Methods and systems to control magnetic fields and magnetic field induced currents, and to provide stimulations within a patient's body, e.g.: deep brain stimulation, in a non-invasive manner and with greater focus and control than has been afforded by prior known methods and systems. An array of magnetic coils is provided and positionable about a portion of a patient's body, and are configured to create a small region of a magnetic hole, or configured to create a small region of concentrated magnetic field strength, or their combination, and at depths within the patient's body in a focused region and sparing the surrounding tissues of the focused region, that have previously not been receptive to non-invasive TMS methods, which are either focused but can affect only the surface and shadow areas, or that can reach certain depths but by doing so only through affecting large surface areas and deep tissue areas.

Methods and systems to control magnetic fields and magnetic field induced currents, and to provide stimulations within a patient's body, e.g.: deep brain stimulation, in a non-invasive manner and with greater focus and control than has been afforded by prior known methods and systems. An array of magnetic coils is provided and positionable about a portion of a patient's body, and are configured to create a small region of a magnetic hole, or configured to create a small region of concentrated magnetic field strength, or their combination, and at depths within the patient's body in a focused region and sparing the surrounding tissues of the focused region, that have previously not been receptive to non-invasive TMS methods, which are either focused but can affect only the surface and shadow areas, or that can reach certain depths but by doing so only through affecting large surface areas and deep tissue areas.

A magnetic-vibration and magnetoelectric therapy device, comprising an upper computer and a lower computer; the upper computer is used to send control instructions to the lower computer, and the lower computer is used to output stimulation signals acting on a human body based on the control instructions. The lower computer comprises a control unit, a magnetic vibration unit, a magnetoelectric unit and an electrical stimulation unit; the control unit is connected with the magnetic vibration unit, the magnetoelectric unit and the electrical stimulation unit respectively, the magnetic vibration unit is used to generate a vibrating magnetic field acting on a human body, the magnetoelectric unit is used to generate a vibrating rotating magnetic field acting on a human body, and the electrical stimulation unit is used to generate electrical stimulation signals acting on a human body. The device can be used to treat chronic prostatitis.

A magnetic-vibration and magnetoelectric therapy device, comprising an upper computer and a lower computer; the upper computer is used to send control instructions to the lower computer, and the lower computer is used to output stimulation signals acting on a human body based on the control instructions. The lower computer comprises a control unit, a magnetic vibration unit, a magnetoelectric unit and an electrical stimulation unit; the control unit is connected with the magnetic vibration unit, the magnetoelectric unit and the electrical stimulation unit respectively, the magnetic vibration unit is used to generate a vibrating magnetic field acting on a human body, the magnetoelectric unit is used to generate a vibrating rotating magnetic field acting on a human body, and the electrical stimulation unit is used to generate electrical stimulation signals acting on a human body. The device can be used to treat chronic prostatitis.

A device for magneto-mechanically radiating oscillating magnetic fields by periodically and precisely moving permanent magnets such that the field they continually radiate oscillates precisely. The device provides for varying magnetic field therapy as well as for use in other areas such as magnetic therapy for mammals and for improving plant growth. The device provides a varying magnetic field therapy that allows a user to use it without any change to the aesthetics of the location it is used in because the field can radiate through, or from under, objects.

A device for magneto-mechanically radiating oscillating magnetic fields by periodically and precisely moving permanent magnets such that the field they continually radiate oscillates precisely. The device provides for varying magnetic field therapy as well as for use in other areas such as magnetic therapy for mammals and for improving plant growth. The device provides a varying magnetic field therapy that allows a user to use it without any change to the aesthetics of the location it is used in because the field can radiate through, or from under, objects.

The disclosure provides an applicator for applying a cosmetic treatment product to the skin or the lips, the applicator comprising at least: an application portion comprising a bundle of needles for applying the cosmetic treatment product and extending along a longitudinal axis, the bundle of needles comprising at least one first set of needles having a distribution that is square in cross-section relative to the longitudinal axis; and a linear drive device connected to the application portion and configured to constrain the bundle of needles to perform reciprocating motion along the longitudinal axis.

A transcranial magnetic stimulation device in accordance with embodiments of the present invention comprises a head mount for disposition on a head of a patient and configured with a plurality of attachment points, a plurality of magnetic assembly devices connected to the plurality of attachment points, a given magnetic assembly device equipped with an actuator device to actuate a magnet, is addressable, and configured to receive a control signal addressed to the given magnetic assembly device, and a processor having a memory and configured by program code. The processor is configured to: select one or more treatment protocol units, generate a control signal using at least information contained in the selected treatment protocol units, energize at least one magnetic assembly device over a period of time to cause the magnet to actuate according to the control signal, and monitor the patient response to energizing to addressable actuator.

Methods for treating a patient using time varying magnetic field are described. The treatment methods combine various approaches for aesthetic treatment. The methods are focused on enhancing a visual appearance of the patient.

Apparatus for an orthopedic brace with magnetic assistance. A pair of braces are configured to each support and secure a magnetic device on each leg above the knee. The magnetic devices generate a magnetic force sufficient to reduce a spastic gait. Each magnetic device has a magnetic field that interacts with a magnetic field of the other magnetic device. The magnetic field produces a magnetic force that repels the other magnetic device as the magnetic devices move relative to each other when the wearer walks. The shape of the magnetic field is configured to aid the wearer in avoiding the legs colliding while walking. In one embodiment discrete magnets are disposed on the medial side of each brace. In another embodiment magnetic material is integral with the medial side of each brace and the magnetic material has a selected field strength curve.