A resonant energy stabilizer contains: a body, a lid, a mineral crystal, the current amplifier, and a medium frequency current device. The body includes an accommodation chamber. The lid includes an accommodating room. The mineral crystal includes a recess configured to accommodate a sapphire for producing far-infrared waves of electrostatic pulse. The recess is surrounded by a white crystal, a citrine and a green crystal which are surrounded by multiple titanium crystals, and a first magnetite is located above the white crystal, the citrine and the green crystal. The current amplifier includes multiple plasma pieces stacked together to increase a distance of the far-infrared waves of the electrostatic pulse, and each plasma piece has a copper coil layer, a red brass patch, and a red copper sheet. The medium frequency current device includes multiple second magnetites, an input segment, a central processing unit, a booster, and an output segment.

Various embodiments of the present disclosure are directed towards a therapeutic furniture apparatus. The therapeutic furniture apparatus includes a non-magnetic base. The non-magnetic base has a vertical portion that extends vertically from the base, and a horizontal portion that extends from the vertical portion at a first location over the non-magnetic base. A non-magnetic ring attachment structure is coupled to the horizontal portion of the non-magnetic support structure at a second location disposed directly over the non-magnetic base. The non-magnetic ring attachment structure extends from the horizontal portion toward the non-magnetic base. A plurality of non-magnetic ring structures are coupled to the non-magnetic ring attachment structure and disposed between the horizontal portion of the non-magnetic support structure and the non-magnetic base. A plurality of permanent magnets are disposed at regular intervals on each of the plurality of non-magnetic ring structures.

Various embodiments of the present disclosure are directed towards a therapeutic furniture apparatus. The therapeutic furniture apparatus includes a non-magnetic base. The non-magnetic base has a vertical portion that extends vertically from the base, and a horizontal portion that extends from the vertical portion at a first location over the non-magnetic base. A non-magnetic ring attachment structure is coupled to the horizontal portion of the non-magnetic support structure at a second location disposed directly over the non-magnetic base. The non-magnetic ring attachment structure extends from the horizontal portion toward the non-magnetic base. A plurality of non-magnetic ring structures are coupled to the non-magnetic ring attachment structure and disposed between the horizontal portion of the non-magnetic support structure and the non-magnetic base. A plurality of permanent magnets are disposed at regular intervals on each of the plurality of non-magnetic ring structures.

A magnetic stimulation system may include first and second subsystems. The first subsystem may include a first stimulator, a first coil, and a first processor configured to determine stimulation parameter data for a subject. The second subsystem may include a second stimulator, a headpiece including an identifier and a second coil mounted to a headpiece body at a fixed location, an image recording device, and a second processor configured to: receive first image data for one or more first images of the subject and headpiece; receive, from the image recording device, second image data for one or more second images of the subject and headpiece; determine, using the first and second image data, that the stimulation parameter data corresponds to the subject; determine, using the second image data, that the headpiece corresponds to the subject; and determine, using the second image data, that the headpiece is at a pre-determined position.

A magnetic stimulation system may include first and second subsystems. The first subsystem may include a first stimulator, a first coil, and a first processor configured to determine stimulation parameter data for a subject. The second subsystem may include a second stimulator, a headpiece including an identifier and a second coil mounted to a headpiece body at a fixed location, an image recording device, and a second processor configured to: receive first image data for one or more first images of the subject and headpiece; receive, from the image recording device, second image data for one or more second images of the subject and headpiece; determine, using the first and second image data, that the stimulation parameter data corresponds to the subject; determine, using the second image data, that the headpiece corresponds to the subject; and determine, using the second image data, that the headpiece is at a pre-determined position.

A system for restoring muscle function to the lumbar spine to treat low back pain is provided. The system may include one or more electrode leads coupled to an implantable pulse generator (IPG) and a tunneler system for subcutaneously implanting a proximal portion of the lead(s). The system may also include a handheld activator configured to transfer a stimulation command to the IPG, and an external programmer configured to transfer programming data to the IPG. The stimulation command directs the programmable controller to stimulate the tissue in accordance with the programming data. The system may include a software-based programming system run on a computer such that the treating physician may program and adjust stimulation parameters.

A system for restoring muscle function to the lumbar spine to treat low back pain is provided. The system may include one or more electrode leads coupled to an implantable pulse generator (IPG) and a tunneler system for subcutaneously implanting a proximal portion of the lead(s). The system may also include a handheld activator configured to transfer a stimulation command to the IPG, and an external programmer configured to transfer programming data to the IPG. The stimulation command directs the programmable controller to stimulate the tissue in accordance with the programming data. The system may include a software-based programming system run on a computer such that the treating physician may program and adjust stimulation parameters.

The disclosure provides methods of cancer treatment and apparatus and, more particularly, to non-invasive cancer treatments utilizing oscillating magnetic fields to disrupt mitochondrial function or induce apoptosis or another mechanism of cell death in cancer cells. The disclosure also provides a device for providing an OMF treatment to a subject.

The disclosure provides methods of cancer treatment and apparatus and, more particularly, to non-invasive cancer treatments utilizing oscillating magnetic fields to disrupt mitochondrial function or induce apoptosis or another mechanism of cell death in cancer cells. The disclosure also provides a device for providing an OMF treatment to a subject.

A system for restoring muscle function to the lumbar spine to treat low back pain is provided. The system may include electrodes coupled to an implantable pulse generator (IPG), a handheld activator configured to transfer a stimulation command to the IPG, and an external programmer configured to transfer programming data to the IPG. The stimulation command directs the programmable controller to stimulate the tissue in accordance with the programming data. The system may include a software-based programming system run on a computer such that the treating physician may program and adjust stimulation parameters.