This disclosure describes techniques for generation of sleep quality information based on posture state data. The techniques may include obtaining posture state data sensed by a medical device for a patient, generating sleep quality information based on lying posture state changes indicated by the posture state data, and presenting the sleep quality information to a user via a user interface.

Systems and methods for deep brain electrode placement and deep brain stimulation (DBS) for treatment of conditions such as obesity are disclosed. In one example approach, during placement of a deep brain stimulating electrode in a target region of the brain of a patient, a temperature of brown adipose tissue (BAT) may be monitored, e.g., via a supraclavicular temperature sensor implanted in the patient, and used to identify an optimal location of electrode stimulation which causes an increase in BAT temperature. Additionally, BAT temperature measurements may be used to provide regulated closed-loop control to increase efficiency of DBS while reducing energy consumption of the pulse generator. Further, core temperature measurements may be obtained from the electrode in the brain and used to adjust DBS.

In some examples, a method may include delivering an electrical stimulation therapy to a patient, the electrical stimulation therapy comprising a first electrical stimulation pulse delivered to the patient via a first electrode and a second electrical stimulation pulse delivered to the patient via a second electrode, wherein the first electrical stimulation pulse and second electrical stimulation pulse are delivered as paired pulses with respect to each other and a combination of the first electrical stimulation pulse and the second electrical stimulation pulse evoke a compound action potential within the patient; sensing the compound action potential evoked by the combination of the first electrical stimulation pulse and the second electrical stimulation pulse; and adjusting one or more parameters of the electrical stimulation therapy based on the sensed compound action potential

A method for optimization of a stimulation specificity of implanted electrodes in excitable tissue of a patient; wherein it comprises the step of electrical stimulation of excitable tissue between one or more combinations of electrode pairs in a cluster of electrodes, or electrical stimulation between one or more combinations of electrode pairs in two or more clusters of electrodes, wherein the two electrodes of said electrode pairs do not belong to the same cluster, wherein the electrical stimulation between different combinations of electrode pairs in a cluster of electrodes, or the electrical stimulation between different combinations of electrode pairs in two or more clusters of electrodes, creates a directed electrical field; wherein the effect of the directed electrical field is assessed after each stimulation step by registering information provided from the patient in view of a therapeutic effect, or by assigning each electrode pair a value related to said information provided by the patient; and choosing, based on the direction of the directed electrical field created, the electrode pair or pairs which give(s) rise to the most favorable assigned value.

This disclosure describes techniques for generation of sleep quality information based on posture state data. The techniques may include obtaining posture state data sensed by a medical device for a patient, generating sleep quality information based on lying posture state changes indicated by the posture state data, and presenting the sleep quality information to a user via a user interface.

An exemplary method of treating obesity or dyslipidemia of a patient includes 1) generating, by an electroacupuncture device implanted beneath a skin surface of the patient, stimulation sessions at a duty cycle that is less than 0.05, and 2) applying, by the electroacupuncture device in accordance with the duty cycle, the stimulation sessions to at least one of a saphenous nerve and a peroneal nerve of the patient by way of an electrode array located within the patient at an acupoint corresponding to at least one of the saphenous nerve and the peroneal nerve.

Systems and methods for deep brain electrode placement and deep brain stimulation (DBS) for treatment of conditions such as obesity are disclosed. In one example approach, during placement of a deep brain stimulating electrode in a target region of the brain of a patient, a temperature of brown adipose tissue (BAT) may be monitored, e.g., via a supraclavicular temperature sensor implanted in the patient, and used to identify an optimal location of electrode stimulation which causes an increase in BAT temperature. Additionally, BAT temperature measurements may be used to provide regulated closed-loop control to increase efficiency of DBS while reducing energy consumption of the pulse generator. Further, core temperature measurements may be obtained from the electrode in the brain and used to adjust DBS.

The disclosed wearable device modulates a patient's gastric emptying time and/or gastric retention time. The wearable device includes a microprocessor, electrical stimulator and at least one electrode configured to deliver electrical stimulation to the epidermis, through a range of 0.1 mm to 10 mm or a range of 0.1 mm to 20 mm of the dermis, of a T2 dermatome to a T12 dermatome or meridian of the patient, a C5 to a T1 dermatome across the hand and/or arm, and/or the upper chest regions. The device is adapted to provide electrical stimulation as per stimulation protocols and to communicate wirelessly with a companion control device configured to monitor and record appetite patterns of the patient. The control device is also configured to monitor, record, and modify stimulation parameters of the stimulation protocols.

In some examples, a method may include delivering an electrical stimulation therapy to a patient, the electrical stimulation therapy comprising a first electrical stimulation pulse delivered to the patient via a first electrode and a second electrical stimulation pulse delivered to the patient via a second electrode, wherein the first electrical stimulation pulse and second electrical stimulation pulse are delivered as paired pulses with respect to each other and a combination of the first electrical stimulation pulse and the second electrical stimulation pulse evoke a compound action potential within the patient; sensing the compound action potential evoked by the combination of the first electrical stimulation pulse and the second electrical stimulation pulse; and adjusting one or more parameters of the electrical stimulation therapy based on the sensed compound action potential.

In an electric taste adjustment device that adjusts taste using electrical signals when eating or drinking, electrodes must be attached in order to apply electrical signals. An electric taste adjustment device is provided to eliminate this hassle. The electric taste adjustment device 1 is attached to a food container, and when the food container is taken into the mouth, the electrodes 1 and 2 connected to the electric taste adjustment device 1 contact an upper mandible and a mandibular base, respectively, to apply an electric signal. This makes it easy to attach electrodes for taste adjustment.