Process and electrostimulation equipment employed in controlling pains of various etiologies, the process predicting the development of an electrostimulation protocol in which the variation of electrical pulses intensity is performed in a random fashion, respecting the limits of stimulation efficiency, in order to reduce the physiological phenomenon of nerve fiber accommodation to the stimuli, the electrostimulation portable equipment, having of a bandage, and having a central electronic module and two lateral flaps, which contain the respective electrodes covered by gel layers removable protective sheets. The module houses the internal components and the electric circuit equipment, power battery, which is a coin-shaped lithium-ion battery. The equipment includes power source, step-up regulator, micro controller, power supply seal, boost source, H-bridge, and electrode output, and switch off module.

This specification describes systems, methods, devices, and other techniques for activating muscle groups in a mammal using an implantable epidural electrical stimulation (EES) system, and for using spinal landmarks to determine implant locations for an EES probe. In some aspects, a first set of electrodes of an EES system is provided at a first set of locations on the dura mater of a spine of a mammal, the first set of locations on the dura mater corresponding to a first muscle group of the mammal, a second set of electrodes is provided at a second set of locations on the dura mater of the spine of the mammal, the second set of locations on the dura mater corresponding to a second muscle group of the mammal, and the first and second sets of locations on the dura mater are stimulated by electrically energizing the first and second sets of electrodes.

This invention relates generally to systems and methods for multifocal direct brain stimulation to enhance cognitive processing, such as but not limited to stimulation-induced modulation of memory.

A system for treating a patient comprises a stimulator for stimulating brain tissue, a controller for setting stimulation parameters and a diagnostic tool for measuring patient parameters and producing diagnostic data. The stimulation parameters comprise test stimulation parameters and treatment stimulation parameters. The stimulator delivers test stimulation energy to the brain tissue based on at least one test stimulation parameter and delivers treatment stimulation energy to the brain tissue based on at least one treatment stimulation parameter. One or more treatment stimulator parameters are determined based on the diagnostic data produced by the diagnostic tool The system is constructed and arranged to treat a neurological disease or a neurological disorder. Methods of treating a neurological disease or neurological disorder are also provided.

A durable nerve cuff electrode for achieving block of an action potential in a large diameter nerve.

The disclosure relates to an electrical stimulation therapy method. The method includes applying a variable frequency stimulation pulse to target nerve tissue of the patient suffering from dysfunction of a nerve circuit in the brain selected from the group consisting of motor circuit, associative circuit and limbic circuit, wherein the variable frequency stimulation pulse comprises at least two kinds of electrical stimulation pulse trains at different frequencies; and each of the at least two kinds of alternate electrical stimulation pulse trains in each of the plurality of pulse train periods has a duration in a range from about 0.1 seconds to about 60 minutes. The target nerve tissue is a part of the nerve circuit. The different frequencies of the electrical stimulation pulse trains are in a range from about 10 Hz to about 250 Hz.

A medical device provides stimulation therapy to a patient based on a set of therapy parameters. One or more therapy parameters may be automatically adjusted based on acceleration forces detected by a sensor, the acceleration forces being applied to the patient. In some examples, adjustments to one or more therapy parameter may be made based on an algorithm. The algorithm may be defined by acceleration and therapy parameter value pairs associated with opposite patient positions.

An energy supplying component (100) includes a plurality of power sources (161, 171, 181, 191) and at least one switch (163, 165, 167, 173, 175, 177, 183, 185, 187, 193, 195, 197). Each power source of the plurality of power sources is configured to output a defined energy level. The at least one switch is configured to reversibly combine two or more power sources of the plurality of power sources for enabling the energy supplying component to supply requested energy at one or both of a needed voltage or a needed current.

There is disclosed a device and method for delivering constant target current to a muscle for electro-stimulation of that muscle. One device is a completely self-contained device with no external means for the adjustment and control of the electro-stimulation delivered to the muscle during treatment. The microprocessor based device monitors indirectly the actual current delivered to the muscle during electro-stimulation via measurement of the return path voltage through the muscle and optionally in addition monitors and adjusts for the internal battery voltage during use of the device in order to deliver a more consistent an accurate and effective target output current to the muscle being stimulated at each and every pulse delivered from the device. The device is pre-programmed with an electro-stimulation treatment cycle and the whole treatment cycle, including the monitoring and adjustment required to achieve this treatment cycle, is automatic within the device.

A method of downregulating and/or upregulating neural activity by applying a high frequency alternating current electrical signal to a nerve in a subject is disclosed. The signal comprises more than one microsecond cycle comprising one or more periods, each period comprising a charge recharge phase, and optionally, a pulse delay, each period having a frequency of at least 1000 Hz; and a microsecond inactive phase. In embodiments, an electrical signal treatment comprises more than one microsecond cycle to form a millisecond cycle, each millisecond cycle separated by a millisecond inactive phase during an on time. In embodiments, the electrical signal patterns can differ in amplitude.