A method comprises generating, by an implantable stimulator, stimulation sessions at a duty cycle that is less than 0.05 and applying, by the implantable stimulator, the stimulation sessions to a patient. 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. The implantable stimulator is powered by a primary battery having an internal impedance greater than 5 ohms.

Devices and methods for manipulating devices such as micro-scale devices are provided. The devices can include a tether of various materials surrounded by a stiff body. The tether interfaces with microscale devices to draw them against the stiff body, holding the microscale devices in a locked position for insertion into or extraction out of tissue. The tensional hook and stiff body are configurable in a multitude of positions and geometries to provide increased engagement. Such configurations allow for a range of implantation and extraction surgical procedures for the device within research and clinical settings.

A system for monitoring patient intake includes an acquisition and transmission device having an electrode configured to detect vagus nerve activity. A first internal inductive coil is configured to communicate a signal indicative of the vagus nerve activity detected by the electrode to a second external inductive coil. The system also includes a processor configured to execute instructions stored in a memory that cause the system to process the signal received by the second induction coil into data corresponding to intake of the patient and communicate the data to a server that is accessible by a clinician.

Techniques for providing therapy to a patient via electrical stimulation are described. The techniques include, for example, determining, relative to a start time of providing the electrical stimulation, one or more efficacy times that correspond to an efficacy indicator, determining, according to the efficacy times, efficacy data items for the patient, comparing the efficacy data items with the efficacy indicator, and generating, based on the comparison, a prediction of an expected response to the therapy manifesting in the patient at a prospective time.

An intra-calvarial implant (ICI) includes one or more electrodes for sensing electrical signals from a brain of a mammal and for electrically stimulating one or more regions of the brain. The electrode(s) are implanted between an outer table and an inner table of the calvarial bone without fully penetrating the inner table, at least one reference electrode, an electronic circuitry module operatively connected to the one or more electrode(s) and to the reference electrode and for controlling the sensing and the stimulating, for at least partially processing the sensed electrical signals to obtain data for storing the data and for wirelessly transmitting the data to an external receiver. The ICI also includes a power harvesting device suitably electrically connected to one or more components of the electronic circuitry module of the ICI for energizing one or more components of the ICI. An ICI system includes ICI(s) and an external controller.

A method comprises generating, by an implantable stimulator, 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 patient. 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. The implantable stimulator is powered by a primary battery located within the implantable stimulator and having an internal impedance greater than 5 ohms.

The disclosed electrical stimulation system generates interventions to assist patients in complying with a diet. 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 and deliver titrated therapy. The control device is also configured to monitor, record, and modify stimulation parameters of the stimulation protocols.

A surgical method of treating a patient is disclosed. The method comprises the steps of: cutting the patient's skin and abdominal wall; dissecting an area of the patient's intestine; and dissecting a portion of the dissected intestinal area such that intestinal mesentery connected thereto is opened in such a way that supply of blood through the mesentery to the dissected intestinal area is maintained as much as possible on both sides of the dissected portion. The method further comprises the steps of dividing the patient's intestine in the dissected portion so as to create an upstream part of the intestine with a first intestinal opening and a downstream part of the intestine with a second intestinal opening with the mesentery still maintaining a tissue connection between the upstream and downstream intestine parts.

The present invention teaches a method and apparatus for physiological modulation, including neural, gastrointestinal, renal, respiratory, and other modulation, for the purposes of treating several disorders, including obesity, depression, epilepsy, diabetes, hypertension, asthma, and other disorders. This includes implanted, percutaneous, hybrid implanted and nonimplanted, nonimplanted, noninvasive neural and neuromuscular modulators, used to deliver autonomic vector modulation to deliver optimal therapy via coordinated multi-nodal modulation at least one of the afferent and efferent neurons of the sympathetic and parasympathetic nervous systems and other nervous system pathways.

A system and method for optimizing parameters of a DBS pulse signal for treatment of a patient is provided. In predicting optimal DBS parameters, functional brain data is input into a predictor system, the functional brain data acquired responsive to a sweeping across a multi-dimensional parameter space of one or more DBS parameters. Statistical metrics of brain response are extracted from the functional brain data for one or more ROIs or voxels of the brain via the predictor system, and a DBS functional atlas is accessed, via the predictor system, that comprises disease-specific brain response maps derived from DBS treatment at optimal DBS parameter settings for a plurality of diseases or neurological conditions. One or more optimal DBS parameters are predicted for the patient based on the statistical metrics of brain response and the DBS functional atlas via the predictor system.