Various embodiments of a ventricular assist system and a method of using such system are disclosed. The system includes a pump adapted to be connected to a heart of a patient, an outflow cannula including a first end adapted to be connected to an outlet of the pump and a second end adapted to be connected to an artery of the patient, and an electrode disposed on an outer surface of the outflow cannula and adapted to be disposed adjacent to an exterior wall of the heart. The system further includes a controller electrically connected to the pump and the electrode, where the controller is adapted to provide a pacing signal to the electrode.

The electronic device using a low frequency according to an embodiment of the present disclosure may include: a belt; a cable including a first line extending in a first direction and a second line extending from between one end and the other end of the first line in a second direction crossing the first direction; a first pad detachably attached to a rear surface of the belt and connected to the one end of the first line on the rear surface of the belt; a second pad detachably attached to the rear surface of the belt and connected to the second line on the rear surface of the belt; and a control box detachably attached to the belt and including a processor, wherein the other end of the first line passes through the belt and is connected to the control box on the front surface of the belt, and a position to which the first pad is attached on the rear surface of the belt and a position to which the second pad is attached on the rear surface of the belt are adjustable.

A smooth muscle stimulation device is intended for use with any one of a variety of electrosurgical units (ESU's) of the type used in tissue resection and other procedures that risk damage to non-target tissues. The smooth muscle stimulation devices typically include an enclosure with stimulation circuitry configured to generate a stimulatory electrical signal which when delivered to a target anatomy induces an observable response in the target anatomy during a medical procedure. An input connector on the enclosure detachably couples to a power output of the ESU, and an output connector on the enclosure detachably couples to an electrosurgical tool. Switching circuitry within the enclosure selectively connects either the power output of the ESU or the stimulatory electrical signal of the stimulation circuitry to the output connector in response to user input.

The present invention defines a device for the treatment of dysphagia comprising a flexible member mounting an imaging device for insertion into a patient and one or more electrodes proximate the imaging device for imparting electrical stimulation to the patient.

The present disclosure provides electroporation systems and methods of preconditioning tissue for electroporation therapy. An electroporation generator includes an electroporation circuit, a preconditioning circuit, and a controller. The electroporation circuit is configured to be coupled to a catheter for delivering the electroporation therapy to target tissue of the patient. The electroporation circuit is further configured to transmit an electroporation signal through the catheter. The preconditioning circuit is configured to be coupled to a preconditioning electrode for stimulating skeletal muscle tissue of the patient. The preconditioning circuit is further configured to transmit a preconditioning signal to the preconditioning electrode. The controller is coupled to the electroporation circuit and the preconditioning circuit, and is configured to synchronize transmissions of the electroporation signal and the preconditioning signal such that the preconditioning signal is transmitted prior to transmission of the electroporation signal.

A noxipoint stimulating device uses light, mechanical force, and heat as a source of stimulating energy, which is configured to be applied on the Noxipoints.

A method of reducing pain and induce/enhance the stem cell growth/differentiation reaction includes identifying a pair of related Noxipoints on an identified muscle/organ and applying a chemical/electrical stimulation to the pair of Noxipoints.

A method for maintaining and/or increasing body temperature of a patient may involve delivering heat to a first location on a limb of the patient, delivering heat to a second location on the limb, apart from the first location, and applying intermittent compression to a third location on the limb, located between the first location and the second location. A device for maintaining and/or increasing body temperature of a patient may include a sleeve for positioning over at least part of one of the patient's limbs, first and second heat delivery members coupled with the sleeve, and an intermittent compression member coupled with the sleeve between the first and second heat delivery members.

An electrical stimulation system includes a stimulator having at least one electrode and a power supply. The electrode is connectable to the power supply, and the power supply delivers electrical stimulation energy in the form of a capacitive discharge voltage through the stimulator and electrode to tissue proximate a target anatomy to induce an observable response in the target anatomy during a medical procedure.

Apparatus and methods for treating back pain are provided, in which an implantable stimulator is configured to communicate with an external control system, the implantable stimulator providing a neuromuscular electrical stimulation therapy designed to cause muscle contraction to rehabilitate the muscle, restore neural drive and restore spinal stability; the implantable stimulator further including one or more of a number of additional therapeutic modalities, including a module that provides analgesic stimulation; a module that monitors muscle performance and adjusts the muscle stimulation regime; and/or a module that provides longer term pain relief by selectively and repeatedly ablating nerve fibers. In an alternative embodiment, a standalone implantable RF ablation system is described.