A system to manage the sleep and/or the well-being of a passenger/user of an aircraft includes a chair to be installed in a cabin of the aircraft and interaction devices to interact with the user. The system further includes a user terminal configured to receive data relating to characteristics of a user profile of the user, and a control/command module connected to the user terminal, interaction devices and a database storing information relating to characteristics of a flight of the aircraft. The command/control module being configured to pilot the interaction devices according to the data relating to characteristics of the user profile and characteristics of the flight of the aircraft.

A system to manage the sleep and/or the well-being of a passenger/user of an aircraft includes a chair to be installed in a cabin of the aircraft and interaction devices to interact with the user. The system further includes a user terminal configured to receive data relating to characteristics of a user profile of the user, and a control/command module connected to the user terminal, interaction devices and a database storing information relating to characteristics of a flight of the aircraft. The command/control module being configured to pilot the interaction devices according to the data relating to characteristics of the user profile and characteristics of the flight of the aircraft.

There is provided herein a stress reducing and/or mindfulness inducing apparatus including: a substantially spherically shaped body “huggable” by two hands of a user; at least a first and a second pair of indentations located on an outer surface of said body, wherein each of the first and the second pair of indentations is suitable for placing corresponding index, middle and ring fingers from each hand of the user, wherein each of the first and the second pair of indentations comprises one or more sensors, wherein the one or more sensors are configured to sense one or more parameters associated with the user's stress and/or mindfulness state, wherein the sensors are the same or different from each other; and an indicator having at least two modes of operation, the indicator is configured to provide the user with an indication regarding his/her stress and/or mindfulness state.

There is provided herein a stress reducing and/or mindfulness inducing apparatus including: a substantially spherically shaped body “huggable” by two hands of a user; at least a first and a second pair of indentations located on an outer surface of said body, wherein each of the first and the second pair of indentations is suitable for placing corresponding index, middle and ring fingers from each hand of the user, wherein each of the first and the second pair of indentations comprises one or more sensors, wherein the one or more sensors are configured to sense one or more parameters associated with the user's stress and/or mindfulness state, wherein the sensors are the same or different from each other; and an indicator having at least two modes of operation, the indicator is configured to provide the user with an indication regarding his/her stress and/or mindfulness state.

Disclosed herein are methods, systems, and devices for controlling a gas mixture within a mechanical ventilator. According to one embodiment, a computer implemented method includes receiving first peripheral arterial oxygen saturation (SpO.sub.2) data from a pulse oximeter via a pulse oximeter interface, wherein the pulse oximeter is configured to monitor a patient receiving invasive ventilation; determining a first mode of operation for a ventilator mechanism, wherein the ventilator mechanism is configured to provide at least a portion of the invasive ventilation; determining first partial pressure of oxygen (PaO.sub.2) data stored in a first lookup table using the first SpO.sub.2 data, wherein the first lookup table is derived from a sigmoid shaped oxyhemoglobin dissociation curve; determining first fraction of inspired oxygen in air (FiO.sub.2) data for setting a mixture in a gas blender in the ventilator mechanism based on the first PaO.sub.2 data and a variable offset; and providing the FiO.sub.2 data to the ventilator mechanism.

Disclosed herein are methods, systems, and devices for controlling a gas mixture within a mechanical ventilator. According to one embodiment, a computer implemented method includes receiving first peripheral arterial oxygen saturation (SpO.sub.2) data from a pulse oximeter via a pulse oximeter interface, wherein the pulse oximeter is configured to monitor a patient receiving invasive ventilation; determining a first mode of operation for a ventilator mechanism, wherein the ventilator mechanism is configured to provide at least a portion of the invasive ventilation; determining first partial pressure of oxygen (PaO.sub.2) data stored in a first lookup table using the first SpO.sub.2 data, wherein the first lookup table is derived from a sigmoid shaped oxyhemoglobin dissociation curve; determining first fraction of inspired oxygen in air (FiO.sub.2) data for setting a mixture in a gas blender in the ventilator mechanism based on the first PaO.sub.2 data and a variable offset; and providing the FiO.sub.2 data to the ventilator mechanism.

Disclosed is an oral mucosa delivery system that allows a composition housed therein to be dispensed in different amount and/or for different duration. The delivery system may comprise a spray cap or an aerosol cap capable of controlling the delivery duration and/or amount by a mechanical or electronic means.

Described is a system including an air pressure supply arrangement, a sensor and a titration device. The air pressure supply arrangement provides air pressure to a patient's airways. The sensor detects input data corresponding to a patient's breathing patterns of a plurality of breaths. The titration device receives and analyzes the input data to determine existence of breathing disorder and corresponding characteristics. The titration device generates output data for adjusting the air pressure supplied to the patient as a function of an index of abnormal respiratory events included in the input data.

Described is a system including an air pressure supply arrangement, a sensor and a titration device. The air pressure supply arrangement provides air pressure to a patient's airways. The sensor detects input data corresponding to a patient's breathing patterns of a plurality of breaths. The titration device receives and analyzes the input data to determine existence of breathing disorder and corresponding characteristics. The titration device generates output data for adjusting the air pressure supplied to the patient as a function of an index of abnormal respiratory events included in the input data.