A Pavlovian conditioned reflex sleep induction kit includes at least one physiological sensor, wherein the at least one physiological sensor is configured to detect at least a physiological parameter of a user and transmit a detection signal to an automatically activated scent diffuser, wherein the automatically activated scent diffuser is configured to receive an electronic activation signal and to diffuse a scent as a function of the electronic activation signal, a control circuit configured to receive the detection signal from the at least one physiological sensor, to ascertain that the user is entering a hypnagogic state, and to transmit the electronic activation signal to the automatically activated scent diffuser, thereby conditioning the user to respond to subsequent sensing of the same scent. For later use, a user-activated scent diffuser is provided, that diffuses the same scent upon activation by a user, to thereby trigger the conditioned reflex to fall asleep.

A method or apparatus to improve sleep aid efficacy is described. The method comprises monitoring the sleeping patterns of a user utilizing a non-intrusive sleep monitoring device. The method further correlates the user's sleep quality and sleep quantity with use of the sleep aid. In one embodiment, the method adjusts the sleep aid based on the sleep statistics.

An ear-worn electronic device includes a right ear device comprising a first processor and a left ear device comprising a second processor communicatively coupled to the first processor. A physiologic sensor module comprises one or more physiologic sensors configured to sense at least one physiologic parameter from a wearer. A motion sensor module comprises one or more sensors configured to sense movement of the wearer. The first and second processors are coupled to the physiologic and motion sensor modules. The first and second processors are configured to produce a three-dimensional virtual sound environment comprising relaxing sounds, generate verbal instructions within the three-dimensional virtual sound environment that guide the wearer through a predetermined mental exercise that promotes wearer relaxation, and generate verbal commentary that assesses wearer compliance with the predetermined mental exercise in response to one or both of the sensed movement and the at least one physiologic parameter.

The present disclosure pertains to delivering sensory stimulation to a user during a sleep session. In some embodiments, sensors are configured to generate output signals conveying information related to brain activity of the user during the sleep session. Sensory stimulators are configured to provide the sensory stimulation to the user during the sleep session. One or more processors are configured to determine a demographic group for the user; select a stimulation parameter model associated with the demographic group of the user from a set of stimulation parameter models associated with different demographic groups; and control the one or more sensory stimulators to deliver the sensory stimulation to the user based on the stimulation parameter model for the demographic group of the user and the output signals.

The present disclosure pertains to delivering sensory stimulation to a user during a sleep session. In some embodiments, sensors are configured to generate output signals conveying information related to brain activity of the user during the sleep session. Sensory stimulators are configured to provide the sensory stimulation to the user during the sleep session. One or more processors are configured to determine a demographic group for the user; select a stimulation parameter model associated with the demographic group of the user from a set of stimulation parameter models associated with different demographic groups; and control the one or more sensory stimulators to deliver the sensory stimulation to the user based on the stimulation parameter model for the demographic group of the user and the output signals.

This disclosure pertains to a system configured to control light exposure for circadian phase management and/or light deficient disorders of a subject. The system comprises a user interface, physiological sensors configured to generate output signals conveying physiological data of the subject, and a light control valve configured to block or reduce blue light ambient radiation reaching eyes of the subject. Processors are in communication with the user interface, the physiological sensors, the light control valve, and radiation generators. The processors cause the system to receive physiological goals of the subject, determine a light control plan based on the physiological goals, the physiological data, environmental data, and time data. The system operates the light control valve to block or reduce blue light ambient radiation based on the light control plan, and generate, using the one or more radiation generators, therapeutic light radiation based on the light control plan.

A sleep inducing device and a sleep management system including the same are provided. The sleep inducing device comprises: a housing unit that includes a frame of which the shape can be changed; a sensor unit that is disposed on one surface of the housing unit and includes a brain-wave measurement sensor that measures a user's brain wave; an output unit that includes a first output unit and a second output unit, wherein the first output unit is located on one side of the housing unit to output a sound or light with a first frequency, and the second output unit is located on an opposite side of the housing unit to output a sound or light with a second frequency that is different from the first frequency; and a control unit that calculates the user's sleep pattern on the basis of the brain wave signal measured by the sensor unit and changes the output signal of the output unit such that the sleep pattern approaches a predetermined value.

The present disclosure pertains to manipulating electrical activity in the brain of a subject to facilitate wakefulness. The system comprises: a sensory stimulator; a sensor configured to generate output signals conveying information related to brain activity, activity of the central nervous system, and/or activity of the peripheral nervous system of the subject; and a processor configured to: receive a target wake-up moment for the subject; determine one or more activity parameters of the subject during the sleep session; determine whether the one or more activity parameters indicate the subject is in deep sleep a predetermined amount of time before the target wake-up moment; and, responsive to the one or more activity parameters indicating the subject is in deep sleep, cause the one or more sensory stimulators to guide the activity parameters and facilitate/accelerate a transition from deep sleep to light sleep before the target wake-up moment.

The present disclosure pertains to manipulating electrical activity in the brain of a subject to facilitate wakefulness. The system comprises: a sensory stimulator; a sensor configured to generate output signals conveying information related to brain activity, activity of the central nervous system, and/or activity of the peripheral nervous system of the subject; and a processor configured to: receive a target wake-up moment for the subject; determine one or more activity parameters of the subject during the sleep session; determine whether the one or more activity parameters indicate the subject is in deep sleep a predetermined amount of time before the target wake-up moment; and, responsive to the one or more activity parameters indicating the subject is in deep sleep, cause the one or more sensory stimulators to guide the activity parameters and facilitate/accelerate a transition from deep sleep to light sleep before the target wake-up moment.

A turbulator adapted to be mounted to or inserted in an inlet portion of a flow meter for a ventilator is disclosed. The turbulator is adapted to create a turbulent gas flow in the inlet portion downstream of the turbulator upon passage of a gas flow therethrough. A flow meter for a ventilator is provided. The flow meter may comprise such turbulator. The turbulator may be arranged in the inlet portion of the flow meter. A membrane for a ventilator flow meter is provided, as well as a flow meter comprising the membrane. A flow meter comprising a turbulator and a membrane is disclosed.