A stimulator and a method using electrical stimulation of a spinal cord, for providing positive regulation of multiple symptoms other than pain is disclosed. An example method includes positioning a first pair of implantable electrodes to a dura matter in an epidural space proximate to a subject's spinal cord at predetermined locations, positioning a second pair of implantable electrodes to the dura matter in the epidural space proximate to the subject's spinal cord at predetermined locations, and transmitting signals of first and second frequencies through the first and second pairs of implantable electrodes respectively, so that the signals of the first and second frequencies interfere with each other to produce at least one beat signal proximate to the subject's spinal cord. The at least one beat signal has a frequency within a range of more than 250 Hz to about 15,000 Hz.

The present invention provides a wearable device, a system for manufacturing a wearable device and a method of neural activity control. The device for temporal interference simulation includes a pair of electrodes at penalizable location. The electrodes each send out a high frequency electromagnetic fields with a very slight difference in the two frequencies. The fields superimpose at a specified region of the brain, which is customized depending on the location of neural activity control, to create a low frequency refractory wave envelope. The low frequency wave inhibits or stimulates local neurons to control electrical activity within that region.

An example method for spinal cord stimulation treatment includes positioning eight implantable electrodes to a dura matter in an epidural space proximate to a subject's spinal cord so that (i) a first circuit is created between a first and second electrode on a first channel, (ii) a second circuit is created between a third and fourth electrode on a second channel, (iii) a third circuit is created between a fifth and sixth electrode on a third channel, and (iv) a fourth circuit is created between a seventh and eighth electrode on a fourth channel, transmitting signals through the first and second circuits that interfere to produce a first beat signal, transmitting signals through the third and fourth circuits that interfere to produce a second beat signal, and interaction of the first and second beat signals results in a combined beat signal proximate to and/or within the subject's spinal cord.

An interferential current therapy kit for treatment of a patient following an orthopedic shoulder surgery includes, within a container for facilitating the distribution and transport of the kit, a first plurality of electrodes, a second plurality of electrodes and an interferential current therapy control unit. The interferential current therapy control unit is configured to supply interferential current electrical impulses, via the electrodes, so as to give rise to at least one first beat impulse acting on the suprascapular nerve of the patient and so as to give rise to the at least one second beat impulse acting on at least one of an axillary nerve and a supraclavicular nerve of the patient.

A method including transcutaneously measuring motility patterns, in the colon of a recipient of an implantable neuromodulator, responsive to an electrical stimulus delivered by the implantable neuromodulator, and programming the implantable neuromodulator responsive to the measured motility patterns, wherein the method comprises adjusting at least one parameter of the implantable neuromodulator that defines the electrical stimulus that the implantable neuromodulator is configured to deliver to the recipient.

In illustrative implementations of this invention, interferential stimulation is precisely directed to arbitrary regions in a brain. The target region is not limited to the area immediately beneath the electrodes, but may be any superficial, mid-depth or deep brain structure. Targeting is achieved by positioning the region of maximum envelope amplitude so that it is located at the targeted tissue. Leakage between current channels is greatly reduced by making at least one of the current channels anti-phasic: that is, the electrode pair of at least one of the current channels has a phase difference between the two electrodes that is substantially equal to 180 degrees. Pairs of stimulating electrodes are positioned side-by-side, rather than in a conventional crisscross pattern, and thus produce only one region of maximum envelope amplitude. Typically, current sources are used to drive the interferential currents.

An electrical stimulation control circuit including a pulse generator, a processing circuit and an electrode is provided. The pulse generator is configured to generate a switching signal. The processing circuit generates an energy signal according to the switching signal. The electrode is configured to contact the skin of a living body and includes a first comb electrode and a second comb electrode. The first comb electrode receives the energy signal and includes a plurality of first electrodes. The first electrodes are electrically connected to each other and extended along a first direction. The second comb electrode receives a ground signal and includes a plurality of second electrodes. The second electrodes are electrically connected to each other and extended along a second direction opposite to the first direction. The first electrodes and the second electrodes are arranged in a staggered manner and electrically insulated from each other.

Systems and methods for treating symptoms of an inflammatory gastrointestinal disease in a patient with transcutaneous stimulation of a peripheral nerve are disclosed. The method can include any number of positioning a first peripheral nerve effector on the patient's skin to stimulate the peripheral nerve of the patient, delivering a first electrical nerve stimulation signal transcutaneously to the peripheral nerve through the first peripheral nerve effector, and modifying at least one brain or spinal cord autonomic feedback loop relating to release of neurotransmitters from the autonomic nervous system that modulate synthesis of inflammatory biomarkers and reduce inflammation relating to the inflammatory gastrointestinal disease.

Ultrasound (US) apparatus and method for applying low energy US onto an internal tissue/organ, including a non-invasive US appliance used on a treatment region over the internal tissue/organ, and an electrical stimulation apparatus for simultaneously inducing interferential electrical stimulation. A controller controls parameters of the electrical stimulation apparatus and the US appliance, and dynamically changes at least one of the parameters, for maintaining the impedance of the body tissue in the treatment region within an impedance range. The US apparatus includes an impedance monitoring apparatus for continuously measuring, tracking, and monitoring impedance in the treatment region, wherein the controller dynamically changes at least one of the parameter in response to the impedance as monitored, for maintaining the impedance within the predefined range. The internal tissue/organ can be a female fertility organ which can be an ovarian follicle, a blood vessel of the uterus (womb), the ovary, the endometrial lining, and the Fallopian tube; a lung, a pulmonary organ, an adipose tissue, ulcer, closed wound, internal injury, inflammation. and nerves.

An example system for exciting a selected set of motor neurons of a patient comprises one or more signal generators configured for generating a first electrical signal and a second electrical signal; a first set of wires configured to provide the first electrical signal to a first set of electrodes, wherein the first set of electrodes are configured for being secured to a first set of positions on the patient; a second set of wires configured to provide the second electrical signal to a second set of electrodes, wherein the second set of electrodes are configured for being secured to a second set of positions on the patient; and a controller configured to control operation of the one or more signal generators. The first electrical signal is a periodic signal of a first frequency. The second electrical signal is a periodic signal of a second frequency. The first frequency and the second frequency differ by a non-zero frequency difference. The first signal is provided to the first electrodes and the second signal is provided to the second electrodes for exciting the set of motor neurons of the patient.