Systems and methods of delivering a therapeutic session to affect a mental or an emotional state of a user include providing a wearable stimulation device having a transducer adapted to generate tactile transcutaneous vibratory output; with a user interface, obtaining data regarding an event to be experienced by the user; communicating the data regarding an event to be experienced by the user to a computer processor; with the computer processor, creating a therapeutic session parameters comprising the following steps: assigning a set of contiguous output segments for the event, and based on the event, assigning a perceived pitch of transcutaneous vibratory output and a perceived beat of transcutaneous vibratory output to each output segment; sending, from the computer processor, the therapeutic session parameters to the transducer; and generating, with the transducer, transcutaneous vibratory output for the therapeutic session based on the therapeutic session parameters.

Systems and methods of treating a sleep disorder of a subject include providing a therapeutic stimulation device comprising a transducer configured to emit transcutaneous vibratory output to a body part of the subject; generating physiological data with a worn sensor and providing it to a processor; providing a stimulation pattern for transcutaneous vibratory output to be emitted by the transducer comprising a perceived pitch, a perceived beat, and an intensity; causing the transducer to emit the transcutaneous vibratory output in the stimulation pattern; determining if the subject is in a pre-sleep state or a sleep state based on the physiological data; and altering the stimulation pattern based on determining the subject is in at least one of a pre-sleep state or a sleep state comprising at least one of (i) reducing a frequency of the perceived pitch, (ii) increasing an interval of the perceived beat, or (iii) reducing the intensity.

Systems and methods are provided to combine multiple stimulation modalities to significantly increase the effectiveness of non-invasive stimulation. Multiple sensor and stimulation devices and modalities can be combined into a single, compact unit that minimizes the need for additional sensors or stimulation devices. The system features several subunits, referred to as sensory and stimulation devices (SSD), that are integrated into a headphone setup. The system is controlled by a centralized controller that communicates with all of the SSDs and with an external computer system that delivers learning material synchronized with the delivery of stimulations and the collection of user responses based on physiological signals.

The present system comprises a pressure generator, an oscillator, sensors, and computer processors. The pressure generator generates a pressurized flow of breathable gas for delivery to the airway of a subject. The oscillator causes high frequency pressure level oscillations in the pressurized flow of breathable gas. The sensors generate output signals conveying information related to one or more parameters of the gas. The computer processors receive a base expiratory pressure level and a base inspiratory pressure level and control the pressure generator and the oscillator to generate the pressurized flow of breathable gas such that during exhalation the pressure level of the pressurized flow of breathable gas oscillates from or about the base expiratory pressure level and during inhalation the pressure level of the pressurized flow of breathable gas oscillates from or about the base inspiratory pressure level.

The present invention relates to a system, method and corresponding computer program for milk ejection reflex (MER) determination, the system comprising a breast shield arrangement (1) for a breast pump (2) configured to be attached on a first breast of a female, a physiological sensor unit (4) for receiving a physiological reception signal from the second breast, which is opposite to the first breast, wherein the physiological reception signal is indicative of fluid contents in the second breast, and wherein the system is configured to determine a milk ejection reflex based on a change in fluid contents in the second breast. It finds particular application during and in connection with breastfeeding and allows for direct detection of the beginning of the milk flow in the breast, i.e. the occurrence of the MER, without delay and with a high degree of precision.

A system and method for facilitating and maintaining various states of a user consciousness, including the transition between a conscious and unconscious state, is provided. The system and method include use of a smart device having a user interface, a biometric sensor coupled to a user and configured to transmit the user's biometric data to the smart device and an environmental sensor configured to transmit environmental data to the smart device. The smart device controls one or more environmental systems proximate the user and an audio/visual device proximate the user to facilitate transitioning the state of the user.

A system and method for facilitating and maintaining various states of a user consciousness, including the transition between a conscious and unconscious state, is provided. The system and method include use of a smart device having a user interface, a biometric sensor coupled to a user and configured to transmit the user's biometric data to the smart device and an environmental sensor configured to transmit environmental data to the smart device. The smart device controls one or more environmental systems proximate the user and an audio/visual device proximate the user to facilitate transitioning the state of the user.

A ventilation system provides patient-triggered support ventilation to a spontaneously breathing patient during ongoing high frequency ventilation (HFV), and has a pneumatic unit operated by a control computer for delivery of breathing gas in response to an effort to breathe by the patient, and an oscillator for superimposing high frequency oscillation onto the breathing gas. The system further includes a bioelectric sensor that measures a bioelectric signal indicative of the patient's efforts to breathe, and the control computer controls the delivery of breathing gas in response to the patient's effort to breathe, based on this bioelectric signal. The ventilation system is hence designed for neurally triggered support ventilation during ongoing HFV, which makes the trigger mechanism of the ventilation system more precise and robust compared to known trigger mechanisms of HFV ventilation systems.

A nerve cuff for establishing a nerve block on a nerve can have a cuff body with a channel for receiving a nerve, a reservoir for holding a drug, and an elongate opening slit extending the length of the cuff body that can be opened to provide access to the channel and can be closed to enclose the cuff body around the nerve. The nerve cuff can also include an electrode for detecting and measuring electrical signals generated by the nerve. A controller can be used to control delivery of the drug based on the electrical signals generated by the nerve.

A method of transplanting a sleep state of a first subject (donor) to a second subject (recipient) comprising: capturing a sleep state of the first subject represented by brain activity patterns; and transplanting the sleep state of the first subject in the second subject by inducing the brain activity patterns in the second subject.