A method for providing electrical stimulation to a user as a user performs a set of tasks during a time window, the method comprising: providing an electrical stimulation treatment, characterized by a stimulation parameter and a set of portions, to a brain region of the user in association with the time window; for each task of the set of tasks: receiving a signal stream characterizing a neurological state of the user; from the signal stream, identifying a neurological signature characterizing the neurological state associated with the task; and modulating the electrical stimulation treatment provided to the brain region of the user based upon the neurological signature, wherein modulating comprises delivering a portion of the set of portions of the electrical stimulation treatment to the brain region of the user, while maintaining an aggregate amount of the stimulation parameter of the treatment provided during the time window below a maximum limit.

A system for percutaneously applying electrical stimulation to target nerve tissue to treat a patient having peripheral neuropathy includes a percutaneous electrode assembly, a power supply, and a pulse generator electrically coupled to the percutaneous electrode assembly and the power supply, the pulse generator configured to deliver electrical stimulation to the target nerve tissue via the percutaneous electrode assembly at a level that initiates vasodilation of vasculature within or adjacent the target nerve tissue, where the vasculature is responsible for perfusing the target nerve tissue and the electrical stimulation is delivered with a carrier frequency in the range of 25 kHz to 500 kHz.

The invention relates to medicine, The technical result of the present invention is to increase the efficiency of treatment of the respiratory system pathologies. The system includes a communication unit connected to a ventilator, a human-machine interface unit, a data processing, storage and management unit, an algorithmic unit, a pulse generation unit, a unit of electromyography electrodes and a stimulation.

A method for variable electrostimulative behavior modification includes sensing placement of a first anatomical portion of a body in contact to a surface of a target object adapted for behavior modification with a multiplicity of electrostimulative end points coupled to an energy source. The method additionally includes delivering an electrical neurostimulus through one of the end points nearest to the placement of the first anatomical portion in proximity to the surface the electrical neurostimulus including a waveform promoting a modification of behavior associated with the placement of the first anatomical portion in proximity to the surface. Thereafter, an anomalous characteristic of the sensed placement indicating a failure to modify the behavior may be detected and a profile of the waveform of the electrical neurostimulus changes to a different waveform in response to the anomalous characteristic of the sensed placement.

Neuromodulation catheter systems with controlled irrigation capabilities and methods for using such systems are disclosed herein. One such method includes, for example, positioning an irrigated neuromodulation catheter at a treatment site within a renal blood vessel of a human patient, delivering neuromodulation energy at the treatment site, and delivering irrigation fluid to the treatment site having characteristics coordinated with the delivered energy. The characteristics can be adjusted to maintain an energy delivery element and/or tissue of the blood vessel at a constant temperature as power is increased. The method can further include monitoring at least one parameter of the tissue and/or of the energy delivery element, and adjusting the neuromodulation energy and/or the characteristics of the irrigation fluid if the at least one parameter falls outside of a treatment range of values.

Techniques are disclosed for using a cardiac signal sensed via a plurality of electrodes disposed on one or more leads implanted within an epidural space of a patient to control spinal cord stimulation (SCS) therapy. In one example, an implantable medical device (IMD) senses an electrical signal via a plurality of electrodes disposed on one or more leads implanted within an epidural space of a patient. Processing circuitry determines, from the electrical signal, one or more cardiac features indicative of activity of a heart of the patient. The processing circuitry controls, based on the one or more cardiac features, delivery of SCS therapy to the patient.

Methods, implantable devices, and systems for treating a cancer or inhibiting cancer growth or recurrence in a subject are described herein. Such methods can include electrically stimulating a thoracic splanchnic nerve (such as a greater splanchnic nerve) of the subject with a plurality of electrical pulses emitted from one or more electrodes m electrical communication with the splanchnic nerve, wherein the plurality of electrical pulses triggers one or more action potentials in the splanchnic nerve to increase circulating natural killer (NK) cells in the subject. An implantable device may include one or more electrodes configured to be in electrical communication with a thoracic splanchnic nerve of a subject with cancer, and be configured to operate the one or more electrodes to electrically stimulate the splanchnic nerve with a plurality of electrical pulses that triggers one or more action potentials in the splanchnic nerve that increase circulating NK cells.

A system, device, and method for transcutaneous nerve stimulation such as facial nerve stimulation, and in particular, to using transcutaneous nerve stimulation for artificially eliciting eye blink, such as with humans with acute facial paralysis (Bell's palsy or Dry Eye syndrome), is disclosed. A battery-operated wearable device may employ a pulse generator for periodically and automatically generating bursts train of asymmetrical Bi-Phasic square pulses. The output pulses are fed to two electrodes that are attached to the skin of the treated person to stimulate the facial nerve for eliciting blinking at a rate that mimics normal blinking operation. The device may include a sensor and a wireless connection, and the parameters of, or the activation of, the generated bursts may be controlled by the sensor output, by human user control, or by data received from the wireless network. Further, the device may transmit status to the wireless network.

Tumor treating fields (TTFields) can be delivered by implanting a plurality of sets of implantable electrode elements within a person's body. Temperature sensors positioned to measure the temperature at the electrode elements are also implanted, along with a circuit that collects temperature measurements from the temperature sensors. In some embodiments, an AC voltage generator configured to apply an AC voltage across the plurality of sets of electrode elements is also implanted within the person's body.

A system and method for altering bone growth on and within an orthopedic implant comprising an implant body, wherein the implant body comprises an exterior surface and an interior surface defining an internal cavity of the implant body, a plurality of electrodes, wherein each electrode is at least partially embedded in the implant body, and comprises at least, a first set of the plurality of electrodes 116, composed of a first material, and a second set of the plurality of electrodes, composed of a second material; and a control system, comprising a processor and circuitry that connects to the plurality of electrodes, wherein the processor, through operating modes, provides machine instructions to control direction and magnitude of current traveling through each electrode from the plurality of electrodes; and a power system, comprising a power source and circuitry that provides electrical power for function of the plurality of electrodes.