A vane compressor for a surgical gas delivery system is disclosed, which includes a compressor head having an outlet port for delivering pressurized gas to a gaseous sealing manifold communicating with a gas sealed trocar and an inlet port for receiving spent gas from the gaseous sealing manifold by way of the gas sealed trocar, wherein the compressor head is coupled to and driven by a motor.

A manifold assembly for a surgical gas delivery system is disclosed, which includes a manifold body including an inlet port for receiving gas from an outlet side of a compressor and an outlet port for recirculating gas to an inlet side of the compressor, a bypass valve communicating with the inlet port and the outlet port of the manifold body, an air ventilation valve for dynamically controlling the ingress of air from atmosphere, a smoke evacuation valve for dynamically controlling the egress of gas from the manifold assembly when the gas delivery system is operating in a smoke evacuation mode, and a gas fill for dynamically controlling the receipt of gas from a source of surgical gas.

A gas heater for a surgical gas delivery system is disclosed, which includes an elongated tubular body defining an interior flow passage having an inlet port for receiving insufflation gas from a gas source and an outlet port for delivering heated insufflation gas to an insufflation manifold, a dielectric support positioned within the interior flow passage of the tubular body, and a resistive element operatively associated with the dielectric support for heating insufflation gas flowing through the tubular body from the inlet port to the outlet port.

A manifold assembly for a surgical gas delivery system is disclosed, which includes a manifold body having an inlet port for receiving insufflation gas from a gas source by way of a high pressure regulator, a first outlet port for delivering insufflation gas to a first access port and a second outlet port for delivering insufflation gas to a second access port, a first outlet line valve operatively associated with the first outlet port, wherein the first outlet line valve includes a first electro-mechanical valve actuator for dynamically controlling the flow of insufflation gas to the first access port, and a second outlet line valve operatively associated with the second outlet port, wherein the second outlet line valve includes a second electro-mechanical valve actuator for dynamically controlling the flow of insufflation gas to the second access port.

The present disclosure relates to a transportable device for providing a cooled, oxygen-containing gas flow for supplying to a body of mammal via the respiratory tract, in particular a human being, in order to lower the body temperature. The device comprises a storage device comprising at least one fluid reservoir and at least one heat exchanger, wherein the storage device is designed to store an oxygen-containing fluid in the fluid reservoir and for providing a discharge flow of the oxygen-containing fluid. The heat exchanger is designed to cool the provided discharge flow by transferring heat to a cooling stream of a stored fluid and provided by the storage device, and a cooled, oxygen-containing gas flow for supplying to the body emerges from the heat exchanger.

A quick-connector for use with an autoretroperfusion and hypothermia system and methods of using the connector. The connector comprises a coolant inlet, a coolant outlet, a coolant reservoir, a blood lumen outlet, a blood lumen inlet, and a blood lumen, whereby the coolant outlet is configured to accept a cooling product from the reservoir, the reservoir is configured to accept cooling product from the coolant inlet. Flowing blood powered by the patient's heart may enter the connector through the blood lumen inlet, travel through the blood lumen while being cooled by cooling product in the reservoir, and leave the connector through the blood lumen outlet. The temperature of blood leaving the connector can be measured at the blood lumen outlet. Catheters can be attached to the blood lumen inlet and blood lumen outlet to receive and send blood, respectively. A cooling system can be attached to the coolant inlet and coolant outlet to provide a source of cooling product.

A transdermal patch comprising: a microneedle in a protruding position, protruding from the transdermal patch; and immobilised functional molecules; wherein a fluid path is provided between the distal tip of the microneedle and the immobilised functional molecules; and the functional molecules are selected to interact with selected target molecules so as to convert or trap said target molecules. The device intends to dynamically curb the postprandial insulin spike offering an unprecedented therapeutic effect for diabetes and obesity with significant benefits in morbidity and without strict diet. The device offers unprecedented phenylketonuria management that removes the burden of strict diet. The device offers easy removal of autoantibodies, low density lipoprotein and other pathogenic molecules. The device can be used in any disorder that requires enzymatic replacement or elimination of pathogenic molecules via biochemical conversion or trapping.

An interactive therapeutic blanket system is disclosed. The interactive therapeutic blanket system provides a set of selectable features that serve to address mental health therapeutic user needs. In one embodiment, a user selects a selectable blanket configuration using a system interface and a blanket system controller controls a set of active blanket devices to the selectable blanket configuration. In one feature, the set of active blanket devices include a set of vibration devices operating according to a temporally-referenced vibration regimen. In another feature, the set of active blanket devices include a set of pressure devices to impart discrete pressure to a user at discrete body locations.

A drug delivery system includes a storage container defining one or more storage compartments and having at least one container sensor coupled thereto, a container condition change mechanism coupled to the storage container for imparting a change on one or more conditions of the one or more storage compartments, at least one drug delivery device adapted to deliver a drug to a user and adapted to be at least partially disposed within one or more of the one or more storage compartments, at least one delivery device sensor, a delivery device condition change mechanism coupled to the drug delivery device, and a controller coupled to the storage container. The storage container may be adapted to hold a number of drug delivery devices within a number of sealable storage compartments. The container sensor is adapted to sense a condition of the storage container, and the delivery device sensor is adapted to sense a condition of the at least one drug delivery device. The controller is adapted to instruct the container condition change mechanism and/or the delivery device change mechanism to impart a change on at least one condition of the storage container and/or the drug delivery device.

Disclosed is a local cooling anesthesia device for spraying a coolant on a treatment site. The local cooling anesthesia device includes a housing which forms an outward form and from which the coolant is sprayed and a spraying unit installed in the housing to spray the coolant. The device also includes a cooling temperature regulator connected to the spraying unit to apply thermal energy to the sprayed coolant for temperature regulation and a control unit connected to the cooling temperature regulator to control the cooling temperature regulator. The cooling anesthesia device has functions of measuring and regulating the temperature of the coolant, and thus can apply the coolant to the treatment site within a safe temperature range according to the purpose of treatment, thereby enabling a desired treatment purpose such as local anesthesia to be safely and rapidly accomplished without side effects such as cytoclasis.