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.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to a patient, the apparatus including a head mount for disposition on the head of a patient; and a plurality of magnet assemblies for releasable mounting on the head mount, wherein each of the magnet assemblies includes a magnet for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents in the brain of a patient so as to modify the natural electrical activity of the brain of the patient; wherein the number of magnet assemblies mounted on the head mount, their individual positioning on the head mount, and their selective provision of a rapidly changing magnetic field is selected so as to allow the spatial, strength and temporal characteristics of the magnetic field to be custom tailored for each patient, whereby to provide patient-specific TMS therapy, to assist in diagnosis or to map out brain function in neuroscience research.

Apparatus for applying Transcranial Magnetic Stimulation (TMS) to a patient, the apparatus including a head mount for disposition on the head of a patient; and a plurality of magnet assemblies for releasable mounting on the head mount, wherein each of the magnet assemblies includes a magnet for selectively providing a rapidly changing magnetic field capable of inducing weak electric currents in the brain of a patient so as to modify the natural electrical activity of the brain of the patient; wherein the number of magnet assemblies mounted on the head mount, their individual positioning on the head mount, and their selective provision of a rapidly changing magnetic field is selected so as to allow the spatial, strength and temporal characteristics of the magnetic field to be custom tailored for each patient, whereby to provide patient-specific TMS therapy, to assist in diagnosis or to map out brain function in neuroscience research.

The invention provides wearable devices for effecting transcranial magnetic stimulation to be used by patients who have suffered brain injuries. Permanent magnets are shifted or rotated to deliver a time-varying magnetic field, preferably about the locus of the injury. In an embodiment, the strong magnetic fields of the permanent magnets are directed to the injured area for therapeutic purposes. A novel mechanism is provided that uses a small battery-powered electromagnet to interact with the weak peripheral magnetic fields of the permanent magnets and to shift the permanent magnets between two or more stable positions. As a result, a lightweight, quiet, wearable device with low power consumption is provided.

The invention provides wearable devices for effecting transcranial magnetic stimulation to be used by patients who have suffered brain injuries. Permanent magnets are shifted or rotated to deliver a time-varying magnetic field, preferably about the locus of the injury. In an embodiment, the strong magnetic fields of the permanent magnets are directed to the injured area for therapeutic purposes. A novel mechanism is provided that uses a small battery-powered electromagnet to interact with the weak peripheral magnetic fields of the permanent magnets and to shift the permanent magnets between two or more stable positions. As a result, a lightweight, quiet, wearable device with low power consumption is provided.

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 system for applying magnetic field to anesthetize a patient is disclosed. The system comprises a first plurality of magnets positioned below a surgical bed to apply the magnetic field when the patient lies on the surgical bed; a second plurality of magnets coupled to one or more reciprocating units and provided operatively below the surgical bed, and one or more ultrasound probes positioned between the first plurality of magnets to measure the spinal cord's depth. The reciprocating units are configured to facilitate a reciprocal movement the second plurality of magnets, thereby moving the second plurality of magnets towards and away from the patient's body for facilitating variation of the magnetic field provided to the patient. The variation of the magnetic field induces an electric flux within the spinal cord, thereby disrupting neurons in the spinal cord and preventing the patient from feeling any pain during a surgical procedure.

A system for applying magnetic field to anesthetize a patient is disclosed. The system comprises a first plurality of magnets positioned below a surgical bed to apply the magnetic field when the patient lies on the surgical bed; a second plurality of magnets coupled to one or more reciprocating units and provided operatively below the surgical bed, and one or more ultrasound probes positioned between the first plurality of magnets to measure the spinal cord's depth. The reciprocating units are configured to facilitate a reciprocal movement the second plurality of magnets, thereby moving the second plurality of magnets towards and away from the patient's body for facilitating variation of the magnetic field provided to the patient. The variation of the magnetic field induces an electric flux within the spinal cord, thereby disrupting neurons in the spinal cord and preventing the patient from feeling any pain during a surgical procedure.

A device for measuring electrophysiological data includes: a series of electrodes; a control circuit including a DC voltage source connected to the electrodes in order to apply, to a pair of electrodes, DC voltage pulses, and in order to connect another high-impedance electrode; and a measurement circuit for measuring the potential of the electrodes and data representative of the current passing through at least one active electrode. The device further includes at least one base incorporating the control circuit and the measurement circuit, and a housing suitable for receiving an electrode assembly which includes at least one electrode of the series in a removable manner, so as to be able to connect or disconnect the electrodes to/from the control circuit and to/from the measurement circuit.

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 the at least one magnetic assembly device.