The invention discloses a multi-tube body adapter which is connected to a plurality of outer tubes for application to a digestive system and a respiratory system of a human body. The multi-tube body adapter includes a housing to form an accommodating space of the multi-chamber. The plurality of chambers is not in communication with each other. One end of the plurality of chambers respectively provides a connection port and the other end of the plurality of chambers is commonly connected to an extension having a plurality of openings. By connecting with the chamber, the connection port and the opening, a supply path for separately providing the supply path of the respiratory system and the digestive system can be formed.

A vaporizing assembly for an aerosol-generating system may comprise a delivery device and a heater assembly. The heater assembly may comprise a heat resistive substrate and a heating element. The delivery device is configured to deliver an aerosol-forming substrate to at least a surface of the heat resistive substrate, wherein the heating element is isolated or separated from the aerosol-forming substrate by the heat resistive substrate. The present disclosure is also directed to a method for generating an aerosol.

A portable control device (10) for regulating a continuous oxygen flow to a user from an oxygen source, comprising: an inlet (11), to which the oxygen source may be fluidly connected; an outlet (12), to which a breathing device may be fluidly connected; a valve arrangement (20) fluidly connected to said inlet and to said outlet, said valve arrangement being adjustable between a maximum flow state corresponding to a maximum continuous flow of oxygen from the inlet to the outlet, and a minimum flow state corresponding to a minimum continuous flow of oxygen; and an actuator (13) movable between a maximum and a minimum position and being mechanically connected to the valve arrangement so that when said actuator is in the maximum position said valve arrangement is in the maximum flow state and when said actuator is in said minimum position said valve arrangement is in said minimum flow state.

Systems for piercing a septum of a drug delivery device is disclosed. The drug delivery device may include a needle conduit having an end and a drug container having a septum. The septum piercing mechanism may include a needle support operatively coupled to the needle conduit. The septum piercing mechanism may be movable from a first, unactivated configuration to a second, activated configuration. In the unactivated configuration, the septum seals an interior of the drug container from the end of the needle conduit. In the activated configuration, the end of the needle conduit pierces through the septum placing the needle conduit in fluid communication with the drug container. In one embodiment, activation may cause the needle support to move towards the drug container. In one embodiment, the needle support may be moved by a biasing member. Alternatively, in another embodiment, the needle support may be moved by a cam mechanism.

A medical infusion system includes a hose line with a distal end region for connection to an infusion reservoir and a proximal end region that has a patient connection port. The patient connection port has a closure device with an air-permeable and liquid-tight design. The system can be used in the medical sector for intravenous medication.

An injection device assembly including a housing, a syringe, a drive mechanism and one or more sensing systems are described. The drive mechanism advances the syringe from a storage position to an injection position, and a plunger advances the syringe piston from an initial position to a final position. The status sensing system may include one or more main PCB(s) disposed in an end portion of the injection device assembly's housing. The system may determine various parameters related to an operational status of the injection device, including the location of the devices components, an amount of medication remaining in the device, a temperature of the medication, and whether or not the device is properly contacting the users skin before injection. The system may communicate such determined parameters to an external device via a wireless communication link.

A computer-implemented medical system is provided. The system includes a docking station and a mobile machine. The system is configured to perform operations comprising: receiving, by the mobile machine and from a user, a request to transport the mobile machine to a target location to perform a medical treatment; automatically navigating the mobile machine to the target location; performing, by the mobile machine, the medical treatment on a patient; determining, by the mobile machine, that the medical treatment is completed and the mobile machine is disconnected from the patient; automatically navigating the mobile machine to a stationary docking station of the medical system; and determining that the mobile machine is connected to the docking station through one or more connectors, and in response, receiving, by the mobile machine, at least one of an electrical charge, a refill of one or more supplies, a cleaning, or a drain of waste.

A compliance monitoring module for a breath-actuated inhaler comprising: a miniature pressure sensor, a sensor port of said sensor being pneumatically coupled to a flow channel through which a user can inhale; a processor configured to: receive a signal originating from a dosing mechanism of the inhaler indicating that medication has been released; receive data from a sensing element of the sensor; and based on said signal from said dosing mechanism and said data from said sensing element, make a determination that inhalation of a breath containing medication through said flow channel complies with one or more predetermined requirements for successful dosing; and a transmitter configured to, responsive to said determination, issue a dosing report.

A method of configuring a personal living environment of a long-term patient comprises providing a central computer controllable via a remote unit. The central computer is coupled to a plurality of output devices, including displays and speakers, and at least one sensor. The method comprises arranging the plurality of output devices in the personal living environment and presenting on at least one display patient selectable objective parameters and subjective parameters. The method comprises obtaining an input from the patient, and in response to the input, representing on the at least one display a relationship, characterized over a time period, between the subjective parameters and the objective parameters selected by the patient. The method comprises shifting presentation of content from one of the plurality of output devices to another of the plurality of output devices based on a proximity of the patient detected by the at least one sensor.

An electronic cigarette, including an atomizing assembly, a battery assembly, and a box assembly. The atomizing assembly is disposed on the battery assembly. The atomizing assembly includes an e-liquid storage unit and an atomization unit. The atomizing assembly and the battery assembly are disposed in the box assembly. The e-liquid storage unit includes a mouthpiece, a seal ring adapted to seal the mouthpiece, a thread ring, a seal plug, an e-liquid tank, and a tank cover. The atomization unit includes an O-ring, a limit cover, an e-liquid conductive cotton, a heating wire, an insulation ring, and a joint. The battery assembly includes a seal, a support, a first battery cell, a base plate, a first magnet, a cartridge, and a battery cover. The box assembly includes an outer sliding cover, a first screw, an inner sliding cover, a second magnet, a fixed part, a flexible circuit board.