A method for conducting intrabody surgery by means of a surgical device having a cutting arrangement actuated by a driveshaft and rotationally supported by the guide wire. A receiving cannel extends through the cutting arrangement and movably receives the guidewire. A plurality of sensors is provided within the cutting arrangement to emit signals capable of changing parameters depending on the composition of the occlusion, so as to allow the control unit to generate signals controlling operation of the cutting arrangement. The method includes the steps of detecting parameters within the intrabody area by the sensors to controlling operation of the cutting arrangement with the power and control unit.

A device for treating infection within a subject includes an ultrasound transducer for applying ultrasound to a treatment site of the subject. In some embodiments, the device transmits ultrasound in the range of greater than about 20 kHz to about 5 MHz to site of infection. For example, the device can transmit ultrasound from a location outside the body to a location inside the body, such as a sinus. The ultrasound may be suitable for removing biofilm or decreasing the viscosity of mucus. Ultrasound from the device can also have other therapeutic and diagnostic uses.

A device having an optical element with a conductive coating. The device may include an optical element, a conductive material and at least one connector. The conductive material is disposed on at least a portion of the optical element. The optical element, for example, may be an object lens of an endoscope or an optical coupler. The connectors (acting as terminal(s)) are capable of providing energy (such as electrical energy) to the conductive material. In one aspect, the conductive material is an optically transparent material. Advantageously, the device may allow visualization of an object—such as body tissue or other matter—concurrent with the application of energy to the object via the conductive coating. This allows the user to observe the alteration of tissue and other matter in real time as the energy is delivered.

Disclosed herein is a therapeutically active agent usable in the treatment of pulmonary arterial hypertension (PAH), for use in the treatment of pulmonary arterial hypertension, as well as methods of treating PAH, said treatment and methods comprising administering such an active agent and effecting pulmonary artery denervation in the subject. In some aspects, a sub-therapeutically effective amount of the active agent is administered. In some aspects, the method is devoid of administering such an active agent for at least one month subsequent to the denervation. Further disclosed is a method of treating PAH comprising determining a responsiveness of the subject to at least one therapeutically active agent usable in treating PAH; and effecting pulmonary artery denervation in a subject responsive to the active agent(s).

Apparatus and methods for deactivating renal nerves extending along a renal artery of a mammalian subject to treat hypertension and related conditions. An ultrasonic transducer (30) is inserted into the renal artery (10) as, for example, by advancing the distal end of a catheter (18) bearing the transducer into the renal artery. The ultrasonic transducer emits unfocused ultrasound so as to heat tissues throughout a relatively large impact volume (11) as, for example, at least about 0.5 cm.sup.3 encompassing the renal artery to a temperature sufficient to inactivate nerve conduction but insufficient to cause rapid ablation or necrosis of the tissues. The treatment can be performed without locating or focusing on individual renal nerves.

A catheter system for ablation of tissue around a blood vessel, e.g., the pulmonary artery, to reduce neural activity of nerves surrounding the blood vessel. The catheter system includes an elongate shaft having a proximal portion coupled to a handle, and a distal portion. The distal portion includes a transducer and an expandable anchor, which may be actuated to transition between a collapsed delivery state and an expanded deployed state where the anchor centralizes the transducer within the blood vessel. The transducer may be actuated to emit energy to reduce neural activity of the nerves surrounding the blood vessel. Systems and method are further provided for confirming that neural activity of the nerves surround the blood vessel has been sufficiently reduced.

Systems, devices and methods treat target tissue to provide a therapeutic benefit to the patient. A tissue treatment device comprises a tissue treatment element constructed and arranged to treat target tissue, such as duodenal mucosa and/or submucosal tissue. Patients treated can safely eliminate or reduce their daily insulin intake.

Regions of tissue having reduced electrical propagation are created in a bladder to affect its electrical or mechanical properties. To create these tissue regions, a tubular device is advanced through the urethra leading to the interior of the bladder, a distal expandable structure of the device is expanded to contact the inner wall of the bladder, and electrodes or other active energy delivery elements of the device are activated to deliver ablation energy. The electrodes or other active energy delivery elements are disposed over the expandable structure which is shaped to conform to the interior of the bladder. The inner wall of the organ is ablated in a predetermined pattern. The same or other electrodes disposed over the expandable structure can used to electrically map the bladder. This map of electrical activity can be used to create the predetermined pattern.

Catheter-based devices and associated methods for immune system neuromodulation of human patients are disclosed herein. One aspect of the present technology is directed to methods of treating a human patient diagnosed with an immune system condition. The methods can include intravascularly positioning a neuromodulation catheter within a blood vessel proximate to neural fibers innervating an immune system organ of the patient. The method also includes reducing sympathetic neural activity in the patient by delivering energy to the neural fibers innervating the immune system organ via the neuromodulation catheter. Reducing sympathetic neural activity improves a measurable physiological parameter corresponding to the immune system condition of the patient.

Tissue treatment systems and methods are disclosed. A tissue treatment system comprises a signal generator, a sensing circuit coupleable to electrode(s) of a catheter, and a controller. The sensing circuit senses neural activity of nerves within tissue surrounding a biological lumen using electrode(s) of the catheter inserted into the biological lumen. The controller determines one or more characteristics of the sensed neural activity of the nerves within the tissue surrounding the biological lumen. The controller also selects one or more denervation parameters based on the one or more characteristics of the sensed neural activity, and controls the signal generator to generate, using the selected one or more denervation parameters, signals for performing a denervation procedure intended to denervate at least some of the nerves for which the neural activity was sensed.