Ablation systems of the present disclosure facilitate the safe formation of wide and deep lesions. For example, ablation systems of the present disclosure can allow for the flow of irrigation fluid and blood through an expandable ablation electrode, resulting in efficient and effective cooling of the ablation electrode as the ablation electrode delivers energy at a treatment site of the patient. Additionally, or alternatively, ablation systems of the present disclosure can include a deformable ablation electrode and a plurality of sensors that, in cooperation, sense the deformation of the ablation electrode, to provide a robust indication of the extent and direction of contact between the ablation electrode and tissue at a treatment site.

An irrigation system for anal or stomal irrigation includes a reservoir, a tubing system providing a first flow path between the reservoir and a catheter, and a pressure channel separate from the first flow path. A pump is operable to move the liquid through the first flow path from the reservoir and through the catheter. A control system is connected to the tubing system. A connector couples the tubing system to the catheter, where the connector includes a chamber coupling the pressure channel to the first flow path, with a membrane located in the chamber between the first flow path and the pressure channel. A pressure sensor communicates with the control system which operates the pump to control the anal or the stomal irrigation with the liquid based on the pressure sensed in the first flow path.

A medical device for the treatment and irrigation of a sinus opening is described. The device allows for single-handed operation to access, dilate and irrigate a sinus opening. The device includes a sinus guide catheter, a guiding element, a balloon dilation catheter, a balloon catheter movement mechanism and a guiding element movement mechanism. A method for treating a sinus opening and irrigating a sinus is also described.

A dilation instrument includes a body, a dilation catheter, a guide member, and a force sensor. The dilation catheter has an expandable dilator. The guide member extends distally from the body and is configured to guide movement of the expandable dilator. The force sensor is operatively connected to the guide member and is configured to sense a force imparted against the guide member for monitoring engagement with an anatomy of a patient.

An ear cleaning device comprising a fluid dispenser in communication with a hollow cleaning body. The hollow cleaning body is elongated according to a relative longitudinal axis. The cleaning body includes an insertion portion configured to assume a resting configuration in which it is at least partially insertable into the ear canal of an ear, and an expanded configuration in which it has an increased volume due to expansion by fluid provided by the fluid dispenser. The insertion portion includes a plurality of lobes which are elongated according to the longitudinal axis and form convex portions towards the outside of the insertion portion. The insertion portion also includes connecting walls between the lobes which are developed according to the longitudinal axis forming grooves between the lobes.

The invention relates to an ear catheter for insertion into the eustachian tube with a first tube as catheter tube (3) provided with at least one first lumen as injection duct (3A) for the application of a liquid/fluid, at least one second lumen as pressure relief lumen (3B) for pressure relief and a self-expandable sealing element (2) for the occlusion of the eustachian tube, as well as an insertion aid comprising a headpiece, a middle piece and an end piece, wherein the insertion aid consists of a biocompatible polymer, and with at least one separator line extending at least through each of the middle piece and the end piece, along which the insertion aid can be unfolded or split open. The insertion aid proposed by the invention can thus be removed from a catheter even if the catheter ends are blocked.

Ablation systems and methods of the present disclosure are directed toward delivering pulsed radiofrequency (RF) energy to target tissue. The pulsations of the RF energy, combined with cooling at a surface of the target tissue, can advantageously promote local heat transfer in the target tissue to form lesions having dimensions larger than those that can be safely formed in tissue using non-pulsed RF energy under similar conditions.

Ablation systems and methods of the present disclosure control lesion depth and width such that, for example, wide and shallow lesions can be formed in target tissue in an anatomic structure of a patient during a medical procedure. Such wide and shallow lesions can be useful for treating, for example, thin tissue such as atrial tissue in atria of the heart of the patient.

A system includes a dilation catheter and a guide member. The dilation catheter includes a proximal end, a distal end, a dilator, a navigation sensor, and a force sensor. The dilator is positioned proximal to the distal end and is configured to transition between a non-dilated configuration and a dilated configuration. The navigation sensor is positioned distal to the dilator and is configured to cooperate with a guidance system and thereby provide signals indicating a position of the dilation catheter in three-dimensional space. The force sensor is positioned distal to the dilator and is configured to provide signals indicating a force encountered by the force sensor. The dilation catheter is configured to slide relative to the guide member. A distal portion of the guide member is sized and configured to fit in a nasal cavity of a patient.

Systems and methods for automated assessment and monitoring of bodily fluids are disclosed. In one embodiment, a system for provisioning a treatment composition to a bladder of a patient includes: an irrigation bag that carries the treatment composition; a catheter configured for connecting the irrigation bag to the bladder; a flow regulator configured for controlling a flow of the treatment composition from the irrigation bag to the bladder; and a drainage bag in fluid communication with the bladder through a drainage tubing of the catheter. The drainage tubing is configured for draining urine from the bladder. The system also includes: a first sensor for detecting a first amount of the treatment composition in the irrigation bag; a second sensor for detecting a second amount of urine in the drainage bag; a third sensor for detecting a concentration of particles in the urine carried by the drainage bag; and a controller.