Device for an endoscopic illumination apparatus comprising a heat pipe having a first end region and a second end region; a first heat source; a heat dissipation element for dissipating thermal energy from said first heat source; a heat sink spaced apart from the first heat source; and a clamping element, wherein the clamping element is reversibly detachably mounted on the heat dissipation element such that the first end region of the heat pipe is held between the heat dissipation element and the clamping element, wherein the heat pipe is adapted to conduct the thermal energy of the heat source to the heat sink, wherein the second end region of the heat pipe is spaced apart from the first end region, and wherein the second end region ends in the heat sink.

Cold plates through which refrigerant flows define a slot between them that can receive a cassette through which sterile working fluid with a relatively low flow rate flows from an intravascular heat exchange catheter. The working fluid from the catheter is heated or cooled by heat exchange with the cold plates through the walls of the cassette to maintain the sterility of the working fluid. On the other hand, high flow rate working fluid chambers surround the cold plates and non-sterile working fluid from an external heat exchange pad flows through the high flow rate working fluid chambers to exchange heat through direct contact with the cold plates.

Device (100, 201) for the adjustment of temperature, especially for the extracorporeal adjustment of the temperature of patients, with a transfer of heat between a fluid and a transfer medium, including a temperature-adjustment body (203) having a primary side which provides a guide for the fluid and having an application side which provides a surface (219) for contacting the temperature-adjustment body (203) with the transfer medium; a cover (221) which is attached to the temperature-adjustment body (203) and which forms a cavity with the temperature-adjustment body (203) on the application side, through which cavity the transfer medium can flow; the cover (221) being attached to the temperature-adjustment body (203) in a detachable manner; and flow-guiding structures (217) for guiding the transfer medium being arranged on the temperature-adjustment body (203) and/or on the cover (221).

A system (20) including a heater/cooler module (22) to heat/cool a first fluid in a primary circuit (28), a heat transfer fluid circuit (24) to provide a second fluid to a target device (38) to heat/cool the target device (38), and a heat exchanger (26) including at least part of the primary circuit (28) and at least part of a secondary circuit (36) through which the second fluid flows to facilitate heat transfer between the first fluid and the second fluid. The primary circuit (28) and the secondary circuit (36) are separate circuits and the first fluid and the second fluid remain separated in the system. Also, the system is modular, such that the elements can be stacked to increase heating/cooling capability and/or to increase the number of heating/cooling channels, and the system is compatible with portable applications, such as ambulance, aircraft, and helicopter applications, and with battery operation and/or the use of uninterruptible power supplies.

A heat exchange system for exchanging heat with working fluid from an intravascular heat exchange catheter or an external heat exchange pad includes a working fluid that circulates between the catheter or pad and a fluid cassette, and a refrigerant system that flows against the outer sides of cold plates between which the cassette is disposed.

A dialysis system includes a filtration system capable of filtering a water stream, a water purification system capable of purifying said water stream in a non-batch process, a mixing system capable of producing a stream of dialysate from mixing one or more dialysate components with the water stream in a non-batch process, and a dialyzer system. The dialyzer may be a microfluidic dialyzer capable of being fluidly coupled to the stream of dialysate and a blood stream.

A storage unit and method for providing heat transfer are disclosed. The storage unit is a storage bag and webs that are both made from the same film material. The storage bag has a top and a bottom surface having interior and exterior surfaces. The interior surface of both the top and bottom surface are connected by the webs. The webs will form channels through which a heat transfer medium can flow. The storage unit can contain bio-pharmaceutical products as well as other medical fluids that need to have heat transferred into or out of.

Device for the extracorporeal controlling of the temperature of patients by transmitting heat between a fluid and a transmission medium, having a primary circuit having a primary unit (102, 201) for receiving the fluid, and a secondary circuit having a secondary unit (104, 200) which includes connectors (240, 242) for infeeding and outfeeding the transmission medium, wherein the secondary unit (104, 200) is capable of being fastened to the primary unit (102, 201) and has nozzles (206) for configuring an impingement flow, said nozzles (206), in the case of a secondary unit (104, 200) being fastened to the primary unit (102, 201), being directed in the direction of the primary unit (102, 201).

A container for warming fluids, the container comprising an inlet port, an outlet port, and a fluid conduit configured for putting the inlet port in fluid communication with the outlet port and comprising one or more deflection sections. The fluid conduit has a non-constant maximum width in a direction of fluid flow through the fluid conduit. At least one of the one or more deflection sections further comprises an entry section and an exit section, each respective exit section being arranged downstream, in the direction of fluid flow, from each respective entry section. The maximum width of the fluid conduit decreases along the direction of fluid flow through the entry section over a first distance and the maximum width of the fluid conduit increases along the direction of fluid flow through the exit section over a second distance, the first distance and the second distance being different from one another. An apparatus for warming medical fluids including the container and an extracorporeal blood circuit including the container are also provided. An extracorporeal blood treatment apparatus including the apparatus for warming medical fluids and/or the extracorporeal blood circuit is also provided.

A blood treatment device includes a heat exchanger having a first space and a second space, with a first fluid flowing through the first space and a second fluid flowing through the second space. The heat exchanger has a membrane which separates the first space from the second space, with the membrane forming a component of a capacitor having two capacitor plates, between which the membrane is located. A monitoring means is connected to the capacitor, and is configured to detect an electrical property of the capacitor, for the purpose of detecting a fluid leak from the first space to the second space.