The invention features methods and devices useful for stimulating brain tissue in a subject via electrodes within cranial bone. These methods and devices may be utilized for the detection, prevention, and/or treatment of neurological disorders via electric stimulation. Additionally, the methods and devices disclosed herein may be useful for the treatment, inhibition, and/or arrestment of the growth of tumors.

An implantable pulse generator (IPG) is disclosed having a plurality of electrode nodes, each electrode node configured to be coupled to an electrode to provide stimulation pulses to a patient's tissue. The IPG includes a digital-to-analog converter configured to amplify a reference current to a first current specified by first control signals; a first resistance configured to receive the first current, wherein a voltage across the first resistance is held to a reference voltage at a first node; a plurality of branches each comprising a second resistance and configured to produce a branch current, wherein a voltage across each second resistance is held to the reference voltage at second nodes; and a switch matrix configurable to selectively couple any branch current to any of the electrode nodes via the second nodes.

A method of treating cardiovascular disease in a patient includes generating, by an implantable stimulator configured to be implanted beneath a skin surface of the patient, stimulation sessions at a duty cycle that is less than 0.05 and applying, by the implantable stimulator in accordance with the duty cycle, the stimulation sessions to a location, within the patient, that is associated with the cardiovascular disease. The duty cycle is a ratio of T3 to T4. Each stimulation session included in the stimulation sessions has a duration of T3 minutes and occurs at a rate of once every T4 minutes.

A system and method for restoring inspiratory muscle function to restore breathing and expiratory muscle function to restore an effective cough in the same individual, wherein the systems that selectively activate the inspiratory or expiratory muscle function are separately ground to limit or prevent the flow of electrical current to both the expiratory and inspiratory muscles at the same time and to avoid damaging either neuromuscular system. Also described is the method by which the inspiratory or expiratory muscles are activated selectively to optimize the action of the inspiratory muscles to restore breathing and to optimize the action of the expiratory muscles to restore cough.

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.

Systems and methods for active charge-balancing for high frequency neural stimulation are disclosed. One illustrative method described herein includes: applying, through a pair of electrodes electrically coupled to a bundle of nerve fibers during a stimulation phase of a neural stimulation procedure, a first current to the bundle of nerve fibers; applying, through the pair of electrodes during a recovery phase of the neural stimulation procedure, a second current to the bundle of nerve fibers, the first current and the second current having opposite polarities; determining sampled voltages between the pair of electrodes during the stimulation phase, during the recovery phase, or between the stimulation phase and the recovery phase; determining a charge buildup in the bundle of nerve fibers based on the sampled voltages; applying, through the pair of electrodes during the stimulation phase or during the recovery phase, a delta current to the bundle of nerves based on the sampled voltages to minimize the charge build up.

Medical devices and methods of medical treatment for the electrical stimulation of target nerves to enhance waste clearance in the brain for treating neurological disorders such as Alzheimer's disease (AD), including prodromal, mild cognitive impairment (MCI) and early stage Alzheimer's disease.

A system and method for treating pain without paresthesia by spinal cord stimulation.

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.

Wirelessly powered and controlled implantable stimulator system in accordance with embodiments of the invention are described. One embodiment includes: a transmitter (TX) coil wirelessly powering and controlling several implantable stimulators though electromagnetic waves that include modulated waveforms that include n-bit passcodes to individually control stimulation of each of the plurality of implantable stimulators; where an implantable stimulator of the several implantable stimulators includes: a receiver (RX) for receiving a modulated waveform from the TX coil, where the implantable stimulator is controlled based on the modulated waveform.