Systems and methods of the present disclosure are directed to neural stimulation via audio and visual stimulations. The combination and/or sequence of audio and visual brain stimulations can adjust, control or otherwise manage the frequency of the neural oscillations to provide beneficial effects to one or more cognitive states or cognitive functions of the brain, while mitigating or preventing adverse consequences on a cognitive state or cognitive function that stems from sleep deprivation. In doing so, the present systems and methods can reduce sleep fragmentation, improve sleep quality, and slow the progression of cognitive decline in a subject with Alzheimer's disease and MCI.

A method of controlled delivery of breathing gases is described the method comprising: applying breathing gas pressure within the first naris of a patient during inhalation; applying breathing gas pressure within the second naris of the patient during inhalation; applying breathing gas pressure within the first naris of the patient during exhalation; and applying breathing gas pressure within the second naris of the patient during exhalation, wherein the breathing gas pressure applied to the first naris during inhalation is higher than the gas pressure applied to the second naris during inhalation and the breathing gas inflow to the patient is substantially through the first naris during inhalation and wherein the breathing gas pressure applied to the first naris during exhalation is lower than the gas pressure applied to the second naris during exhalation and the gas outflow from the patient is substantially through the first naris during exhalation. An apparatus and system implementing the method is also described.

A method of controlled delivery of breathing gases is described the method comprising: applying breathing gas pressure within the first naris of a patient during inhalation; applying breathing gas pressure within the second naris of the patient during inhalation; applying breathing gas pressure within the first naris of the patient during exhalation; and applying breathing gas pressure within the second naris of the patient during exhalation, wherein the breathing gas pressure applied to the first naris during inhalation is higher than the gas pressure applied to the second naris during inhalation and the breathing gas inflow to the patient is substantially through the first naris during inhalation and wherein the breathing gas pressure applied to the first naris during exhalation is lower than the gas pressure applied to the second naris during exhalation and the gas outflow from the patient is substantially through the first naris during exhalation. An apparatus and system implementing the method is also described.

Systems and methods for inducing natural sleep in a subject is provided. In some aspects, the method includes inducing a first sleep state; monitoring a first plurality of characteristics of a brain of the subject to verify the subject is in the first sleep state; inducing a second sleep state after the subject has been in the first sleep state for a predetermined amount of time; and monitoring a second plurality of characteristics of the brain of the subject to verify the subject is in the second sleep state.

A system that determines one or more sleep phenotyping parameters of a subject. In one embodiment, the system comprises a sleep sensor, a stimulus generator, and a processor. The sleep sensor generates signals that convey information related to the physiological functions that indicate the sleep stage of the subject. The stimulus generator provides a stimulus to the subject that enables information related to the sleep phenotyping parameters to be determined. The processor receives the signals generated by the sleep sensor and is in operative communication with the stimulus generator. The processor (i) determines, based on the signals received from the sleep sensor, whether a trigger condition related to the current sleep stage of the subject is satisfied, (ii) controls the stimulus generator to provide the stimulus to the subject if the trigger condition is satisfied, and (iii) quantifies the response of the subject to the stimulus.

A system that determines one or more sleep phenotyping parameters of a subject. In one embodiment, the system comprises a sleep sensor, a stimulus generator, and a processor. The sleep sensor generates signals that convey information related to the physiological functions that indicate the sleep stage of the subject. The stimulus generator provides a stimulus to the subject that enables information related to the sleep phenotyping parameters to be determined. The processor receives the signals generated by the sleep sensor and is in operative communication with the stimulus generator. The processor (i) determines, based on the signals received from the sleep sensor, whether a trigger condition related to the current sleep stage of the subject is satisfied, (ii) controls the stimulus generator to provide the stimulus to the subject if the trigger condition is satisfied, and (iii) quantifies the response of the subject to the stimulus.

The invention relates to a method for secure communication in a respiratory system during the remote adjustment of a respiratory device by a server.

The present invention relates to an integrated sleep diagnosis and treatment device, and more particularly to an integrated apnea diagnosis and treatment device. The present invention additionally relates to methods of sleep diagnosis and treatment. The sleep disorder treatment system of the present invention can use a diagnosis device to perform various forms of analysis to determine or diagnose a subject's sleeping disorder or symptoms of a subject's sleep disorder, and using this analysis or diagnosis can with or in some embodiments without human intervention treat the subject either physically or chemically to improve the sleeping disorder or the symptoms of the sleeping disorder. The diagnostic part of the system can use many different types of sensors and methods for diagnosing the severity of the symptoms of or the sleep disorder itself. The treatment part of the system can use a device to physically or chemically treat the subject's symptoms or sleep disorder itself.

Apparatuses (including devices, kits, and systems) and methods to non-invasively and chemically (rather than thermally) activate thermoreceptors to modulate sleep. For example, described herein are apparatuses including topical compositions that stimulate thermoreceptors on the subject's skin (e.g., forehead, hands, and/or feet) for a period of time to induce a sensation of temperature (heat or cold) without significantly altering the person's actual skin temperature to improve sleep quality, including reducing sleep-onset latency, enhancing depth of sleep, and/or extending the amount of time a subject sleeps. The subject may be suffering from insomnia or some other sleep disorder.

Apparatuses (including devices, kits, and systems) and methods to non-invasively and chemically (rather than thermally) activate thermoreceptors to modulate sleep. For example, described herein are apparatuses including topical compositions that stimulate thermoreceptors on the subject's skin (e.g., forehead, hands, and/or feet) for a period of time to induce a sensation of temperature (heat or cold) without significantly altering the person's actual skin temperature to improve sleep quality, including reducing sleep-onset latency, enhancing depth of sleep, and/or extending the amount of time a subject sleeps. The subject may be suffering from insomnia or some other sleep disorder.