The present invention relates to systems for use for radio frequency ablation. The systems can include one or more of an ablation tool, power source for use with the ablation tool and a backstop for use in conjunction with the ablation tool during surgical procedures. Preferred ablation tools comprise a series of three or more blade-shaped electrodes disposed in a linear, curved, curvilinear or circular array. The backstops are useful for reducing direct physical and thermal heat transfer injuries to the patient or surgeon during procedures using radiofrequency (RF) ablation devices.

Apparatus, systems, and methods provide access to the renal pelvis of a kidney to treat renal nerves embedded in tissue surrounding the renal pelvis. Access to the renal pelvis may be via the urinary tract or via minimally invasive incisions through the abdomen and kidney tissue. Treatment is effected by exchanging energy, typically delivering heat or extracting heat through a wall of the renal pelvis, or by delivering active substances.

Described herein are elongate applicator tools adapted to be inserted into a body to deliver high voltage, sub-microsecond electrical energy to target tissue. These tools may be configured as laparoscopes, endoscopes, and/or catheters. Also disclosed herein systems including these tools and method of their operation.

The invention generally relates to systems and methods for therapeutically modulating nerves in or associated with a nasal region of a patient for the treatment of a rhinosinusitis condition.

A sub-microsecond pulsed electric field generator is disclosed. The field generator includes a controller, which generates a power supply control signal and generates a pulse generator control signal, and a power supply, which receives the power supply control signal and generates one or more power voltages based on the received power supply control signal. The field generator also includes a pulse generator which receives the power voltages and the pulse generator control signal, and generates one or more pulses based on the power voltages and based on the pulse generator control signal. In some embodiments, the controller receives feedback signals representing a value of a characteristic of or a result of the pulses and generates at least one of the power supply control signal and the pulse generator control signal based on the received feedback signals.

A robotic system for treating a patient includes a robotic arm with an end effector for treating the patient, wherein the robotic arm is configured to be movable in a space surrounding the patient, and the end effector is configured to be movable individually and co-movable with the robotic arm in said space; a sensing device for acquiring data associating with coordinates and images of the end effector and the patient; and a controller in communications with the robotic arm and the sensing device for controlling movements of the robotic arm with the end effector and treatments of the patient with the end effector based on the acquired data and a treatment plan.

An apparatus includes a shaft assembly, first and second electrode assemblies, and a controller. The shaft assembly is configured to fit in a nasal cavity of a patient. The first and second electrode assemblies are at the distal end of the shaft assembly. The second electrode assembly includes a stimulus electrode and a sensing electrode. The stimulus and sensing electrodes are positioned on opposing lateral sides in relation to the longitudinal axis of the shaft assembly. The controller is operable to generate an electrical signal to perform one or both of tissue ablation or denervation of a targeted nerve via the first electrode assembly, generate an electrical stimulus signal to stimulate the targeted nerve via the stimulus electrode of the second electrode assembly, and process a response signal received from the targeted nerve via the sensing electrode of the second electrode assembly.

Disclosed herein is a medical RF apparatus using an RF pulse, comprising an RF generator, which generates a test pulse for detecting characteristics of tissue; a monitoring unit, which monitors the change in the information on the tissue state while the test pulse is transmitted to the tissue; and a measurement unit, which determines the tissue characteristics of a patient by comparing the values monitored in the monitoring unit with the reference data; and a method for controlling the same.

A treatment apparatus includes a motorized subsystem in a handpiece housing having a rotating output shaft, an axial cam driven in rotation by the output shaft, and a push rod linearly driven by the axial cam. A cartridge is removably attachable to the handpiece housing and includes a cartridge housing, a needle assembly, a piston in the housing engaging the needle assembly and linearly driven forward by the push rod, and a first biasing member urging the piston rearward.

An electrode for electroporation comprising a plurality of electrode needles, wherein first polarity electrode needles, an electrode needle holding portion, and a syringe holding portion are provided; two or more first polarity electrode needles project from a bottom surface of a lower structural body of an outer frame support of the electrode needle holding portion toward an electroporation target side; the bottom surface of the lower structural body of the outer frame support is provided with a hole for syringe needle insertion and removal communicating with a syringe holding portion side; the syringe holding portion is provided on a side opposite to the electroporation target side of the electrode needle holding portion; and the syringe holding portion has a path for syringe needle insertion and removal, at least a portion of the path for syringe needle insertion and removal being provided with an electro-conductive portion for a second polarity.