The invention relates to a device for neurovascular stimulation, at least comprising: at least one brain activity sensor, at least one cardiovascular sensor, at least one computing unit and at least one output unit. The computing unit comprises at least one task algorithm, wherein signals of at least the brain activity sensor and the cardiovascular sensor can be received by the computing unit, and wherein a task, which is in correlation with at least the signals from at least the brain activity sensor and the signals of the cardiovascular sensor, can be determined by means of the task algorithm and can be output by means of the output unit.

The invention relates to a device for neurovascular stimulation, at least comprising: at least one brain activity sensor, at least one cardiovascular sensor, at least one computing unit and at least one output unit. The computing unit comprises at least one task algorithm, wherein signals of at least the brain activity sensor and the cardiovascular sensor can be received by the computing unit, and wherein a task, which is in correlation with at least the signals from at least the brain activity sensor and the signals of the cardiovascular sensor, can be determined by means of the task algorithm and can be output by means of the output unit.

Systems and methods for adjusting a user's circadian rhythm are provided. In some embodiments, a system may be configured to obtain information relating to the user's present circadian rhythm and information relating to one or more anticipated times of sleep and/or wakefulness. The system may generate a model for estimating the user's circadian rhythm. The system may also generate a model for estimating the user's homeostatic sleep drive. Based on one or both models, the system may generate instructions for activating the light source to adjust the user's circadian rhythm.

Systems and methods for adjusting a user's circadian rhythm are provided. In some embodiments, a system may be configured to obtain information relating to the user's present circadian rhythm and information relating to one or more anticipated times of sleep and/or wakefulness. The system may generate a model for estimating the user's circadian rhythm. The system may also generate a model for estimating the user's homeostatic sleep drive. Based on one or both models, the system may generate instructions for activating the light source to adjust the user's circadian rhythm.

A respiratory assistance device including a respiratory interface device configured to be worn by a user and deliver a gas, a gas temperature measurement unit configured to measure a gas temperature that is a temperature of the gas, a warming unit configured to warm the gas, and a temperature change unit configured to change the gas temperature by controlling the warming unit. The respiratory assistance device can administer comfortable respiratory assistance even during sleep.

Disclosed are methods and devices for modulating delta brainwaves in a sleeping subject. In various embodiments, the method includes a) detecting and monitoring an initial delta wave in a subject, b) applying an electrical current to modulate the initial delta wave in the subject, thereby modifying the initial delta wave in the subject to form a modified delta wave, and, optionally, repeating cycles of steps a) and b), thereby modulating delta brainwaves.

Disclosed are methods and devices for modulating delta brainwaves in a sleeping subject. In various embodiments, the method includes a) detecting and monitoring an initial delta wave in a subject, b) applying an electrical current to modulate the initial delta wave in the subject, thereby modifying the initial delta wave in the subject to form a modified delta wave, and, optionally, repeating cycles of steps a) and b), thereby modulating delta brainwaves.

An oral therapy device structure and methods of utilizing said device are described. Embodiments of the oral therapy device structure include a top member and a bottom member, where the top member fits over at least a portion of the upper teeth of a user, and includes one or more partially embedded sensors. The bottom member fits over at least a portion of the bottom teeth of the user. A coupling structure physically joins a portion of the top member to a portion of the bottom member. A mandibular positioning drive (MPD) is at least partially embedded within the bottom member, where the MPD is capable of moving the bottom member from a first position to a second position.

A vaporizer system may include a vaporizer device and a vaporizer accessory configured to couple to the vaporizer device. The vaporizer accessory may include a sensor configured to continuously and passively monitor a biomarker of the user. The biomarker includes a concentration of carbon monoxide in the user's blood. Related systems and methods are also described.

A multisensory environment apparatus for providing stress reduction to a user is disclosed. The apparatus includes a support frame that defines a recess. Auditory signal generators, somatosensory signal modules, olfactive signal modules, visual signal modules, and vestibular signal modules are positioned to deliver the associated to a user positioned in the recess. One or more of these signals are delivered to the user by the multisensory environment apparatus during a session. The delivery of the auditory and vibrotactile signals to the user work to meet the user's vital functions where they are, entrain them, and guide them to a more relaxed state, helping to reduce stress. The combination of the signals and the apparatus provide short term relief of acute stress, and long term benefits by breaking the cycle of chronic stress.