Embodiments herein relate to medical devices and methods for using the same to treat cancerous tumors within a bodily tissue. A medical device system is included having an electric field generating circuit configured to generate one or more electric fields and a control circuit in communication with the electric field generating circuit. The control circuit configured to control delivery of the one or more electric fields from the electric field generating circuit. The system can include two or more electrodes to deliver the electric fields to a site of a cancerous tumor within a patient and a temperature sensor to measure the temperature of tissue at the site of the cancerous tumor. The control circuit can cause the electric field generating circuit to generate one or more electric fields at frequencies selected from a range of between 10 kHz to 1 MHz. Other embodiments are also included herein.

A treatment system includes a generator and a fluid transfer cartridge. The fluid transfer cartridge includes a cartridge shell having a cartridge cavity. The cartridge cavity is between a front face and a rear face. A syringe barrel is disposed within the cartridge cavity, and has a syringe cavity. The fluid transfer cartridge includes a cartridge manifold in the cartridge cavity. The cartridge manifold includes a fluid transfer plate having a front fluid channel in a front plate surface, and a rear fluid channel in a rear plate surface. The cartridge manifold includes a fluid port extending through the fluid transfer plate from the front fluid channel to the rear fluid channel. The front fluid channel, the rear fluid channel, and the fluid port are in fluid communication with the syringe cavity. Other embodiments are also described and claimed.

A neuromodulation catheter includes an elongate shaft and a neuromodulation element. The shaft includes two or more first cut shapes and two or more second cut shapes along a helical path extending around a longitudinal axis of the shaft. The first cut shapes are configured to at least partially resist deformation in response to longitudinal compression and tension on the shaft and torsion on the shaft in a first circumferential direction. The second cut shapes are configured to at least partially resist deformation in response to longitudinal compression on the shaft and torsion on the shaft in both first and second opposite circumferential directions.

Methods and apparatuses for temperature modification of a patient, or selected regions thereof, including an induced state of hypothermia. The temperature modification is accomplished using an in-dwelling heat exchange catheter within which a fluid heat exchange medium circulates. A heat exchange cassette is attached to the circulatory conduits of the catheter, the heat exchange cassette being sized to engage a cavity within a control unit. The control unit includes a heater/cooler device for providing heated or cooled fluid to a heat exchanger in thermal communication with the fluid heat exchange medium circulating to the heat exchange catheter, a user input device, and a processor connected to receive input from various sensors around the body and the system. A temperature control scheme for ramping the body temperature up or down without overshoot is provided.

Methods, devices, and systems employ cryolysis of oropharyngeal adipose tissues to selectively remove fat cells from the tissues causing obstructive sleep apnea. In various embodiments, a chilled liquid—e.g., a liquid or air—is applied to the target tissue at a temperature and for a duration sufficient to cause cryolysis.

An electrochemical reactor includes positive and negative electrodes. A conductive and/or dielectric liquid is provided between the positive and negative electrodes. A first isolation member provided on the positive electrode isolates the positive electrode from the liquid, and a second isolation member provided on the negative electrode isolates the negative electrode from the liquid. The first and second isolation member each includes a liquid-repellent porous membrane. The reactor further includes a pressure-applying member which pressurizes the liquid to fill the pores of the first and second liquid-repellent porous membranes with the liquid, thereby causing an electrochemical reaction involving the positive and negative electrodes.

The invention provides for a system for in vivo real time measurement of NADH recovery kinetics, comprising: 1) a specific pulse sequence to non-destructively, yet effectively, photobleach NADH for measurement of NADH recovery kinetics; 2) illumination light parameters to acquire NADH fluorescence before and after photobleaching, without causing fluorescence bleaching artifacts, for measurement of NADH recovery kinetics; and 3) configurations for devices capable of photobleaching NADH by at least 10% within tissues for effective measurement of NADH recovery kinetics in tissues within a living subject or excised tissues and organs.

The present invention provides methods and devices for controlling a cold slurry that is delivered to a target tissue and for limiting heat transferring from surrounding tissue to the target tissue. In particular, a balloon structure is deployed at or near a point of delivery to act as a physical and/or thermal barrier. In some instances, the balloon structure can act as a pressure device obstructing the flow of warm blood into a treatment area, which can melt the cold slurry.

The present invention provides methods and devices for making a cold slurry at a point of delivery. A point of delivery device delivers cold slurry components to a location at or near a target tissue. The components are combined to form the cold slurry at or near the point of delivery. This approach to generating a cold slurry at the point of delivery allows the characteristics of the cold slurry, such as temperature, particle shape and particle size, to be maintained and controlled.

Embodiments of the invention provide apparatus, systems and method for introducing fluids into a body cavity for treatment. One embodiment provides an apparatus for treating a patient including an access device for insertion into the peritoneal cavity of the patient including an infusion member in a lumen of the access device. An oxygenated solution may be infused and removed into and out of the cavity via the infusion member.