Systems and methods are provided for identifying a therapeutic VR activity or exercise for a subject/patient based on the subject's impairments, dynamically adjusting a VR activity for a patient, and identifying potential impairments based on a patient's performance in a VR activity. Patients may each have various physical, neurological, cognitive, and/or sensory impairments to be treated. Not all therapeutic activities may be appropriate for some patients and their impairments. A VR therapeutic activity platform may increase patient engagement and challenge patients at more appropriate times by better matching activities corresponding to a patient's impairments and dynamically adjusting each VR activity based on performance to offer a challenging and rewarding therapeutic experience.

A thoracic catheter protector pouch (1) to be worn by an adult, person or infant has a band (2) that encircles a body portion, such as a chest or arm, and a medial pocket portion (5) for holding a catheter tube (10) and connector end (11). The pocket portion has an inner panel (15) with a catheter tube securement strap (14) and two flaps (3 and 4) which open to insert a catheter and close over each other securely by fasteners (6 and 7) preferably hook and loop fastening material. The band is preferably elastomeric and is size adjustable.

A device and method for inducing sleep, improving blood circulation, and correcting autonomous imbalances. The device includes a heat exchange member mounted on top of housing, the heat exchange member can receive a neck of a user and apply alternate hot and cold stimuli to the neck. The hot and cold stimuli improve blood circulation and correct the autonomous imbalances. The device includes a drive module and a heat sink to quickly switch from hot to cold.

A bed includes components to control pressure of a sleep surface, for example based on sleep position and sleep stages of a user. In some embodiments target pressures for the sleep surface are iteratively adjusted over multiple sleep sessions so to achieve improvements in sleep states and/or sleep quality for the user.

The present invention relates to a chest tube insertion device using an endoscopic guide, the device having a structure comprising: a tube insertion guide body which is made from a transparent or semitransparent synthetic resin material and which is introduced into the thoracic cavity of the human body while being flexibly bendable, an endoscopic tube disposed inside the tube insertion guide body; a chest tube formed as a structure for encompassing the outer side of the tube insertion guide body, so as to be spaced from the endoscopic tube; a guide holder for performing an endoscopic guide function and a tube insertion guide body fixing function when the tube insertion guide body is inserted into the thoracic cavity; and a handle part to which the guide holder is separably coupled.

In an embodiment, a control system is described. The control system controls a respiratory support system for supplying therapy gas to a subject. The control system comprises processing circuitry communicatively coupled to an interface for receiving an indication of a combination of the subject's head orientation and torso orientation. The indication is based on orientation data provided by a sensing system configured to detect the subject's head orientation and torso orientation. The control system further comprises a machine-readable medium storing instructions. When executed by the processing circuitry, the instructions cause the processing circuitry to identify, from parameter information associated with each of a set of different combinations of head orientation and torso orientation, a parameter value of the therapy gas for the respiratory support system to use in supplying the therapy gas to the subject for the indicated combination of the subject's head orientation and torso orientation. The respiratory support system is caused to supply the therapy gas with the identified parameter value.

Systems and methods for reducing vibrations perceived by a human due to an artificial heart valve include a vest that is wearable around a torso of the human, a plurality of sensors mounted to the vest, a plurality of vibration-generating actuators mounted to the vest, and a controller. The plurality of sensors detects vibrations in the human generated by the artificial heart valve. The controller is operable to receive signals representing the detected vibrations from the plurality of sensors, and is operable to produce anti-vibration signals that substantially attenuate the detected vibrations. A first sensor of the plurality of sensors is located near a first vibration-generating actuator of the plurality of vibration-generating actuators to form a sensor/actuator set. In the sensor/actuator set, the anti-vibration signals generated by the controller for the first vibration-generating actuator correspond to the vibrations detected by the first sensor.

A transportable extracorporeal system includes a housing, a blood flow inlet, a blood flow outlet, a plurality of hollow gas permeable fibers, a gas inlet in fluid connection with inlets of the plurality of hollow gas permeable fibers, a gas outlet in fluid connection with outlets of the plurality of hollow gas permeable fibers, a first moving element, a concentrated oxygen generating device, a second moving element, a hollow transport conduit having a proximal opening and a distal opening and a power source configured to provide power to the first and second moving elements. The plurality of hollow gas permeable fibers comprising a gas transfer membrane. The concentrated oxygen generating device is configured to recycle waste oxygen from the gas transfer membrane to increase throughput and remove, by an adsorption/desorption process, unwanted gasses.

A chest-supported nebulizer apparatus. The chest-supported nebulizer apparatus has a planar base that rests on the chest of a user. At least one lateral strap and a neck strap is removably securable from the planar base. The neck strap can encircle the neck of the user and is slidably adjustable to adjust the length of the neck strap. A receptacle is disposed in the planar base, wherein the receptacle can receive a central support therein. The central support is pivotally affixed to the receptacle, allowing a user to adjust the angle of the central support relative to the planar base. A support assembly is slidably affixed to the central support. The support assembly is sized to receive a nebulizer.

The present invention relates to an apparatus that provides therapeutic effects and a source of hydration. The apparatus includes a garment that has one or more compartments for storing a therapeutic element. The therapeutic element may include one or more herbs, essential oils, and combinations thereof. The apparatus also includes a portable drinking apparatus attached to the garment. The portable drinking apparatus includes a pouch having a liquid reservoir inserted therein and a drinking tube having a first end in fluid communication with the liquid reservoir and a second end having a mouth operated valve. Methods of use are also disclosed.