurality of magnetic assemblies on locations of the head mount selected to stimulate the targeted subcortical location in the brain of the patient, and activating the plurality of magnetic assemblies at the selected locations to generate magnetic fluxes of a selected strength, frequency and duration directed into the brain of the patient,/wherein the magnetic flux directed into the brain of the patient from each of the assemblies is operative to generate induced electric field in regions of the brain and the regions of induced electric fields generated by each of the plurality of magnetic assemblies converge in the targeted subcortical location and combine to a magnitude sufficient to affect the biological, cellular or biochemical function or structure in the targeted subcortical location.

A method of affecting a biological, cellular or biochemical function or structure in a targeted subcortical location in a brain of a patient using a TRPMS apparatus placed on a head of the patient includes positioning two or more of a plurality of magnetic assemblies on locations of the head mount selected to stimulate the targeted subcortical location in the brain of the patient, and activating the plurality of magnetic assemblies at the selected locations to generate magnetic fluxes of a selected strength, frequency and duration directed into the brain of the patient,/wherein the magnetic flux directed into the brain of the patient from each of the assemblies is operative to generate induced electric field in regions of the brain and the regions of induced electric fields generated by each of the plurality of magnetic assemblies converge in the targeted subcortical location and combine to a magnitude sufficient to affect the biological, cellular or biochemical function or structure in the targeted subcortical location.

A method of affecting a biological, cellular or biochemical function or structure in a targeted subcortical location in a brain of a patient using a TRPMS apparatus placed on a head of the patient includes positioning two or more of a plurality of magnetic assemblies on locations of the head mount selected to stimulate the targeted subcortical location in the brain of the patient, and activating the plurality of magnetic assemblies at the selected locations to generate magnetic fluxes of a selected strength, frequency and duration directed into the brain of the patient, wherein the magnetic flux directed into the brain of the patient from each of the assemblies is operative to generate induced electric field in regions of the brain and the regions of induced electric fields generated by each of the plurality of magnetic assemblies converge in the targeted subcortical location and combine to a magnitude sufficient to affect the biological, cellular or biochemical function or structure in the targeted subcortical location.