A method of treating an ailment suffered by a patient using one or more electrodes adjacent spinal column tissue of the patient, comprises delivering electrical modulation energy from the one or more electrodes to the spinal column tissue in accordance with a continuous bi-phasic waveform having a positive phase and a negative phase, thereby modulating the spinal column tissue to treat the ailment. An implantable electrical modulation system, comprises one or more electrical terminals configured for being coupled to one or more modulation leads, output modulation circuitry capable of outputting electrical modulation energy to the electrical terminal(s) in accordance with a continuous bi-phasic waveform, and control circuitry configured for modifying a shape of the continuous bi-phasic waveform, thereby changing the characteristics of the electrical modulation energy outputted to the electrode(s).

Systems and methods for optimizing neuromodulation field design for pain therapy are discussed. An exemplary neuromodulation system includes an electrostimulator to stimulate target tissue to induce paresthesia, a data receiver to receive pain data including pain sites experiencing pain, and to receive patient feedback on the induced paresthesia including paresthesia sites experiencing paresthesia. The neuromodulation system includes a processor circuit configured to generate a spatial correspondence indication between the pain sites and the paresthesia sites over one or more dermatomes, determine an anodic weight and a cathodic weight for each of multiple electrode locations using the spatial correspondence indication, and generate a stimulation field definition for neuromodulation pain therapy.

Techniques are described, for medical devices that deliver electrical stimulation using current or voltage regulators having an adjustable master amplitude. One example method includes receiving, via a programmer for an electrical stimulator, user input indicating a desired electrical current amplitude, and selecting a first fraction adjustment or a second fraction adjustment, as a target adjustment for achieving the desired electrical current amplitude.

Systems, devices, and techniques for adjusting electrical stimulation are described. For example, processing circuitry is configured to receive, via a sensing electrode located at a target region of a patient, a plurality of evoked compound action potential (ECAP) signals elicited from respective electrical stimuli delivered to the patient; determine, based on the plurality of ECAP signals, an aggressor category for at least some ECAP signals of the plurality of ECAP signals, the aggressor category determined from a plurality of aggressor categories; determine, based on the aggressor category, a set of control policy parameters that at least partially define closed-loop control of stimulation therapy; and controlling delivery of the stimulation therapy according to at least the set of control policy parameters and one or more subsequent ECAP signals.

The disclosure provides systems and methods for detecting, monitoring, and/or treating obstructive sleep apnea, as well as other conditions, using vital sign and/or biometric data collected and/or imputed from one or more photoplethysmography sensors in conjunction with vital sign and/or biometric data from one or more additional sensors such as activity, body position, ECG, HR, or SpO.sub.2 levels, e.g., as feedback to control therapy and/or to titrate therapy on a periodic basis.

An example method of delivering electrical stimulation includes obtaining, by an implantable medical device (IMD) connected to a lead carrying a plurality of electrodes, one or more stimulation parameters; and delivering, by the IMD and based on the one or more stimulation parameters, electrical stimulation therapy via the plurality of electrodes, wherein delivering the electrical stimulation therapy comprises scanning delivery of the electrical stimulation therapy through different pairs of electrodes of the plurality of electrodes.

Systems, devices, and techniques are described for determining a posture state of a patient based on detected evoked compound action potentials (ECAPs). In one example, a medical device includes stimulation circuitry configured to deliver electrical stimulation and sensing circuitry configured to sense a plurality of evoked compound action potential (ECAP) signals. The medical device also includes processing circuitry configured to control the stimulation circuitry to deliver a plurality of electrical stimulation pulses having different amplitude values, control the sensing circuitry to detect, after delivery of each electrical stimulation pulse of the plurality of electrical stimulation pulses, a respective ECAP signal of the plurality of ECAP signals, and determine, based on the plurality of ECAP signals, a posture state of the patient.

A system may include an implantable device and a controller. The implantable device may include sensing-capable electrodes. The controller may be configured to receive a trigger signal indicative of a trigger to evaluate sensing capabilities of the sensing capable electrodes, respond to the received trigger signal by evaluating the sensing capabilities of the sensing-capable electrodes to assess or reassess which of the sensing-capable electrodes are available to be activated for sensing ECAPs, activate at least one of the sensing-capable electrodes that are available to be activated based on the evaluating the sensing capabilities, and sense the ECAPs using the activated ones of the sensing-capable electrodes.

A programming algorithm is disclosed to efficiently select stimulation parameters for a patient having a Deep Brain Stimulation (DBS) implant, which is especially useful in optimizing stimulation when the DBS implant includes a directional lead capable of providing simulation at a rotational angle θ. The algorithm preferably first simultaneously determines an optimal longitudinal position (Lopt) and amplitude (Iopt1) for stimulation along the lead. This occurs by the algorithm efficiently selecting various values for L and I at which stimulation can be tried on the patient and scored. Once Lopt is determined, and if rotational optimization is possible at this longitudinal position, the algorithm simultaneously determines an optimal rotational angle (θopt) and amplitude (Iopt2) for stimulation around the lead at the optimized longitudinal position Lopt. This also occurs by the algorithm efficiently selecting various values for θ and I at which stimulation can be tried on the patient and scored.

Systems and methods are provided for stimulating one or more nerves with an implantable device. The implantable device may comprise an antenna circuit including a loop antenna and a control circuit including a rectifying diode for rectifying an alternating voltage induced in the antenna circuit by an external electromagnetic field. The implantable device may also include a chargeable storage element for storing energy from the rectified voltage without using a battery. The device may also include an electrode array containing a set of electrodes for emitting an electric field using the stored energy in response to a control signal received from the control circuit. The components of the device may be affixed onto a soft polymer substrate including a linkable peripheral tab on at least two edges of a substantially rectangular body section of the substrate for forming a cuff about the one or more nerves to be stimulated.