An example of subject may deliver a therapy by delivering energy to tissue. The system may comprise a magnetic field system and an electric field system. The magnetic field system may be configured to provide a magnetic field in a first direction to the tissue. The magnetic field system may include at least one magnetic field source to produce the magnetic field. The magnetic field produced by the at least one magnetic field source may include a magnetic field produced by at least one of a permanent magnet, a temporary magnet or electric current flow through a conductor. The electric field system may be configured to provide an electric field in a second direction to the tissue. The electric field system may include at least one electric field source to provide the electric field and the second direction is non-parallel to the first direction.

A device for providing an energetic field to promote the body's self-healing process comprises electronics immersed in a dialectric oil in a first enclosure which accelerate and spin an energetic current within a gas-filed glass tube. The tube protrudes through a small opening into a second large metal (e.g. copper)-lined patient enclosure, such that the energy emitted from the tube is directed toward a circular concave baffle covered in a densely woven fabric. A plastic sheet optionally protects the patient from arcing with the baffle. Seating/support is provided to properly position the patient; as well as seating for the practitioner/therapist who both positions the patient, and provides mental and emotional guidance, to optimize patient receptivity to treatment.

An electroporation system may include a well plate, a dispenser and a dispenser-well positioning system. The well plate may include wells, each of the wells including an interior, a first electrode adjacent the interior and a second electrode adjacent the interior and spaced from the first electrode. The first electrode and the second electrode are to apply an electrostatic field across the well. The dispenser is to dispense a cell having a diameter into each of the wells. The dispenser-well positioning system is to align each well and the dispenser such that the dispenser dispenses the cell into each well at a location spaced from the first electrode and the second electrode by a distance of at least 5 times the diameter of the cell.

Disclosed are a wound treatment patch using static electricity, and a method for fabricating the wound treatment patch using static electricity. The patch includes a substrate made of a sticky polymer; a first electrode disposed in a first partial region of one face of the substrate and exposed to an outside; and a second electrode disposed in a second partial region other than the first partial region, and spaced apart from the first electrode, and encapsulated within the substrate, wherein each of the first electrode and the second electrode is made of hydrogel having electrical conductivity or a soft polymer having electrical conductivity.

Disclosed are a wound treatment patch using static electricity, and a method for fabricating the wound treatment patch using static electricity. The patch includes a substrate made of a sticky polymer; a first electrode disposed in a first partial region of one face of the substrate and exposed to an outside; and a second electrode disposed in a second partial region other than the first partial region, and spaced apart from the first electrode, and encapsulated within the substrate, wherein each of the first electrode and the second electrode is made of hydrogel having electrical conductivity or a soft polymer having electrical conductivity.

An autonomous neurostimulation unit used in the modulation of the nervous system is provided and has: at least one pair of pads, each formed by at least one inner layer of ceramic; an intermediate layer; and a conductive alloy coating. The material of the layer of coating is different and has different conductivity in each of the pads of the pair. The unit can be used in the modulation of the nervous system, with neurostimulation methods that are adapted to each patient.

An example of subject may deliver a therapy by delivering energy to tissue. The system may comprise a magnetic field system and an electric field system. The magnetic field system may be configured to provide a magnetic field in a first direction to the tissue. The magnetic field system may include at least one magnetic field source to produce the magnetic field. The magnetic field produced by the at least one magnetic field source may include a magnetic field produced by at least one of a permanent magnet, a temporary magnet or electric current flow through a conductor. The electric field system may be configured to provide an electric field in a second direction to the tissue. The electric field system may include at least one electric field source to provide the electric field and the second direction is non-parallel to the first direction.

An example of subject may deliver a therapy by delivering energy to tissue. The system may comprise a magnetic field system and an electric field system. The magnetic field system may be configured to provide a magnetic field in a first direction to the tissue. The magnetic field system may include at least one magnetic field source to produce the magnetic field. The magnetic field produced by the at least one magnetic field source may include a magnetic field produced by at least one of a permanent magnet, a temporary magnet or electric current flow through a conductor. The electric field system may be configured to provide an electric field in a second direction to the tissue. The electric field system may include at least one electric field source to provide the electric field and the second direction is non-parallel to the first direction.

The present invention relates to a stimulation apparatus for applying electrical stimulation to a subject for stimulation application. Specifically, a stimulation apparatus according to the present invention comprises: a stimulation part comprising a first conductive member and a first surface which comes into contact with a subject for stimulation application and to which an alternating electric field transmitted from the subject for stimulation application upon contact is input; a conductive part comprising a second conductive member and positioned away from the stimulation part; and a connecting member for electrically connecting the stimulation part and conductive part.

A method for deactivating circulating cancer cells (CTCs). The method includes reducing viability of CTCs and/or destroying CTCs by applying a positive electrostatic field to bloodstream of a cancer patient.