Embodiments of the present disclosure provide a biofield apparatus. The apparatus includes a first vial and a second vial configured to hold fluid for storing biofield information associated with a subject. The apparatus includes an input plate and an output plate. The input plate and the output plate include an input plate vial well and an output plate vial well, respectively. The apparatus includes a control unit configured to provide a first signal to the input plate for capturing the biofield information from the subject. The control unit encodes and transmits the biofield information captured from the subject, to the fluid within the first vial. Further, the control unit amplifies the biofield information within the first vial based on a target amplification level. The control unit transmits the biofield information from the fluid within the second vial to the subject for enhancing the biofield information and properties of the subject.

The invention relates to electret implant and to electrotherapy using static electricity of electret coatings for treatment of arthrosis of different joints: knee, hip, and shoulder, including for the arthrosis treatment of small bones of arms and legs. The inventive electret implant includes an extended body with a proximal and a distal end. On surface of the body a dielectric coating in an electret state is formed. The implant, wherein its body is implemented as a rod, at the proximal end of which a frontal surface is formed, and the fixation device of the implant in the hole in the bone can be made at the distal end. The bushing, wherein on its outer surface a thread for its set is made in the hole in the bone, and on its inner surface a thread for fixation of the electret implant in the hole is made.

The invention relates to electret implant and to electrotherapy using static electricity of electret coatings for treatment of arthrosis of different joints: knee, hip, and shoulder, including for the arthrosis treatment of small bones of arms and legs. The inventive electret implant includes an extended body with a proximal and a distal end. On surface of the body a dielectric coating in an electret state is formed. The implant, wherein its body is implemented as a rod, at the proximal end of which a frontal surface is formed, and the fixation device of the implant in the hole in the bone can be made at the distal end. The bushing, wherein on its outer surface a thread for its set is made in the hole in the bone, and on its inner surface a thread for fixation of the electret implant in the hole is made.

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.

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.

A device for relieving pains and spasms by applying electrical pulses which makes it possible to render the electrical pulses easier to tolerate by limiting or preventing the painful or untimely discharges which hamper the use of the relief device. The relief device delivers electrical pulses only when it bears or rolls in a back-and-forth movement on the skin or clothing of a user. The relief device comprises means for limiting the maximum voltage delivered to the user, one or more means of triggering the pulses delivered by the electrodes, an activation delayer and a system for progressively launching the potential delivered by the electrodes.

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.

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.

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.