Introduced are a bed device system and methods for: gathering human biological signals, such as heart rate, breathing rate, or temperature; analyzing the gathered human biological signals; and controlling the bed device system, e.g., a temperature of the bed device, based on the analysis.

Introduced are a bed device system and methods for: gathering human biological signals, such as heart rate, breathing rate, or temperature; analyzing the gathered human biological signals; and controlling the bed device system, e.g., a temperature of the bed device, based on the analysis.

A system for reducing a kinetosis effect in at least one passenger of a vehicle comprises at least one set of headphones having two loudspeakers and at least one first ear bud, wherein the at least one set of headphones is designed, at least by means of a sensor device integrated in the first ear bud, to detect the kinetosis effect in the auditory canal of the respective passenger via measurement of the body temperature and to provide acoustic signals by means of the two loudspeakers in order to reduce the kinetosis effect of the passenger depending on the kinetosis effect detected. Forces acting on the passenger and their countenance can also be measured.

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 system and method for measuring the effectiveness of a dose from an inhaler on a user is disclosed. The inhaler includes a drug container and a dosing mechanism coupled to the drug container to aerate a dose from the drug container. The dosing mechanism provides the aerated dose to the user. A sensor interface is in communication with a physiological sensor. The physiological sensor is attached to a user to sense a physiological response to the dose. Physiological data is sent to the sensor interface. A controller is coupled to the sensor interface to collect the sensed physiological data from the user corresponding to the time that the aerated dose is delivered to the user. The effectiveness of the dose may be determined from the collected data. The dose amount or frequency may be changed or the drug may be changed based on the collected data.

A system and method for measuring the effectiveness of a dose from an inhaler on a user is disclosed. The inhaler includes a drug container and a dosing mechanism coupled to the drug container to aerate a dose from the drug container. The dosing mechanism provides the aerated dose to the user. A sensor interface is in communication with a physiological sensor. The physiological sensor is attached to a user to sense a physiological response to the dose. Physiological data is sent to the sensor interface. A controller is coupled to the sensor interface to collect the sensed physiological data from the user corresponding to the time that the aerated dose is delivered to the user. The effectiveness of the dose may be determined from the collected data. The dose amount or frequency may be changed or the drug may be changed based on the collected data.

A method for managing sleep of a user comprises obtaining, by a computing system, sleep data and environmental data for the user; determining, by the computing system, a sleep state of the user based on the sleep data; determining, by the computing system, one or more awakening actions based on the sleep state of the user and the environmental data; and causing one or more devices in an environment of the user to perform the one or more awakening actions to awaken the user.

Provided is an electronic atomization apparatus in the technical field of atomization. The electronic atomization apparatus includes a main unit and an atomizer. The main unit includes a housing component, a control assembly, and a battery assembly. The control assembly and the battery assembly are disposed inside the housing component. The control assembly is electrically connected to the battery assembly. The atomizer includes an atomization housing and a heating circuit disposed inside the atomization housing. One end of the atomization housing is connected to one end of the housing component. The atomization housing is provided with at least two atomization compartments that are independent of each other. The heating circuit is electrically connected to the control assembly. Another end of the atomization housing is provided with a gas outlet. The gas outlet may selectively communicate with one of the at least two atomization compartments.

Medical techniques include systems and methods for administering a positive pressure ventilation, a positive end expiratory pressure, and a vacuum to a person. Approaches also include treating a person with an intrathoracic pressure regulator so as to modulate or upregulate the autonomic system of the person, and treating a person with a combination of an intrathoracic pressure regulation treatment and an intra-aortic balloon pump treatment.