A personal vapor inhaling unit is disclosed. An electronic flameless vapor inhaler unit that may simulate a cigarette has a cavity that receives a cartridge in the distal end of the inhaler unit. The cartridge brings a substance to be vaporized in contact with a wick. When the unit is activated, and the user provides suction, the substance to be vaporized is drawn out of the cartridge, through the wick, and is atomized by the wick into a cavity containing a heating element. The heating element vaporizes the atomized substance. The vapors then continue to be pulled by the user through a mouthpiece and mouthpiece cover where they may be inhaled.

This document describes a system for determining positioning of an intubation tube in a patient. The system can include a first acoustic sensor configured to be disposed to listen to one of a lung and a stomach of the patient and to provide a first signal. The system includes a signal processing unit, coupled to the first acoustic sensor, configured to analyze spectral components of the first signal and determine whether a frequency of the spectral components of the first signal are characteristic of sounds induced by ventilation via the intubation tube of airflow to the lung or the stomach of the patient.

A system includes a mobile device having one or more cameras to take images; a sensor detecting reflected light from one or more lasers and a diffuser to detect object range or dimension; code for motion tracking, environmental understanding by detecting planes in an environment, and estimating light and dimensions of the surrounding based on the one or more lasers; code to estimate a three-dimensional (3D) volume of an object from multiple perspectives and from projected laser beams to measure size or scale and determine locations of points on the object's surface in a plane or a slice using time-of-flight, wherein positions and cross-sections for different slices are correlated to construct a 3D model of the object, including object position and shape; the device receiving user request to select a content from one or more augmented, virtual, or extended reality contents and rendering a reality view of the environment.

A system includes a mobile device having one or more cameras to take images; a sensor detecting reflected light from one or more lasers and a diffuser to detect object range or dimension; code for motion tracking, environmental understanding by detecting planes in an environment, and estimating light and dimensions of the surrounding based on the one or more lasers; code to estimate a three-dimensional (3D) volume of an object from multiple perspectives and from projected laser beams to measure size or scale and determine locations of points on the object's surface in a plane or a slice using time-of-flight, wherein positions and cross-sections for different slices are correlated to construct a 3D model of the object, including object position and shape; the device receiving user request to select a content from one or more augmented, virtual, or extended reality contents and rendering a reality view of the environment.

Systems and methods for detection and/or intervention of stress episodes such as nightmares during sleep activity or flashbacks or anxiety attacks during waking or sleep activity. In some embodiments, sensors, such as gyroscopes, accelerometers, heart rate sensors, and/or other sensors, may be used for monitoring stress indicators indicative of a user's stress level. The sensed stress indicators may be used to calculate a stress level. If the stress level meets or exceeds a stress level threshold, haptic, audio, visual, and/or other feedback or alerts may be used to draw a user's attention and thus interrupt the stress episode.

Systems and methods for detection and/or intervention of stress episodes such as nightmares during sleep activity or flashbacks or anxiety attacks during waking or sleep activity. In some embodiments, sensors, such as gyroscopes, accelerometers, heart rate sensors, and/or other sensors, may be used for monitoring stress indicators indicative of a user's stress level. The sensed stress indicators may be used to calculate a stress level. If the stress level meets or exceeds a stress level threshold, haptic, audio, visual, and/or other feedback or alerts may be used to draw a user's attention and thus interrupt the stress episode.

A skin desensitizing device for temporarily numbing and/or cooling a surface of a subject's skin. The skin desensitizing device comprises a controller, a skin-bracing interface, and at least one overloading-neural source, which includes (i) a transcutaneous electrical nerve stimulator (TENS)-like device capable of electrically stimulating superficial skin neurons of the subject's skin into a state of fibrillation, (ii) a thermoelectric device capable of cooling the subject's skin to approximately 30° F. to 38° F., and (iii) a vibration device capable of vibrating the subject's skin to overload the skin's vibration sensors.

A skin desensitizing device for temporarily numbing and/or cooling a surface of a subject's skin. The skin desensitizing device comprises a controller, a skin-bracing interface, and at least one overloading-neural source, which includes (i) a transcutaneous electrical nerve stimulator (TENS)-like device capable of electrically stimulating superficial skin neurons of the subject's skin into a state of fibrillation, (ii) a thermoelectric device capable of cooling the subject's skin to approximately 30° F. to 38° F., and (iii) a vibration device capable of vibrating the subject's skin to overload the skin's vibration sensors.

A processor of a medical device configured to communicate with a remote server can be programmed to protect the medical device from exposure to unauthorized or malicious software. A system or method to implement this form of protection can include, for example, at least one processor on the medical device, a control software module that controls the operation of the medical device and is executable on the processor, a data management module that manages data flow to and from the control software module from sources external to the medical device, and an agent module that has access to a limited number of designated memory locations in the medical device. In addition, a hemodialysis apparatus can be configured to operate in conjunction with an apparatus for providing purified water from a source such as a municipal water supply or a well. A system for controlling delivery of purified water to the hemodialysis apparatus can comprise a therapy controller of the hemodialysis apparatus configured to communicate with a controller of a water purification device, and a user interface controller of the hemodialysis apparatus configured to communicate with the therapy controller, and to send data to and receive data from a user interface.

A patient management system for providing patient queues of patient reports to users includes communications circuitry configured to receive first physiological information from monitoring medical devices being worn by a first plurality of patients and receive second physiological information from therapeutic medical devices being worn by a second plurality of patients. Each of the monitoring medical devices is configured to sense one or more predetermined physiological parameters of its respective patient. Each of the therapeutic medical devices is configured to monitor its respective patient for a predetermined physiological condition and provide a treatment. The patient management system also includes at least one processor configured to prepare a plurality of monitoring patient reports, prepare a plurality of therapeutic patient reports, generate a patient queue based on the pluralities of monitoring and therapeutic patient reports, and provide the patient queue to an end user computing device via the communications circuitry.