A massage pillow configured to be positioned over a fluid jet includes a cushion and a retaining assembly. The cushion includes a front surface, a rear surface, and side surfaces extending there between. The rear surface includes an annular edge defining an opening providing access to an interior of the cushion sized to at least partially cover the jet. The retainer assembly includes an opening configured to align with the jet and a peripheral edge configured to retain the annular edge of the cushion. The retainer assembly is configured to be removably fixed to a wall surrounding the jet with the jet aligned with the opening of the retainer assembly and the opening of the cushion, such that fluid expelled from the jet passes into the interior of the cushion, so that the pillow provides massage and/or warmth due to the expelled fluid.

An embodiment of a system for treating sleep apnea includes a collar, pump, motor, sensor, memory, and controller, which is configured to store, in the memory, information related to sleep-apnea events or sleep-apnea treatment, experienced by the subject. For example, the controller can obtain, and store in the memory, information related to sleep-apnea events, and the controller, or another computing system, can correlate this information with the subject's lifestyle choices, and can recommend lifestyle changes to improve the subject's sleep apnea. Furthermore, the controller can obtain and store, in the memory, information related to usage and settings of the sleep-apnea system, and the controller, or another computing system, can correlate this information with the subject's wellbeing, and can recommend changes in the usage or the settings of the sleep-apnea system that can improve the subject's wellbeing.

A lung gas exchange device includes a front housing, at least one strap configured to affix the front housing to an anterior neck of a user, a vibration device positioned within the front housing, a wear plate configured to transfer vibration from the vibration device to the anterior neck of the user, a power source configured to provide power to the vibration device, a power control mechanism configured to allow a user to turn on and off the vibration device; and a central processing unit board connected to the power control mechanism, the power source, and the vibration device.

A health-regain device, includes a driving portion, a health portion disposed on one side of the driving portion, and a control module communicably connected to the driving portion, wherein the control module controls the driving portion driving the health portion in rhythmic reciprocating motion.

A device for treatment of temporomandibular joint (TMJ) disorder is disclosed. The device combines the benefits of LED therapy with the stimulation and pain relieving qualities of a transcutaneous electrical nerve simulation (TENS) unit for the TMJ treatment. The device comprises an adjustable headband strap, to be worn by a user. The adjustable strap could consist of a shoulder extension, and face and head extensions, which offers a combined TENS and red LED contact points. The TENS connectors connect a remote TENS controller to the headband strap and the headband strap to the user's skin for the optimum stimulation. Further, the device comprises acupuncture points for skin rejuvenation. A temple strap formed integral to the headband strap consists of a TENS electrode and LED unit and for the adjustment of the headband.

A person's sleep disorders are resolved by applying low frequency vibration. Mechanical vibrators (1) present on a first side of a plate type base member (9) set the plate type base member (9) in vibration in such a way that its second surface transmits mechanical vibration. A plurality of first low frequency pulse trains (100; 101, 102, 103 . . . ) of mechanical vibration are conducted to a part of the person's body, at successive time periods (T; T1, T2, T3 . . . ). A frequency (f) of vibration in each individual pulse train (100) is maintained constant (f; fa, fb, fc . . . ) within the range of 20-50 Hz. The pressure pulses (400) of said pulse train (100) have a contact power (I) with said part of the body within the range of 40-70 dB. The constant frequencies (fa, fb, fc . . . ) of the successive pulse trains (100; 101, 102, 103 . . . ) are mutually different and change monotonously and mostly linearly. At least one second pulse train (100) is transmitted to said part of the body.

A stand-alone continuous cardiac Doppler pulse monitoring patch provides visual and auditory signals that a pulse is detected or not detected in a human subject. The invention is a small patch with a peel-away adhesive surface that is applied to the skin of the subject, preferably near a large artery. The adhesive surface of the patch includes a conductive medium to enhance transmission and reception of ultrasonic waves. The patch includes an integral power source, transmitters and receivers to send and detect reflected ultrasonic waves, a transducer to convert the reflected waves into an electrical signal, a processor to analyze the signal, a light to indicate the presence and strength of a pulse, and a speaker also to indicate the presence and strength of a pulse. The Doppler effect of waves reflecting from blood pumped from a heart is used to detect a pulse in the subject. The presence of a pulse is analyzed by the processor to determine the frequency and strength of blood flow. The processor causes the light to blink at a rate to indicate the frequency of rhythmic blood flow. In a further embodiment, the processor analyzes the strength of the blood flow and causes the light to increase or decrease in intensity to reflect the strength or weakness of the flow. The processor may also drive a speaker to emit sounds, such as beeps, that indicate the frequency and strength of blood flow. The absence of blood flow may be indicated by the absence of light or sound, or by separate light or auditory signals.

A device is provided for automatically assessing functional hemodynamic properties of a patient is provided, the device comprising: a housing; an ultrasound unit coupled to the housing and adapted for adducing ultrasonic waves into the patient at a vessel; a detector adapted to sense signals obtained as a result of adducing ultrasonic waves into the patient at the vessel and to record the; and a processor adapted for receiving the recorded signals as data and transforming the data for output at an interface. Other devices, systems, methods, and/or computer-readable media may be provided in relation to assessing functional hemodynamics of a patient.

Systems and methods for communicating with a guide animal are provided. One embodiment of a method includes determining a first command to provide to a user to proceed to a destination, determining a second command to provide to the guide animal to correspond with the first command, and outputting the first command to direct the user toward the destination. Some embodiments include outputting the second command to direct the guide animal toward the destination, where the second command is outputted to be imperceptible by the user but is perceptible by the guide animal.

Provided is a spinal traction device and a spinal traction method for spinal traction, and the spinal traction device includes: an upper body support unit configured to support an upper body of a person and having at least one spine pressing unit installed on one surface thereof; a lower body support unit configured to support a lower body of the person and having a moving means so as to move away from or close to the upper body support unit; and a controller configured to adjust a movement of the lower body support unit. The spinal traction device has a technical feature in which at least one spine pressing unit is in close contact with and supports the spine of the upper body when the lower body support unit moves.