A variable length interstitial probe apparatus includes: a probe for effecting thermal therapy and/or cryotherapy to a tissue; a flexible umbilical sheath permanently affixed to the probe, including at least one interface for supplying energy, cooling fluid, cooling gas, heating fluid, and/or heating gas to the probe; and an adjustable depth stop configured to slide along a length of a shaft region of the probe, and lock to the shaft region at a selected position. The adjustable depth stop is configured to engage a probe driver and/or a skull mount apparatus to stabilize positioning of the probe and to control a depth of entry of the probe into a patient. The probe may be configured to effect temperature modulation therapy, where processing circuitry activates a modulation pattern of thermal therapy emission and cryogenic therapy emission for applying a thermal dose to the tissue.

One embodiment provides a tightly targeted minimally invasive therapy (TTMIT) parathyroid tissue ablating instrument. A substance that cytotoxically ablates parathyroidal tissue during application in the parathyroidal tissue of therapeutically sufficient units of an electromagnetic energy having a frequency only ranging from ultraviolet to visible to near infrared. A substance delivery device is configured to introduce the substance into the parathyroidal tissue. An electromagnetic energy treatment device is configured to apply the therapeutically sufficient units of the electromagnetic energy within a thermal range that is non-cytotoxic to the parathyroidal tissue to the substance after the substance has been introduced by the substance delivery device. A sensor is configured to monitor activation of the substance as the therapeutically sufficient units of the electromagnetic energy are applied. The electromagnetic energy treatment device is further configured to modulate applying the therapeutically sufficient units of the electromagnetic energy once the substance has been activated.

A method of using a cryotherapeutic system in accordance with a particular embodiment includes advancing an elongate shaft of a catheter toward a treatment location within a body lumen of a human patient and directing a flow of refrigerant toward a cryotherapeutic element at a distal end portion of the shaft. The directed refrigerant is expanded to cause cooling within a balloon of the cryotherapeutic element. The pressure within the balloon is monitored and its rate of change calculated. The rate of change is then processed using different feedback loops during different monitoring windows of a treatment cycle. The individual feedback loops include an upper and a lower threshold and are configured to cause the flow of refrigerant to the cryotherapeutic element to stop if the rate of change falls outside a range between the upper and the lower threshold.

Systems and methods for assessing sympathetic nervous system (SNS) tone for renal neuromodulation therapy are disclosed herein. A system configured in accordance with embodiments of the present technology can include, for example, a detector attached to or implanted in a patient and a receiver communicatively coupled to the detector. The detector can measure cardiac data and the receiver and/or a device communicatively coupled thereto can analyze the cardiac data to provide one or more SNS tone indicators. The SNS tone indicators can be used to determine whether a patient will be responsive to a neuromodulation therapy and/or whether a neuromodulation therapy was effective.

A cryosurgical instrument includes a feed line for conveying fluid into an expansion chamber. The feed line has a capillary line section that terminates in the expansion chamber and forms an aperture for the fluid to undergo the Joule-Thomson effect. The flow cross-section of the feed line decreases in at least one transition section of the feed line in the form of a funnel. Following each transition section there preferably follows a step section, in which latter section the flow cross-section is preferably largely constant. The last step section is preferably formed by the capillary line section. Due to the acceleration of the fluid in the transition sections and the abating of pressure fluctuations in the capillary tube section and, optionally in the additional step sections, the expansion range in the expansion chamber is increased, without impeding the backflow of the expanded gas out of the expansion chamber.

A catheter-based medical device including controlled refrigerant dispersion is disclosed. The device includes a fluid injection tube that carries refrigerant from a coolant supply to the distal portion of the device. A fluid dispersion unit is disposed on the distal end of the fluid tube to control the angle of distribution for refrigerant that is expelled from the fluid injection tube. Controlling the angle of distribution for the refrigerant facilitates dispersion of the fluid in a predetermined spray pattern. The disclosure further relates to cryoablation treatment systems incorporating such a catheter, and to cryoablation treatment methods for tissue treatment to address various conditions suitably treatable with cryoablation.

Example apparatuses and systems are disclosed for providing controlled delivery of electrolysis products to a site which may be used for treatment of infection and ablation of undesirable cells and tissue. A system disclosed may include a power supply, two electrodes, an aqueous matrix that may close the electric circuit between the electrodes at the treated site, and a controller. The controller may control the electrical circuit to induce a direct current through the electrodes and an aqueous matrix to produce electrolysis products. The duration and magnitude of the charge applied may determine the dose of the products applied to the treatment site. The composition of the electrodes and the aqueous matrix may be chosen to produce desired products. An apparatus is disclosed that may be in the form of a pad for applying to a wound. An apparatus is disclosed that may be used for treating internal tissue.

Systems, devices and methods for performing medical procedures in the intestine of a patient are provided. A medical device for performing a treatment and/or a diagnostic procedure can include an elongate shaft assembly comprising at least a shaft assembly first section comprising a distal section of the shaft assembly, and a shaft assembly second section proximal to the first section, and a functional assembly positioned on the shaft assembly first section. Additional sections of the shaft assembly can be included, and each section can comprise a different construction, such as to achieve a different stiffness as described herein. Variable stiffness along the length of the shaft assembly can be provided to aid in translation of the device through the patient's GI tract (e.g. through the stomach and into the small intestine), as described herein.

Systems and methods can be used to retrieve and remove blood clots from blood vessels. For example, this document describes catheter-based cryogenic devices that are used to retrieve and remove blood clots. The systems and methods provided herein can be used to remove blood clots from all types of blood vessels including, but not limited to, peripheral vessels, coronary arteries, central veins, pulmonary arteries, cerebral arteries, and any other type of blood vessel that can contain blood clots.

A method of predicting an adverse event during an ablation procedure includes providing a medical device having an expandable element and positioning the medical device proximate to an area of target tissue. The medical device includes a fluid exhaust lumen and a fluid supply lumen each being in fluid communication with the expandable element. The method further includes delivering fluid to expandable element and exhausting fluid from the expandable element; measuring a pressure within a vacuum return path; and measuring a period of time it takes for the pressure within the vacuum return path to reach a target pressure.