Aspects of the present disclosure are presented for a single surgical instrument configured to grasp, seal, and/or cut tissue through application of therapeutic energy, and also detect nerves through application of non-therapeutic electrical energy. A medical device may include two jaws at an end effector, used to apply therapeutic energy and to perform surgical procedures. The therapeutic energy may be in the form of ultrasonic vibrations or higher voltage electrosurgical energy. One of the jaws may be configured to cut tissue through application of the blade. In addition, one or both of the two jaws may be configured to apply nontherapeutic energy for nerve stimulation probing. The application of therapeutic energy may be disabled while the nontherapeutic nerve stimulation energy is applied, and vice versa. The nontherapeutic nerve stimulation energy may be applied to the use of one or more probes positioned near one or both of the jaws.

The disclosure describes devices and methods for providing transdermal electrical stimulation therapy to a subject including positioning a stimulator electrode over a glabrous skin surface overlying a palm of the subject and delivering electrical stimulation via a pulse generator transdermally through the glabrous skin surface and to a target nerve or tissue within the hand to stimulate the target nerve or tissue within the hand so that pain felt by the subject is mitigated. The pulses generated during the electrical stimulation therapy may include pulses of two different magnitudes.

Electrical stimulation devices can be used to treat tinnitus. For example, tinnitus can be treated using implantable electrodes and stimulation devices for delivering electrical stimulation to a patient's cochlear region, such as the cochlear promontory. Intraosseous cochlear promontory electrode(s), endosteal electrode(s), subendosteal electrode(s), or short intracochlear electrode(s) (or a combination thereof), connected to a cochlear implant receiver/stimulator device, can provide a successful model for long-term treatment of tinnitus in a large number of patients. In some cases, patients can simply turn on the tinnitus implant when experiencing troublesome tinnitus and gain instant relief.

This document provides methods and materials for modulating afferent nerve signals to treat medical conditions such as CHF, CHF respiration, dyspnea, peripheral vascular disease (e.g., peripheral arterial disease or venous insufficiency), hypertension (e.g., age-associated hypertension, resistant hypertension, or chronic refractory hypertension), COPD, sleep apnea, and chronic forms of lung disease where muscle dysfunction is a part of the disease pathophysiology. For example, methods and materials involved in using electrical and/or chemical techniques to block or reduce afferent nerve signals (e.g., nerve signals of group III and/or IV afferents coming from skeletal muscle and/or the kidneys) are provided.

Systems and methods for implementation of a disposable miniaturized implant for treatment of Post-Operative Ileums (POI),a miniaturized implant for treating chronic GI dysmotility (e.g., dysphagia, gastroesophageal reflux disease (GERD), nausea, functional dyspepsia, blockage of transit, and gastroparesis, inflammatory bowel disease) and obesity, by providing electrical stimulation to the part of bowel going through surgery to expedite the healing process while recording the smooth muscle activities simultaneously, or providing stimulation on a treatment location of the GI tract or the branch of the vagus nerve. Systems and methods are also provided for non-invasive, transcutaneous stimulation of anatomy within the abdomen of the patient.

A system and methods utilizing electrical stimulation to achieve a desired therapeutic effect are provided. In one aspect, a method for controlling nerve activity in a subject is provided. The method includes receiving input indicating a desired therapeutic effect for at least one neural structure of a subject, and selecting, based on the input received, an electrical stimulation configured to achieve the desired therapeutic effect. The method also includes controlling a sympathetic nerve activity in the subject by delivering the electrical stimulation using electrodes positioned proximate to nerves innervating the subject's skin.

Generally discussed herein are systems, devices, and methods for providing a therapy (e.g., stimulation) and/or data signal using an implantable device. Systems, devices and methods for interacting with (e.g., communicating with, receiving power from) an external device are also provided.

A neurostimulation system having an external or an implantable pulse generator programmed to innervate a specific nerve or group of nerves in a patient through an electrode as a mode of treatment, having a patient remote that wirelessly communicates with the pulse generator to increase stimulation, decrease stimulation, and provide indications to a patient regarding the status of the neurostimulation system. The patient remote can allow for adjustment of stimulation power within a clinically effective range and for turning on and turning off the pulse generator. The patient remote and neurostimulation system can also store a stimulation level when the pulse generator is turned off and automatically restore the pulse generator to the stored stimulation level when the pulse generator is turned on.

An implantable medical lead for sacral modulation therapy is disclosed. The implantable medical lead includes a lead body having a distal portion. An electrode is electrically coupled to the lead body and configured to generate a stimulation field or to sense electrical fields. A fixation mechanism is coupled to the distal portion. The fixation mechanism is configured to anchor the implantable medical lead against an interior wall of a blood vessel. The electrode can effect the stimulation field from within the vessel to stimulate a selected sacral nerve or sense electrical signals such as muscle or nerve responses. Guided implantation of the medical lead or other medical leads through the body to a nerve of interest for neurostimulation via remote sensor is also disclosed.

Personalized network searching, in which a search query is received from a user, and a request is received to personalize a search result. Responsive to the search query and the request to personalize the search result, a personalized search result is generated by searching a personalized search object. Responsive to the search query, a general search result is generated by searching the general search object. The personalized search result and the general search result are provided to a client device, an advertisement is selected based at least in part upon the personalized search object, and the advertisement, the personalized search result, and the general search result are displayed.