A system for providing treatment adapted to clear lung airways, the system including at least one pressure applicator adapted, when activated, to apply pressure at at least one specific location on a torso of a patient, and, when deactivated, to release the pressure, a sensor for sensing a signal associated with the patient, and, a controller, in communication with the sensor, adapted to analyze the signal and to control activation and deactivation of the at least one pressure applicator based, at least in part, on analyzing the signal. Related apparatus and methods are also described.

In an example, an apparatus is described that includes an implantable housing, a heart signal sensing circuit configured to sense intrinsic electrical heart signals, a ventricular tachyarrhythmia (VT) detector circuit, operatively coupled to the heart signal sensing circuit, the detector circuit operable to detect a VT based on the sensed heart signals, a processor configured to control delivery of an anti-tachyarrhythmia pacing (ATP) therapy based on the detected VT, and an energy delivery circuit configured to deliver the ATP therapy in response to the detected VT, wherein the apparatus does not include a shock circuit capable of delivering a therapeutically-effective cardioverting or defibrillating shock.

A protective dressing includes an outer dressing and an adhesive layer. The outer dressing includes an opening and a cavity sized to receive a phase-change material (PCM) insert inserted through the opening. The adhesive layer is configured to adhere to a patient's skin surrounding an anatomic site. When adhered to the patient's skin, the PCM insert modifies the patient's skin at the anatomic site. The PCM insert may be removed and replaced with another PCM insert. For example, a warm PCM insert may be replaced with a refrigerated PCM insert. The opening of the outer dressing may be self-sealing. The opening of the outer dressing may be sealed with an upper layer dressing coupled to the PCM cooling insert.

A method for stabilizing a gait of a user wearing a hearing device comprises: sensing an audio signal with a microphone of the hearing device; modifying the audio signal with the hearing device into a modified audio signal; sensing a movement signal of the user with a movement sensor of the hearing device; determining a step signal indicative of a timing of steps of the user and/or a sway signal of the user indicative of a sway of the user over time from the movement signal; predicting a future step signal from the step signal; triggering a cue signal depending on the future step signal and/or the future sway signal; generating an output cue to be output to the user, the output cue comprising an acoustic cue; and adding the acoustic cue to the audio signal or the modified audio signal at the timing of the cue signal.

Personal thermal stability control herein provides for personalized temperature regulation dependent upon biometric sensor feedback, sleep stage, and so on, particularly for sleeping users, predicting and preemptively responding to fluctuations indicative of thermal stability, resulting from such things as transitions between sleep stages, hot flashes, night sweats, and general thermal instability. Specifically, in one embodiment, a system herein may comprise: an on-demand cooling system; one or more biometric sensors configured to monitor one or more corresponding indicators of thermal stability of a user; and a controller configured to: a) receive the one or more corresponding indicators of thermal stability of the user; b) predict an onset of a thermal instability of the user based on the one or more corresponding indicators of thermal stability of the user; and c) activate the on-demand cooling system to counteract the predicted onset of a thermal instability of the user.

A method of detecting catheter movement includes positioning a first sensor in a first body cavity, monitoring a first parameter profile of the first body cavity, positioning a second sensor in a second body cavity, monitoring a second parameter profile of the second body cavity, the second parameter profile different than the first parameter profile at a first time, and, when the second parameter profile is the same as the first parameter profile at a second time after the first time, taking a catheter movement action.

Devices, systems and methods for treating various disorders and medical conditions through noninvasive stimulation of a nerve. A system comprises a stimulator including an electrode configured to contact an outer skin surface of a patient and an energy source coupled to the housing, The energy source generates an electrical impulse and the stimulator transmits the electrical impulse from the electrode transcutaneously through an outer skin surface of the patient to a selected nerve within the patient. The system further includes an application on a mobile device that receives data from a remote source. The mobile device couples to the stimulator and the application causes the mobile device to transmit the data to the stimulator.

Methods, systems and wearable devices for real-time mental stress assessment are provided. The methods and systems employ deep learning using a Gated Recurrent Unit (GRU) gating mechanism in a recurrent neural network with a sliding window approach applied to raw EEG data.

A vibrotactile stimulation device intended to be applied against a body medium (MC) to be stimulated, produced in the form of a functional unit, comprising a vibrating effector suitable for applying, to said medium, pulses of mechanical vibrational energy, and a controller for controlling the effector according to stimulation rules. The functional unit further houses a first electrode suitable for cooperating with at least one second electrode separated from the first electrode in order to supply signals representative of a cardiac activity and a muscular activity on the medium to be stimulated, said controller being sensitive to cardiac activity and muscular activity signals in order to influence the stimulation. The stimulation device may be used for body stimulation in combating sleep apnea, with improved detection.

Disclosed are an automatic control system for urinary incontinence with a function of multi-point switching in turn and an intracorporeal apparatus (200) thereof. The intracorporeal apparatus (200) is completely implanted in a body. The intracorporeal apparatus (200) comprises an intracorporeal microcontroller (220) and urethral blockers (230), the intracorporeal microcontroller (220) being configured to control the urethral blockers (230) to block and unblock the urethra. The intracorporeal apparatus (200) comprises at least two urethral blockers (230) provided at different locations on the urethra, i.e., a first urethral blocker (230a) and a second urethral blocker (230b), and the intracorporeal microcontroller (220) is configured to control the at least two urethral blockers (230) to block and unblock the urethra in turn.