Abstract: Methods for treating hyperaldosteronism with therapeutic renal neuromodulation and associated systems and methods are disclosed herein. One aspect of the present technology, for example, is directed to methods that at least partially inhibit sympathetic neural activity in renal nerves proximate a renal blood vessel of a human patient. One or more measurable physiological parameters corresponding to hyperaldosteronism of the patient can thereby be improved. Moreover, central sympathetic drive in the patient can be reduced in a manner that treats the patient for hyperaldosteronism. Renal sympathetic nerve activity can be modulated along the afferent and/or efferent pathway. The modulation can be achieved, for example, using an intravascularly positioned catheter carrying a neuromodulation assembly, e.g., a neuromodulation assembly configured to use electrically-induced, thermally-induced, and/or chemically-induced approaches to modulate the renal nerve.

Abstract: Cryotherapeutic devices for renal neuromodulation and associated systems and methods are disclosed herein. A cryotherapeutic device configured in accordance with a particular embodiment of the present technology can include an elongated shaft having a distal portion and a supply lumen along at least a portion of the shaft. The shaft can be configured to locate the distal portion intravascularly at a treatment site proximate a renal artery or renal ostium. The supply lumen can be configured to receive a liquid refrigerant. The cryotherapeutic device can further include a cooling assembly at the distal portion of the shaft. The cooling assembly can include an applicator having a distributor in fluid communication with the supply lumen and a balloon configured to deliver cryotherapeutic cooling to nerves proximate the treatment site when the cooling assembly is in a deployed state.

Abstract: Methods for treating erectile dysfunction with therapeutic neuromodulation and associated systems and methods are disclosed herein. Erectile dysfunction can be characterized by the inability to develop and/or maintain an erection during sexual arousal or activity. One aspect of the present technology is directed to methods that at least partially inhibit sympathetic neural activity in nerves innervating the penis of a patient. Sympathetic drive in the patient can thereby be reduced in a manner that treats the patient for erectile dysfunction. Sympathetic nerve activity can be modulated along afferent and/or efferent pathways. The modulation can be achieved, for example, using an intravascularly positioned catheter carrying a therapeutic assembly, e.g., a therapeutic assembly configured to use electrically-induced, thermally-induced, and/or chemically-induced approaches to modulate the nerves.

Abstract: 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. An open distal end or one or more orifices may be provided on the injection tube for the refrigerant to be expelled into an expandable chamber such as a balloon disposed on the distal portion of the catheter. The dispersion of the refrigerant from the injection tube may be controlled or manipulable to direct the refrigerant to one or more target locations.

Abstract: A medical device, including an elongate body having a proximal portion and a distal portion; a shaft at least partially disposed within the elongate body; an expandable element at the distal portion of the elongate body; and a fluid delivery conduit defining a deflectable segment movably coupled to the shaft, the deflectable segment being transitionable from a substantially linear configuration to a substantially curvilinear configuration.

Abstract: Liners for cryogenic treatment systems are described where a cryogenic fluid or gas may be introduced into a liner expanded within a body lumen such as the uterine cavity. The liner may be intentionally sized to be substantially larger than the typical size of the uterine cavity, e.g., 1.2 times (or more), greater than the size of the uterine cavity into which the liner is inserted. Because the liner is sized intentionally larger than the body lumen to be treated, the liner may never fully expand when deployed. But even with folds or portions of the liner being folded upon itself, the liner may remain sufficiently supple such that the resulting uncontrolled folds allow for complete conformance of the liner against the anatomy of the contacted tissue.

Abstract: Methods for treating a patient using therapeutic spinal neuromodulation and associated devices, systems, and methods are disclosed herein. One aspect of the present technology is directed to methods including modulating nerves of one or more targeted organs proximate one or more dorsal root ganglia, stellate ganglia, vertebral ganglia, or cervical ganglia of the nerves using an intravascularly-positioned therapeutic element. One or more measurable physiological parameters corresponding to at least one condition associated with sympathetic activity in the targeted organs and/or central sympathetic activity in the patient can thereby be reduced.

Abstract: A cryosurgery system for application of medical-grade liquid nitrogen to a treatment area via a small, low pressure, open tipped catheter. The system includes a console, including a touch panel computer, a cryogen module, a suction module and an electronics module, and a disposable spray kit. Features include optional low cryogen flow setting to reduce the cryogen flow rate by 50%, improved cryogen flow consistency reducing pressure pulses and peaks, an integrated suction pump for improved consistency and self-checks, specified vent tube areas and corresponding maximum expected pressures during cryospray procedure; optional pressure sensing capability to monitor pressure during a treatment, and novel catheter designs of multilayer and flexible construction providing a variety of spray patterns.

Abstract: 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.

Abstract: Neuromodulation catheters with nerve monitoring features for transmitting digital neural signals and associated systems and methods are disclosed herein. A neuromodulation catheter configured in accordance with some embodiments of the present technology can include, for example, a handle and an elongated shaft attached to the handle. The shaft can have a proximal portion and a distal portion configured to be moved within a lumen of a blood vessel of a human patient. The neuromodulation catheter can further include an array of contacts at the distal portion of the shaft and a digitizer at the handle or the shaft. The contacts can be configured to detect analog neural signals from within the blood vessel. The digitizer can be configured to receive the analog neural signals from the contacts, digitize the analog neural signals into digital neural signals, and transmit the digital neural signals to a read/write module external to the patient.

Abstract: Neuromodulation systems with nerve monitoring assemblies and associated devices, systems, and methods are disclosed herein. A neuromodulation system configured in accordance with some embodiments of the present technology can include, for example, a generator, a nerve monitoring assembly configured to detect electroneurogram (ENG) signals, and a neuromodulation catheter. The neuromodulation catheter can include an elongated shaft with a distal portion and a proximal portion. The distal portion of the shaft can include an array of electrodes configured to detect nerve activity from within a blood vessel of a human. The proximal portion of the shaft can include at least one connector that operably couples the electrodes to the generator and to the nerve monitoring assembly.

Abstract: There is provided a method of supplying cryoenergy to a plaque within a blood vessel. The method comprises expanding an expandable membrane of a catheter apparatus with a pressure of less than 5 ATM (507 kPa), the catheter apparatus having been placed in thermal contact with the plaque within the blood vessel. The method also comprises establishing a temperature of between +15° C. (288K) and ?35° C. (238K) at an interface of the expandable membrane and the blood vessel. A system and catheter apparatus are also provided.

Abstract: A method and system for monitoring phrenic nerve function and preventing phrenic nerve injury during cardiac ablation. The system includes a pacing device operable to transmit stimulation energy to the phrenic nerve through target tissue proximate the phrenic nerve, a plurality of assessment electrodes operable to make comparisons between baseline, real-time, and predetermined threshold values for CMAP signal amplitude and amplitude over time. The processing device may be connected to an ablation console, and the processing device may interrupt or adjust an ablation procedure controlled by the ablation console and/or generate a system alert in response to one of these comparisons, if the comparison indicates phrenic nerve injury.

Abstract: Methods and systems for treating tissue that employ a radiometer for temperature measurements and use feedback from the radiometer to regulate energy being applied to the tissue are provided. For example, methods and systems are provided for calculating temperature based on signal(s) from a radiometer, which may provide useful information about tissue temperature at depth, and automatically regulating energy applied to the tissue based on the tissue temperature.

Abstract: Methods for treating polycystic ovary syndrome with therapeutic ovarian neuromodulation and associated systems and methods are disclosed herein. Polycystic ovary syndrome can be associated, for example, with a condition including at least one of oligo/amenorrhea, infertility, hirsutism, obesity, metabolic syndrome, insulin resistance, and increased cardiovascular risk profile. One aspect of the present technology is directed to methods that at least partially inhibit sympathetic neural activity in nerves proximate an ovarian artery of an ovary of a patient. Sympathetic drive in the patient can thereby be reduced in a manner that treats the patient for the polycystic ovary syndrome. Ovarian sympathetic nerve activity can be modulated along afferent and/or efferent pathways. The modulation can be achieved, for example, using an intravascularly positioned catheter carrying a therapeutic assembly, e.g.

Abstract: Methods, systems, and devices for providing a denervating energy treatment to the tissue of the pulmonary vein and antrum region of the left atrium utilizing a catheter-based structure having one or more energy delivery surfaces. In some instances energy delivery surfaces are arranged with a circumferential and axial offset relative to one another. A pattern of individual lesions loosely approximating a helix, or other staggered pattern, or roughly circumferential are placed so as to provide a pattern which covers substantially the circumference of the treated area while avoiding stenosis. Denervating energy is applied by modulation of the energy delivery surfaces using an energy source integrated with a controller and control algorithm. In some instances feedback is used in a control algorithm for energy modulation. Energy sources are radiofrequency, ultrasound, and cryogenic.

Abstract: A system and method for controlling the inflation, ablation, and deflation of a balloon catheter. The system includes a balloon catheter, a console, a pressurized gas or liquid inflation source, and an umbilical system to deliver pressurized coolant to the balloon catheter. The system may include controller that monitors the amount of pressure and volume within the balloon catheter. During inflation, the pressure and/or volume of fluid within the balloon is maintained at a target amount in order to provide sufficient mechanized pressure against the desired target region. The system limits the inflation pressure such that a safe quantity of gas would be released should a leak occur. If the amount falls below a certain threshold level, gas or fluid egress is presumed and the inflation process is halted.

Abstract: Methods and apparatus for the treatment of a body cavity or lumen are described where a heated fluid and/or gas may be introduced through a catheter and into treatment area within the body contained between one or more inflatable/expandable members. The catheter may also have optional pressure and temperature sensing elements which may allow for control of the pressure and temperature within the treatment zone and also prevent the pressure from exceeding a pressure of the inflatable/expandable members to thereby contain the treatment area between these inflatable/expandable members. Optionally, a chilled, room temperature, or warmed fluid such as water may then be used to rapidly terminate the treatment session.

Abstract: A cryosurgical device, with a control for the supply and/or removal of a coolant gas to a cryoprobe via a return flow or a supply flow. The device has at least one socket for the attachment of a rigid cryoprobe and a flexible cryoprobe. The socket and the plugs of the cryoprobes each form probe couplings. The configuration of the cryosurgical device allows both rigid and flexible cryoprobes to be automatically connected to the appropriate return flow conduit, independently of the level of knowledge of operating personnel.

Abstract: A cryogenic probe design is provided containing, for example, an inner coil injection tube with a continuous flow of circulating liquid and an outer jacket enclosing the inner coil injection tube. A transducer may monitor parameters in the region between the inner coil injection tube and the outer jacket. An outer jacket serves to prevent gas leakage. One or more embodiments of a probe design provide continuous flow for example via a continuous and controlled path from inlet to outlet and an expanded thermally transmissive region. Expanding a thermally transmissive region of the cooling zone may be provided, for example, in one or more embodiments of injection tube designs.

Abstract: Neuromodulation cryotherapeutic devices and associated systems and methods are disclosed herein. A cryotherapeutic device configured in accordance with a particular embodiment of the present technology can include an elongated shaft having distal portion and a supply lumen along at least a portion of the shaft. The shaft can be configured to locate the distal portion intravascularly at a treatment site proximate a renal artery or renal ostium. The supply lumen can be configured to receive a liquid refrigerant. The cryotherapeutic device can further include a cooling assembly at the distal portion of the shaft. The cooling assembly can include an applicator in fluid communication with the supply lumen and configured to deliver cryotherapeutic cooling to nerves proximate the target site when the cooling assembly is in a deployed state.

Abstract: The present invention relates to devices and methods for altering the tissue in and around an intervertebral disc through localized hypothermia therapy to restore function of the disc and reduce pain. Hypothermia therapy is defined as the reduction of tissue temperature to below that of the equilibrium temperature. Target therapeutic temperatures and times are varied according to the desired treatment effect. Intended effects of hypothermia of the intervertebral disc include cellular disruption leading to cell death and or structural and chemical denaturation within the anulus fibrosus, nucleus pulposus, or nerve fibers, temporary or permanent deadening of the nerves within or surrounding the disc, induction of a healing response, angiogenesis, or accelerated degeneration and/or drying of the nucleus pulposus and/or anulus fibrosus, Various effects can be achievW by reaching different temperatures for differing periods of time or by the proximity of the hypothermia therapy device to the treatment target.

Abstract: A method and system for cryotreatment and mapping of target tissue. The cryotreatment system may include a cryotreatment catheter, a mapping catheter including one or more mapping electrodes, and one or more temperature sensors located on the mapping catheter and/or the cryotreatment catheter. The cryotreatment catheter distal tip may be short enough to allow at least one mapping electrode to be positioned proximate the cryoballoon, for example, within 6 mm or less from the cryoballoon. Energy, such as radiofrequency energy, may be delivered to one or more mapping electrodes when one or more temperature sensors indicate a temperature of approximately 0° C. or below at one or more mapping electrode in order to thaw or prevent the formation of ice on the mapping electrodes when positioned proximate a cryoballoon during a cryotreatment procedure in order to recapture cardiac signals.

Abstract: A cryogenic medical device for delivery of subcooled liquid cryogen to various configurations of cryoprobes is designed for the treatment of damaged, diseased, cancerous or other unwanted tissues. The device is a closed or semi-closed system in which the liquid cryogen is contained in both the supply and return stages. The device is capable of generating cryogen to a supercritical state and may be utilized in any rapid cooling systems. As designed, the device comprises a number of parts including a vacuum insulated outer dewar, submersible cryogen pump, baffled linear heat exchanger, multiple pressurization cartridges, a return chamber, and a series of valves to control the flow of the liquid cryogen interconnected with cryotreatment devices including cryoprobes and catheters. The cryogenic medical device promotes subcooling to the tips of various external cryogenic instrument configurations.

Abstract: A cryotherapy catheter can include an elongate member and an inflatable balloon at a distal end of the elongate member, the elongate member having lumens formed therein to supply cryogenic fluid to a chamber of the balloon and to channel exhaust from the balloon chamber; and a controller programmed to control a first rate at which the cryogenic fluid is supplied to the balloon chamber and a second rate at which exhaust is channeled from the balloon chamber, wherein the controller is programmed to a) develop, during a first phase of a cryotherapy procedure, a first pressure inside the balloon chamber at a value that is greater than an ambient pressure outside and adjacent to a proximal end of the elongate member, and b) develop, during a second phase of the cryotherapy procedure, the first pressure at a value that is less than the ambient pressure.

Abstract: A method and system for cryotreatment of target tissue using a cryotreatment catheter through which a mapping catheter may be freely movable, even during activation of the cryotreatment element. The cryotreatment system may include a cryotreatment catheter, a mapping catheter slidably disposed within a lumen of the cryotreatment catheter, and one or more heating elements. The one or more heating elements may be disposed on the mapping catheter or within the lumen of the cryotreatment catheter. Activation of the one or more heating elements prevents the freezing of, or thaws, fluid within the lumen of the cryotreatment device when one or more cryotreatment elements are activated. The lack of frozen fluid within the lumen allows the mapping catheter to freely move within the cryotreatment catheter during a cryotreatment procedure, so that the mapping catheter may be positioned proximate the treatment site after initiation of cryotreatment.

Abstract: The present invention advantageously provides a method and system for cryogenically ablating large areas of tissue within the left atrium. In an exemplary embodiment a cryotherapy device includes a catheter body, a proximal end and a distal end; a first lumen; a second lumen; and an ablation element expandable from a first diameter to a second diameter, the ablation element having a surface portion that conforms to the uneven surface topography of the cardiac tissue. The ablation element can include one or more deformable balloon and/or flexible elements. The surface of the balloon can further be shaped by regulation of pressure within the one or more balloons. In an exemplary method, a tissue ablation device is provided and tissue in the left atrium is ablated with the device, whereby the ablation is created by freezing tissue.

Abstract: Apparatus and method for ablating target tissue including a non-linear area of tissue in the left atrium of a patient. The method can include selecting an ablation apparatus having an ablator with a tissue engagement section, penetrating a chest cavity of the patient, and identifying the target tissue. The method can also include positioning the ablation apparatus adjacent to the target tissue so that the tissue engagement section can transfer ablation energy to the target tissue. The method can further include energizing the tissue engagement section with ablation energy in order to create a footprint on the non-linear area of tissue in the left atrium and to reduce an overall mass of excitable tissue in the left atrium.

Abstract: A cryogenic probe for ablating cardiac tissue is provided comprising a handle piece and an elongated probe tube extending from the handle that terminates in a malleable end effector closed at its distal end and having a smooth outer surface. A semi-rigid insulative sleeve extends from the handle and overlies the proximal portion of the probe tube. An internal support preferably in the form of a coiled spring is located interior of the probe tube for supporting the interior surface of the probe tube. A plurality of cryogenic fluid supply tubes are disposed on the interior of the probe tube for introducing cryogenic fluid to the probe tube, each supply tube having an outlet orifice, with the outlet orifices being staggered along the length of the probe tube. In one embodiment, the probe tube is axially movable relative to the sleeve/handle between retracted and extended positions. Also, the probe tube may be provided with a thermocouple for measuring the temperature of the surface of the probe tube.

Abstract: A medical device, including an elongate body having a proximal portion and a distal portion; a shaft at least partially disposed within the elongate body; an expandable element at the distal portion of the elongate body; and a fluid delivery conduit defining a deflectable segment movably coupled to the shaft, the deflectable segment being transitionable from a substantially linear configuration to a substantially curvilinear configuration.

Abstract: A method of cryoablating diseased tissue is provided. The method includes providing an embolization agent. The embolization agent includes an inner core made of a first material. The inner core has a diameter less than a diameter of an opening of a target vessel. The embolization agent further includes an erodible outer shell made of a second embolization material encompassing the inner core. The erodible outer shell has an initial diameter greater than the diameter of the opening to occlude the target vessel. The method further includes occluding the opening of the target vessel with the embolization agent to reduce blood flow in the diseased tissue. The method further includes cryoablating the diseased tissue with a cryoablation probe while the target vessel is occluded by the embolization agent.

Abstract: Methods for therapeutic renal denervation are disclosed herein. One aspect of the present application, for example, is directed to methods that block, reduce and/or inhibit renal sympathetic nerve activity to achieve a reduction in central sympathetic tone. Renal sympathetic nerve activity may be altered or modulated along the afferent and/or efferent pathway. The achieved reduction in central sympathetic tone may carry several therapeutic benefits across many disease states.

Abstract: A method and system for preventing phrenic nerve injury during a cardiac ablation procedure. The method generally includes stimulating a phrenic nerve with a pacing electrode at a location proximate a target treatment location, ablating tissue at the target treatment location with a treatment element, obtaining a heart audio signal with an audio sensor positioned proximate the target treatment location, and determining whether phrenic nerve stimulation (PNS) is present based as least in part on the obtained heart audio signal. A processor may be used to compare an amplitude of the obtained heart audio signal to a predetermined threshold amplitude. The processor may determine that PNS is present if the amplitude of the obtained audio signal is greater than the threshold amplitude. If PNS is present, ablation of the tissue may continue at the current or greater energy level and/or at the current treatment location without injuring the phrenic nerve.

Abstract: Embodiments related to cryogenically ablating a vessel wall in a partial circumferential, non-continuous, or helical ablation pattern are disclosed. A catheter is disclosed that includes a cryoballoon for ablation of the vessel wall. A radially expandable insulative element is disposed over the cryoballoon to shield non-targeted tissue of the vessel wall from the cryoballoon and prevent ablation of the non-targeted tissue. Partial circumferential, non-continuous, and helical ablation can be effective for treating a variety of renal, cardio-renal, and other diseases including but not limited to hypertension, heart failure, renal disease, renal failure, contrast nephropathy, arrhythmia, and myocardial infarction. The insulative element may be, for example, a sheath component having opening(s) formed therethrough or may be an outer balloon within which the cryoballoon is disposed.

Abstract: A system and method for controlling the inflation, ablation, and deflation of a balloon catheter. The system includes a balloon catheter, a console, a pressurized gas or liquid inflation source, and an umbilical system to deliver pressurized coolant to the balloon catheter. The system may include controller that monitors the amount of pressure and volume within the balloon catheter. During inflation, the pressure and/or volume of fluid within the balloon is maintained at a target amount in order to provide sufficient mechanized pressure against the desired target region. The system limits the inflation pressure such that a safe quantity of gas would be released should a leak occur. If the amount falls below a certain threshold level, gas or fluid egress is presumed and the inflation process is halted.

Abstract: A device for providing a cryotherapy ablation treatment includes a piping assembly and a snow horn adapted to create a spray of snow from a pressurized source of a low-temperature liquid, a tubular applicator for collecting a mass of snow at a prescribed density that is sufficient to allow the mass to serve as the needed, low temperature, thermal reservoir for the device after the applicator's distal end has been disconnected from the snow horn end so that it can to be used during the treatment process, and an applicator tip adapted to allow it to connect to the applicator's distal end and be used to treat those specific locations which are to receive this treatment.

Abstract: A point of incision is created within tissue, the tissue having a temporoparietal fascia-deep temporoparietal fascia layer (TPF-sDTF) beneath skin and a temporal branch of a target nerve extending along a portion of the TPF-sDTF, the point of incision being laterally displaced from the target nerve. A cryogenic probe having a distal tip extending from an elongated body is inserted into the point of incision. The TPF-sDTF is bluntly dissected using the cryogenic probe such that a treating portion of the cryogenic probe is directly adjacent to a first treatment portion of the target nerve. The cryogenic probe is activated to create a first treatment zone at the first treatment portion of the target nerve to cause a therapeutic effect.

Abstract: A cryoablation system includes thermally insulated containers for holding liquid refrigerant. The containers are placed in a docking station that charges the containers with a liquid refrigerant at a cryogenic temperature suitable for carrying out a surgical procedure. The charged containers are detachably connectable with an inlet line of a cryoablation probe. When the cryoprobe is activated, the chilled liquid refrigerant is transported from a delivery container, through the cryoprobe, and to a recovery container. The recovery container is preferably identical in design to the delivery container. The refilled recovery container is then placed in the docking station to charge. In another embodiment, a cartridge includes a delivery container and recovery container combined as a single unit. Methods are also described.

Abstract: A novel medical probe assembly, system, and methods for the use thereof to treat tissue are described. The system optionally comprises an energy source, two probe assemblies, and one or more cooling devices to provide cooling to at least one of the probe assemblies. The probe assemblies may be configured in a bipolar mode, whereby current flows preferentially between the probe assemblies. The probe assemblies and system described herein are particularly useful to deliver radio frequency energy to a patient's body. RF energy delivery may be used for various applications, including the treatment of pain, tumor ablation and cardiac ablation.

Abstract: A method and system for performing pulmonary vein isolation, mapping, and assessing pulmonary vein occlusion using a single device. The device may generally include an ablation element, such as a cryoballoon, and a sensing component slidably disposed within a lumen of the device and bearing one or more mapping electrodes and one or more pressure sensors. The method may generally include mapping cardiac electrical signals within a heart and/or pulmonary vein, positioning a distal portion of the sensing component within a pulmonary vein, advancing the ablation element until it is in contact with the pulmonary vein ostium, recording blood pressure measurements within the pulmonary vein with the one or more pressure sensors to assess pulmonary vein occlusion, and activating the treatment element when the pulmonary vein is completely occluded. The sensing component may have a straight or hooped configuration, or a configuration therebetween.

Abstract: Apparatus and methods for insulating tissue during therapeutic procedures.

Abstract: Methods and devices for treating nasal airways are provided. Such devices and methods may improve airflow through an internal and/or external nasal valve, and comprise the use of mechanical re-shaping, energy application and other treatments to modify the shape, structure, and/or air flow characteristics of an internal nasal valve, an external nasal valve or other nasal airways.

Abstract: Methods and apparatus for the treatment of a body cavity or lumen are described where a heated fluid and/or gas may be introduced through a catheter and into treatment area within the body contained between one or more inflatable/expandable members. The catheter may also have optional pressure and temperature sensing elements which may allow for control of the pressure and temperature within the treatment zone and also prevent the pressure from exceeding a pressure of the inflatable/expandable members to thereby contain the treatment area between these inflatable/expandable members. Optionally, a chilled, room temperature, or warmed fluid such as water may then be used to rapidly terminate the treatment session.

Abstract: A cryotherapy catheter can include an elongate member and an inflatable balloon at a distal end of the elongate member, the elongate member having lumens formed therein to supply cryogenic fluid to a chamber of the balloon and to channel exhaust from the balloon chamber; and a controller programmed to control a first rate at which the cryogenic fluid is supplied to the balloon chamber and a second rate at which exhaust is channeled from the balloon chamber, wherein the controller is programmed to a) develop, during a first phase of a cryotherapy procedure, a first pressure inside the balloon chamber at a value that is greater than an ambient pressure outside and adjacent to a proximal end of the elongate member, and b) develop, during a second phase of the cryotherapy procedure, the first pressure at a value that is less than the ambient pressure.

Abstract: A cryoablation system includes thermally insulated containers for holding liquid refrigerant. The containers are placed in a docking station that charges the containers with a liquid refrigerant at a cryogenic temperature suitable for carrying out a surgical procedure. The charged containers are detachably connectable with an inlet line of a cryoablation probe. When the cryoprobe is activated, the chilled liquid refrigerant is transported from a delivery container, through the cryoprobe, and to a recovery container. The recovery container is preferably identical in design to the delivery container. The refilled recovery container is then placed in the docking station to charge. In another embodiment, a cartridge includes a delivery container and recovery container combined as a single unit. Methods are also described.

Abstract: Ablation devices useful for removing nerve and soft tissue via a minimally invasive procedure to alleviate pain are provided. The device comprises a plurality of probes each comprising an interior surface defining an internal passage and an exterior surface comprising a tip. The internal passage has a filament comprising an opening configured to release a pressurized material into the interior surface of the probe so as to cool the exterior surface of the probe to a selected temperature. A plurality of introducers are provided each comprising an interior surface configured for engagement with the probe where at least one air gap is produced by the introducer and probe engagement and an exterior surface comprising a heat conductive tip where the probe tip is snap fixed with the introducer tip in a configuration for ablating nerve and/or soft tissue. Methods for ablating nerve and/or soft tissue utilizing the ablation devices are also provided.

Abstract: A method and system for continuously delivering cryotreatment to a treatment device. In one embodiment, the system may include a first PID circuit in the fluid delivery line and a second PID circuit in the fluid return line, and the first and second PID circuits may operate simultaneously to continuously provide coolant to a cryotreatment device during the inflation phase, ablation phase, and warming (or thawing) phase while providing for temperature adjustment. Alternatively, the system may include a bypass line by which coolant may bypass the subcooler system and be delivered to the cryotreatment device at non-ablation temperatures during the inflation phase. During the ablation phase, coolant may flow through the subcooler system.

Abstract: Ablation devices useful for destroying nerve and soft tissue via a minimally invasive procedure to alleviate pain are provided. The device comprises a probe comprising an interior surface that defines an internal passage and an exterior surface comprising a tip. The internal passage has a filament comprising an opening configured to release a pressurized material into the interior surface of the probe so as to cool the exterior surface of the probe to a selected temperature. A release instrument is provided comprising a sheath that comprises an exterior surface and an interior surface configured for engagement with the probe. The probe tip is configured for ablating nerve and/or soft tissue by forming an ice ball and the release instrument is configured to release the probe tip from the ice ball. Methods for ablating nerve and/or soft tissue utilizing the ablation devices are also provided.

Abstract: An endoscopic cryoablation apparatus for the ablation of unwanted tissues is disclosed. A method of utilizing the apparatus for ablating pancreatic cancer, gastrointestinal cancers, or other undesired tissue is also incorporated. The apparatus provides a cryoprobe needle tip covered by an outer sheath at a distal end of a catheter shaft such that the distal end includes a defined ablation zone. As implemented, the cryocatheter can be utilized alone or in combination with and endoscopic ultrasound. A moveable handle attached to the outer sheath is configured such that the handle retracts and protracts the outer sheath to expose and cover, respectively, the cryoprobe needle tip.

Abstract: Ablation devices comprising a probe or needle useful for destroying nerve and soft tissue via a minimally invasive procedure to alleviate pain are provided. The probe comprises at least two prongs spaced apart and parallel to each other. The at least two prongs each having an interior surface and an exterior surface and an internal passage disposed in the interior surface of the at least two prongs. A filament is disposed in the internal passage of the at least two prongs that has an opening configured to release a pressurized material into the interior surface of the at least two prongs so as to cool the exterior surface of the at least two prongs to a temperature configured for ablating nerve and/or soft tissue. Methods for ablating nerve and/or soft tissue utilizing the ablation devices are also provided.