Abstract: An embodiment provides techniques for distinguishing between breathing events based on sensor data obtained from one or more wearable sensors. In one example, sensor data is obtained that includes one or more of a sensor signal and descriptive metadata of the sensor signal. Processing is applied to distinguish between a cough and another breathing event based on the sensor data, and an indication of a cough is provided.

Abstract: An intelligent oral appliance (100) comprises maxillary and mandibular appliances (102, 104), an electromagnetic clamp (106, 108), first and second sensors (110, 112), a timer (114), and a controller (116). The electromagnetic clamp (106, 108) couples between the maxillary (102) and mandibular (104) appliances and operates according to engaged and disengaged clamping actions. The first sensor (110) detects a body/head position/orientation. The second sensor (112) detects a characteristic of sleep disordered breathing, snoring intensity, or combination thereof. The timer (114) provides preset time intervals.

Abstract: A system for determining an airway flow value in a patient is provided. The system comprises a computer system that comprises one or more physical processors programmed with computer program instructions which, when executed cause the computer system to obtain, from one or more health monitoring devices, airway pressure information of the patient and airway flow information of the patient; determine an airway flow limitation index from the airway pressure information of the patient and the airway flow information of the patient; and determine the airway flow limitation value for the patient by comparing the determined airway flow limitation index with an airway flow limitation threshold value. The airway flow limitation value indicates a number of breaths of the patient that are flow limited in a given time period.

Abstract: A system for adjusting extrinsic positive end expiratory pressure during an expiratory phase of a ventilator is provided. The system includes a computer system that comprises one or more physical processors programmed with computer program instructions which, when executed cause the computer system to: determine a respiratory reactance from airway flow information of the patient and airway pressure information of the patient, the airway flow information and airway pressure information of the patient being obtained from one or more sensors, and adjust the extrinsic positive end expiratory pressure during the expiratory phase of the ventilator such that the determined respiratory reactance falls within a defined respiratory reactance range.

Abstract: A health status monitoring method includes: (a) analyzing transport layer data for a dwelling to identify a plurality of occupant specific transport layer data items based on MAC address mapping, (b) establishing an Internet traffic pattern for the occupant for a period of time based on the identified plurality of occupant specific transport layer data items, (c) comparing the established Internet traffic pattern to a predetermined baseline Internet traffic pattern for the occupant and identifying a deviation from the predetermined baseline Internet traffic pattern based on the comparison, and (d) determining that a change in the health status is possible for the occupant based on the identifying of the deviation.

Abstract: A system includes facilitating therapy with couples working together for perceiving shared positive benefits by treating sleep disordered breathing issues. Spousal influence can greatly influence and motivate the patient in continuing the therapy. Moreover, through monitoring bed partners' sleep using wearable data, causal information about whose sleep is affecting whom can be inferred. Users can be prompted to seek diagnosis and treatment for sleep disordered breathing conditions and can be used to help coach around therapy adherence.

Abstract: An apparatus and method for non-invasive determination of airway resistance for the detection of pulmonary airway disease includes providing an apparatus and method wherein changes in a pulsatile blood pressure waveform are detected by PhotoPlethysmoGram (PPG) or Ballistography (BSG) and are automatically determined to reflect decreases in airflow and changes in airway resistance.

Abstract: A health status monitoring method includes: (a) analyzing transport layer data for a dwelling to identify a plurality of occupant specific transport layer data items based on MAC address mapping, (b) establishing an Internet traffic pattern for the occupant for a period of time based on the identified plurality of occupant specific transport layer data items, (c) comparing the established Internet traffic pattern to a predetermined baseline Internet traffic pattern for the occupant and identifying a deviation from the predetermined baseline Internet traffic pattern based on the comparison, and (d) determining that a change in the health status is possible for the occupant based on the identifying of the deviation.

Abstract: A method of providing pressure support to a patient that includes determining a measure associated with an inspiratory time of the patient during therapy, delivering a flow of breathing gas to the patient at an inspiratory positive airway pressure (IPAP) level during at least a portion of an inspiratory phase of the patient, delivering the flow of breathing gas to the patient at an expiratory positive airway pressure (EPAP) level that is less than the IPAP level during at least a portion of an expiratory phase of the patient, and automatically setting a rise time associated with a transition from the EPAP level to the IPAP level based on the measure associated with the inspiratory time of the patient. Also provided is a pressure support system adapted to perform the method.

Abstract: 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.

Abstract: The present disclosure pertains to a system and method for controlling insufflation pressure during inexsufflation of a subject. The system inexsufflates the subject such that tidal flow and/or tidal volume are monitored during insufflation, and insufflation pressure is adjusted to maintain the flow rate of the pressurized flow of breathable gas until a target tidal volume is reached for the insufflation. When the target tidal volume has substantially been reached, the system is causes gas to be evacuated from the airway of the subject. This may provide for more precise, customized therapy for the subject than is provided by conventional inexsufflation systems in which inspiratory flow may not be monitored and/or controlled. In one embodiment, the system comprises one or more of a pressure generator, a subject interface, one or more sensors, a processor, a user interface, electronic storage, and/or other components.

Abstract: A system for adjusting extrinsic positive end expiratory pressure during an expiratory phase of a ventilator is provided. The system includes a computer system that comprises one or more physical processors programmed with computer program instructions which, when executed cause the computer system to: determine a respiratory reactance from airway flow information of the patient and airway pressure information of the patient, the airway flow information and airway pressure information of the patient being obtained from one or more sensors, and adjust the extrinsic positive end expiratory pressure during the expiratory phase of the ventilator such that the determined respiratory reactance falls within a defined respiratory reactance range.

Abstract: A system for determining an airway flow value in a patient is provided. The system comprises a computer system that comprises one or more physical processors programmed with computer program instructions which, when executed cause the computer system to obtain, from one or more health monitoring devices, airway pressure information of the patient and airway flow information of the patient; determine an airway flow limitation index from the airway pressure information of the patient and the airway flow information of the patient; and determine the airway flow limitation value for the patient by comparing the determined airway flow limitation index with an airway flow limitation threshold value. The airway flow limitation value indicates a number of breaths of the patient that are flow limited in a given time period.

Abstract: A method of providing pressure support to a patient that includes determining a measure associated with an inspiratory time of the patient during therapy, delivering a flow of breathing gas to the patient at an inspiratory positive airway pressure (IPAP) level during at least a portion of an inspiratory phase of the patient, delivering the flow of breathing gas to the patient at an expiratory positive airway pressure (EPAP) level that is less than the IPAP level during at least a portion of an expiratory phase of the patient, and automatically setting a rise time associated with a transition from the EPAP level to the IPAP level based on the measure associated with the inspiratory time of the patient. Also provided is a pressure support system adapted to perform the method.

Abstract: The present disclosure pertains to a pillow system (40), in particular a pillow system that surrounds the subject's head. In some embodiments, the pillow system provides sound suppression. In some embodiments used with positive airways pressure (“PAP”) systems, the pillow system includes a tube that delivers breathable gas to a mask.

Abstract: The present disclosure pertains to a pillow system, in particular a pillow system that surrounds the subject's head, and moves with the subject. In some embodiments, the pillow system provides sound suppression. In some embodiments used with positive airways pressure (“PAP”) systems, the pillow system includes a tube that delivers breathable gas to a mask.

Abstract: Compounds of the formula (I) wherein X and Y are independently O, S or NR5, R1, R2 and R4 are independently hydrogen, halogen, C1-C6alkyl, C1-C6haloalkyl, C1-C6alkoxy or C1-C6haloalkoxy and R3 is an aromatic five-membered heterocycle, which can be substituted are useful as a pesticides especially fungicide.

Abstract: A system and method for delivering a flow of gas to an airway of a patient (54). The system includes a gas flow generator (52) and a patient circuit (56) comprising a conduit (100) that communicates the flow of gas to a patient. A sensor (62) is configured to measure a rate of the flow gas and generate flow signals based on the measured rate of flow. A controller (64) is operatively connected with the gas flow generator (52) and the sensor (62) and is configured to control a pressure of the flow of gas provided to the patient. The controller (64) receives the flow signals from the sensor (62), determines a rate of change in the flow of the gas, and modifies or compensates the pressure of the flow of gas provided to the patient if the rate of change in the flow of gas provided to the patient exceeds a threshold amount.

Abstract: A system for controlling machine-induced expiratory airflow of a subject, the subject having an airway, the system comprising: a pressure generator (140) configured to generate a pressurized flow of breathable gas for delivery to the airway of the subject; and one or more processors (110) configured to execute computer program modules, the computer program modules comprising: a control module (170) configured to control the pressure generator a metric determination module (154) configured to determine a value of a flow metric during expiration by the subject, a flow analysis module (156) configured to compare the determined value of the flow metric with a target level of the flow metric; and an adjustment module (160) configured to adjust one or more of exsufflation pressure.

Abstract: A pressurized flow of breathable gas is delivered to the airway of a subject in accordance with a therapy regime. Responsive to the subject resuming respiration after a respiratory event, delivery of the pressurized flow of breathable gas is resumed at an inhalation in the therapy regime. As such, the therapy regime is effectively re-synchronized with the respiration of the subject subsequent to a respiratory event.