A system for accessing a patient's uterine cavity and detecting perforations in the uterus includes an elongated probe having a flow channel extending to a terminal outlet in a distal region of the probe. A fluid source is coupled to the flow channel, and a seal on the probe is positionable in an endocervical canal. The probe may be trans-cervically inserted into the uterine cavity, and a fluid may be introduced through the channel to flow outwardly from the terminal outlet into the uterine cavity. A parameter of said fluid flow is monitored to detect a perforation in the uterus.

In an exemplary arrangement, a vapor generator for use in a medical device may include a heating core in fluid communication with a source of fluid and defining at least one fluid pathway along which fluid from the source of fluid travels. The at least one fluid pathway may include one or more surfaces that generate turbulence in the fluid. The vapor generator may also include a coil disposed about the heating core, wherein the coil is configured to receive a current so as to heat the fluid traveling along the at least one fluid pathway, thereby generating a vapor.

Methods, devices, and systems are described herein for applying energy to tissue for ablation of tissue while allowing the tissue to be resorbed within the body. Such methods, devices, and systems control application of energy to maintain a temperature of target tissue above an ablation temperature, being dependent upon the activation time, and below a transformation temperature, also being dependent upon the activation time, where the transformation prevents or hinders resorption of the treated tissue by the body.

An electrophysiological catheter and an ablation system comprising a control device, an ablation energy output device and the electrophysiological catheter. The control device controls the ablation energy output device to selectively provide a first fluid or a second fluid that is a frozen liquid to the electrophysiological catheter. When the ablation energy output device provides the first fluid, the control device controls a first heating component on the electrophysiological catheter to work to heat the fluid entering the electrophysiological catheter for spraying a thermal ablation gas onto the inner surface of a balloon; and when the ablation energy output device provides frozen liquid, the control device controls the first heating component not to work to directly spray the frozen liquid to the inner surface of the balloon.

A method and laser surgical devices for surgical incising and ablating living tissues using laser beam and effecting enhanced surgical haemostasis concurrently with incising and ablating are disclosed. The method requires a surgical laser beam that is pulsed and is highly absorbed in living tissues and enhanced haemostatic action is achieved using along with the surgical laser beam energy, delivered in pulses, another separately controlled energy effecting haemostasis, by applying the second energy in any and every given spot of incising and ablating in a preemptive and focused manner, which minimizes haemostasis-related damage to surrounding tissues. In one embodiment a heated gas jet from a hollow core optical fiber transmitting the surgical laser beam is used. In other embodiments an ancillary laser radiation at a wavelength chosen specifically to minimize haemostasis-related damage to tissue is utilized for preemptive and controlled haemostatic effect.

An instrument and method for applying thermal energy to targeted tissue. An instrument and method for tissue thermotherapy. In one embodiment, a method includes providing a vapor source comprising a pump configured for providing a flow of liquid media from a liquid media source into a vaporization chamber having a heating mechanism, actuating the pump to provide the liquid into the vaporization chamber, applying energy from the heating mechanism to convert a substantially water liquid media into a minimum water vapor level for causing an intended effect in tissue. For examples such levels can comprise at least 60% water vapor, at least 70% water vapor, at least 80% water vapor or at least 90% water vapor for causing an intended effect in tissue.

Provided are a system and a method for determining the temperature of a body by imaging a hydrogen proton-rich material positioned within the body using nuclear magnetic resonance imaging. A method to increase changes in the MRI signal strength as a function of temperature, thus improving temperature sensitivity, is also provided. The system and method employ polymers having mechanical stability and magnetic image brightness at low temperatures of between 0° C. and −65° C. or high temperatures of between +37° C. and +80° C.

A method and system of providing therapy to a patient's uterus is provided, which can include any number of features. The method can include the steps of inserting a uterine device into the uterus and performing a uterine integrity test to determine that the uterus is intact and not perforated. If it is determined that the uterus is not perforated, a patency test can be performed to determine that the uterine device is not clogged or embedded in tissue. If the uterus is intact and the device is not clogged or embedded in tissue, the uterus can be treated with the uterine device, e.g., uterine ablation. Systems for performing these methods are also disclosed.

A method to apply a nerve inhibiting cloud surrounding a blood vessel includes creating a treatment plan, wherein the treatment plan prescribes application of the nerve inhibiting cloud towards at least a majority portion of a circumference of a blood vessel wall, and applying the nerve inhibiting cloud towards the majority portion of the circumference of the blood vessel wall for a time sufficient to inhibit a function of a nerve that surrounds the blood vessel wall.

A vapor-based ablation method mitigates constriction of the airways for the treatment of asthma and COPD. A vapor ablation catheter is advanced along the airways, through the airway wall, and to an extra-airway target tissue. The position of the catheter is assessed to determine whether the catheter is in contact with the target tissue. In embodiments, the distal energy delivery section of the catheter is manipulated to contact an exterior surface of the target tissue, or to enter the target tissue. Once the position is confirmed, vapor is delivered to the target tissue through an egress port with a sufficient amount of energy to ablate the target tissue. The target tissue may vary and include smooth muscle surrounding the airways, and nerves that control the smooth muscle. Methods for treating lung cancer are also described including delivering a vapor at lung tumors and growths, and blood vessels feeding the lung tumors and growths.