A connection unit establishes a fluid connection between a patient and a ventilator. The connection unit includes a patient-side connection piece, a device-side connection piece, a port piece and a central piece, which provides a tube with a curved tube segment and is connected with a fluid-tight connection to the two connection pieces. The port piece includes a straight tube segment and a bent surface with a bent surface and with a passage opening. The port piece is inserted into a receiving opening of the central piece. The bent surface of the port piece forms a part of a wall of the curved tube segment. The straight tube segment of the port piece and the central piece provide a straight tube, which is interrupted by the passage opening. An additional device is insertable through the straight tube segment and through the passage opening into the provided tube.

A connection unit establishes a fluid connection between a patient and a ventilator. The connection unit includes a patient-side connection piece, a device-side connection piece, a port piece and a central piece, which provides a tube with a curved tube segment and is connected with a fluid-tight connection to the two connection pieces. The port piece includes a straight tube segment and a bent surface with a bent surface and with a passage opening. The port piece is inserted into a receiving opening of the central piece. The bent surface of the port piece forms a part of a wall of the curved tube segment. The straight tube segment of the port piece and the central piece provide a straight tube, which is interrupted by the passage opening. An additional device is insertable through the straight tube segment and through the passage opening into the provided tube.

A device for controlling respiration during sleep based on the user physiological characteristic. The device includes an odor disperser for dispersing an odor; at least one detector for detecting a physiological characteristic of a user; and a controller for controlling respiration of the user by instructing the odor dispenser to disperse an odor responsive to detections by the at least one detector.

In general, drug administration devices configured to communicate with networks and external devices are provided. In an exemplary embodiment, a drug administration device is configured to adjust an operational parameter of the drug administration device based on a data packet formed from drug administration data ancillary data received from networks and/or external devices. In another example embodiment, a drug administration device is configured to scan for and establish communications with at least one external device. In another example embodiment, a method includes assessing whether to update a control program on a drug administration device from a network or external device. In another example embodiment, a system includes a first drug administration device configured to communicate with a second drug administration device to optimize a drug treatment.

In general, drug administration devices configured to communicate with networks and external devices are provided. In an exemplary embodiment, a drug administration device is configured to adjust an operational parameter of the drug administration device based on a data packet formed from drug administration data ancillary data received from networks and/or external devices. In another example embodiment, a drug administration device is configured to scan for and establish communications with at least one external device. In another example embodiment, a method includes assessing whether to update a control program on a drug administration device from a network or external device. In another example embodiment, a system includes a first drug administration device configured to communicate with a second drug administration device to optimize a drug treatment.

A mist inhaler device (200) for generating a mist for inhalation by a user. The device comprises a mist generator device (201) and a driver device (202). The driver device (202) is configured to drive the mist generator device (201) at an optimum frequency to maximise the efficiency of mist generation by the mist generator device (201).

This disclosure describes systems and methods for providing novel adaptive base flow scheduling during ventilation of a patient to optimize the accuracy of estimated exhaled tidal volume. Further, this disclosure describes systems and methods for providing novel adaptive inspiratory trigger threshold scheduling during the novel adaptive base flow scheduling.

An attachment for monitoring an inhaler usage to be used for monitoring a usage frequency of patients using inhalers is provided. The attachment allows monitoring the inhaler usage of the patients and provides a low energy consumption. With an effective power management system developed with the attachment, the attachment is used for a longer period of time without a need for a battery replacement.

The disclosure provides systems and methods for neuromodulation using a housing that at least partially contains a stimulator assembly, wherein the stimulator assembly is configured to generate vibration by mechanical oscillation and/or using a sound wave; and wherein the vibration generated by the stimulator assembly is configured to therapeutically treat the subject by stimulating one or more nerves when the housing is placed in proximity to or on a skin surface of a subject.

The disclosure provides systems and methods for neuromodulation using a housing that at least partially contains a stimulator assembly, wherein the stimulator assembly is configured to generate vibration by mechanical oscillation and/or using a sound wave; and wherein the vibration generated by the stimulator assembly is configured to therapeutically treat the subject by stimulating one or more nerves when the housing is placed in proximity to or on a skin surface of a subject.