The invention relates to a device for treating an individual suffering from cardiac or circulatory arrest or from a stroke, comprising a blood withdrawal device (BE) that is applied to the individual (P), an analysis unit (BA) which is directly or indirectly connected to the blood withdrawal device for detecting a blood analysis result (BAE) providing at least one characteristic of the blood, directly or indirectly connected to a blood return device (BR) that is applied to the individual (P) and is designed to deliver a substance to the individual via the return device (BR).

A heart lung machine (HLM) includes a control area net-work (CAN); a pump; a number of sensors; and a control assembly, all communicatively coupled to the CAN. The control assembly includes a control display device and a processing unit, which is configured to fa-cilitate a semi-automatic safety check. To do so, the processing unit is configured to provide an HLM system safety check user interface (UI) on a display device, the HLM system safety check UI including a rep-resentation of each sensor; activate a sensor; present, via the UI, an in-dication of the activation of the sensor; determine an alarm state of the sensor; present a representation of the alarm state of the sensor on the control display device; present a safety check result of the sensor via the UI; and save a safety check result corresponding to the sensor.

Disclosed herein are methods of treating venous thrombosis and vascular inflammation through administration of carbon monoxide and/or a carbon monoxide releasing molecule. Also disclosed herein are devices capable of releasing carbon monoxide for the purpose of treating microvascular, arterial and venous thromboembolism and/or inflammation.

An arterial cannula connects to a heart-lung machine for supplying a patient with oxygen-rich blood and includes a tubular body having a front end region for positioning at the aortic arch, a main region, and a rear end region for connection to the supply side. The length of the tubular body is dimensioned so that the cannula can be placed at the femoral artery and extends to the aortic arch. The tubular body is flexible and includes a lumen, and perforations in the front end region. The front end region is pre-curved, following the shape of the aortic arch. An insertion aid is located inside the tubular body for placing the cannula and is slidable into or withdrawable from the tubular body after the cannula has been placed. The curvature of the front end region adjusts automatically after the cannula is placed and the insertion aid withdrawn.

The present application relates to a method for controlling a disinfection status of a heater and/or cooler for human body temperature control during extracorporeal circulation. The temperature control is conducted by use of a heat exchanger and a temperature control liquid circulating through the heat exchanger and the heater and/or cooler. The inventive method comprises using a long term disinfectant in the temperature control liquid, measuring and preferably recording the concentration of the disinfectant in the temperature control liquid and deducing a disinfectant status of the temperature control liquid from the measured concentration of the disinfectant in the temperature control liquid.

A system for cardiopulmonary bypass, including: a cardiopulmonary bypass reservoir configured to store a blood; a pump in fluid communication with the cardiopulmonary bypass reservoir configured to provide pressure to the system; an oxygen source including a pressure regulator configured to regulate an oxygen pressure; an oxygenator fluidly connected to the pressure regulator of the oxygen source via an sweep gas inlet, wherein the sweep gas inlet is configured to have a subatmospheric pressure and the oxygenator is configured to oxygenate the blood; a vacuum regulator fluidly connected to the oxygenator via an sweep gas outlet, and configured to provide the subatmospheric pressure; a flow restrictor fluidly connected to the sweep gas inlet and configured to allow for a pressure drop from the oxygen source to the oxygenator; and an arterial filter fluidly connected to a blood outlet of the oxygenator and to the cardiopulmonary bypass reservoir.

An exchanger for medical use comprises: a box-like body having a base, an upper end, a peripheral wall that delimits a heat exchange chamber; the body having: a first aperture from which a fluid to be thermo-regulated enters and a first exit of the thermo-regulated fluid; a second delivery aperture of a thermo-regulator fluid and a second exit of the thermo-regulated fluid; a heat exchange element that exchanges heat by lapping, housed in the exchange chamber and held between two holding elements, dividing the exchange chamber into a zone where the thermo-regulator fluid flows and a zone where the fluid to be thermo-regulated flows, which are fluid-dynamically separated from each other; a collection compartment to collect the air separated from the fluid to be thermo-regulated, obtained in the opposite end, connected to the thermo-regulation chamber and equipped with an aperture toward the outside; the box-like body has a second housing chamber for a pumping group, connected with the heat exchange chamber.

The present application relates to a method for disinfection of a temperature control device for human body temperature control during extracorporeal circulation which temperature control is conducted by use of a heat exchanger and a temperature control liquid circulating through the heat exchanger and the temperature control device. According to the present application, the temperature control device is connected to a temperature control liquid supply and, during operation of the temperature control device for human body temperature control, a disinfectant is selectively added to the temperature control liquid supply upstream of the temperature control device.

The invention is a cooling unit for a heat exchanger, which preferably is a heat exchanger integrated in an oxygenator for the purpose of controlling the temperature of blood conveyed in an extracorporeal blood circuit. The cooling unit has a reservoir in which a liquid is stored, a reaction vessel comprises a reactant and which, in conjunction with the liquid, is able to initiate an endothermal reaction. A fluidic access is generated between the reservoir and the reaction vessel. A fluid line extends at least in part inside the reaction vessel which has an inlet line and outlet line, which are each connectable or connected in a fluid-tight manner to a hose system of the heat exchanger, which together with the hose system of the heat exchanger, provides least part of a fluid circuit.

An extension cannula for use with a conventional ECMO return cannula is provided. The extension cannula includes a flexible conduit transitionable between a collapsed insertion state and an expanded deployed state when in communication with blood flow from an ECMO machine via the ECMO return cannula. The extension cannula may be positioned through a conventional ECMO return cannula such that the proximal end of the flexible conduit is disposed within and proximal to the end of the ECMO return cannula, while the distal end of the flexible conduit is disposed in a patient's thoracic aorta to deliver oxygenated blood directly to the patient's thoracic aorta via one or more pores at the distal region of the flexible conduit to improve cerebral oxygenation, maintain systemic arterial pulsatility, and reduce the potential for end-organ injury.