An apparatus capable of creating synchronized sound, vibration and magnetic field stimulation, for the purpose of habituating and inhibiting brain function while stimulating the human spiritual energy system, is described. The apparatus comprises an amplifier and transducers built into a comfortable seating arrangement including a support structure and a motion platform. The support structure, such as a chair, rests upon the motion platform, which is adapted to impart three-dimensional motion to the support structure. The apparatus uses layered music to create synchronized sounds, vibrations and magnetic fields.

The present method and system provides a neuromodulation therapy including receiving a plurality of input data relating to a patient, the input data including brain value measurements. The method and system includes analyzing the input data in reference to reference data generated based on machine learning operations associated with existing patient data and reference database data. Based thereon, the method and system includes electronically determining, a brain malady and a severity value for the patient and electronically generating a treatment protocol for the patient, the treatment protocol includes transcranial stimulation parameters. Therein, the method and system includes applying a transcranial stimulation using the transcranial stimulation parameters based on the treatment protocol.

The present method and system provides a neuromodulation therapy including receiving a plurality of input data relating to a patient, the input data including brain value measurements. The method and system includes analyzing the input data in reference to reference data generated based on machine learning operations associated with existing patient data and reference database data. Based thereon, the method and system includes electronically determining, a brain malady and a severity value for the patient and electronically generating a treatment protocol for the patient, the treatment protocol includes transcranial stimulation parameters. Therein, the method and system includes applying a transcranial stimulation using the transcranial stimulation parameters based on the treatment protocol.

The invention disclosure relates to a device for emitting a magnetic field including an insulating support intended to be applied on a part of a person's body, at least two hexagonal antennas, and a power supply source. The device has at least a first antenna and at least a second antenna, that are reversely wound.

The invention disclosure relates to a device for emitting a magnetic field including an insulating support intended to be applied on a part of a person's body, at least two hexagonal antennas, and a power supply source. The device has at least a first antenna and at least a second antenna, that are reversely wound.

An implant unit configured for implantation into a body of a subject is provided. The implant unit may include a flexible carrier unit including a central portion and two elongated arms extending from the central portion, an antenna, located on the central portion, configured to receive a signal, at least one pair of electrodes arranged on a first elongated arm of the two elongated arms. The at least one pair of electrodes may be adapted to modulate a first nerve. The elongated arms of the flexible carrier may be configured to form an open ended curvature around a muscle with the nerve to be stimulated within an arc of the curvature.

A method for modulating an immune response by activating or inhibiting dopaminergic neurons in the Ventral Tegmental Area (VTA) is provided. Modulation is achieved by modulating the activity, the abundance or both of: a natural killer cell, a CD8 T-cell, a CD4 T-cell, a B-cell, a dendritic cell, a macrophage, a granulocyte, or their combination.

A method for modulating an immune response by activating or inhibiting dopaminergic neurons in the Ventral Tegmental Area (VTA) is provided. Modulation is achieved by modulating the activity, the abundance or both of: a natural killer cell, a CD8 T-cell, a CD4 T-cell, a B-cell, a dendritic cell, a macrophage, a granulocyte, or their combination.

The disclosure discloses a magnetic stimulation method with a controllable induced field direction, and belongs to the technical field of noninvasive neural regulation. The method includes the following steps: S100, calculating currents i.sub.1j, i.sub.2j, i.sub.3j, j=1, 2, . . . n required to be made to generate a unit-direction vector electric field at a target point P.sub.t, the same below; S200, decomposing a vector electric field E required at the target point to three fundamental vector directions to obtain electric field components E.sub.1, E.sub.2, E.sub.3; S300, calculating currents that may generate the electric field components E.sub.1, E.sub.2, E.sub.3 at the target point, I.sub.1j=E.sub.1i.sub.1j, I.sub.2j=E.sub.2i.sub.2j, I.sub.3j=E.sub.3i.sub.3j; S400, superimposing the currents of the three energization modes to obtain a resultant current I.sub.j=I.sub.1j+I.sub.2j+I.sub.3j=E.sub.1i.sub.1j+E.sub.2i.sub.2j+E.sub.3i.sub.3j to be made of each coil of a coil group, that is, generating a required electric field E at the target point for specific directional simulation.

The disclosure discloses a magnetic stimulation method with a controllable induced field direction, and belongs to the technical field of noninvasive neural regulation. The method includes the following steps: S100, calculating currents i.sub.1j, i.sub.2j, i.sub.3j, j=1, 2, . . . n required to be made to generate a unit-direction vector electric field at a target point P.sub.t, the same below; S200, decomposing a vector electric field E required at the target point to three fundamental vector directions to obtain electric field components E.sub.1, E.sub.2, E.sub.3; S300, calculating currents that may generate the electric field components E.sub.1, E.sub.2, E.sub.3 at the target point, I.sub.1j=E.sub.1i.sub.1j, I.sub.2j=E.sub.2i.sub.2j, I.sub.3j=E.sub.3i.sub.3j; S400, superimposing the currents of the three energization modes to obtain a resultant current I.sub.j=I.sub.1j+I.sub.2j+I.sub.3j=E.sub.1i.sub.1j+E.sub.2i.sub.2j+E.sub.3i.sub.3j to be made of each coil of a coil group, that is, generating a required electric field E at the target point for specific directional simulation.