A gas circuit control system of a pneumatic cardiopulmonary resuscitation pressing device comprises a gas control valve (3) communicating with a piston cylinder (2) of the pneumatic cardiopulmonary resuscitation pressing device, and a spool of the gas control valve (3) controls gas charging and discharging of the piston cylinder (2) when reciprocating; and at least one end of the spool of the gas control valve (3) is provided with a gas cavity, the gas cavity communicates with a gas source through a miniature electronic control valve (4), and the miniature electronic control valve controls gas charging and discharging of the gas cavity to drive the spool of the gas control valve (3) to reciprocate. The gas circuit control system of a pneumatic cardiopulmonary resuscitation pressing device can greatly reduce the power consumption of electronic control pneumatic pressing devices

A device performs a flexion process or an extension process with respect to a knee joint. The device includes a support frame extending in a longitudinal direction. A flexion system includes a foot support assembly configured to translate relative to the support frame in the longitudinal direction thereof and a flexion linear actuator configured to cause the translation of the foot support assembly. The extension system an extension pad assembly including a first expansion pad configured to engage an upper surface of the leg at a position above the knee joint and a second expansion pad configured to engage the upper surface of the leg at a position below the knee joint. An extension linear actuator is configured to translate the extension pad assembly with respect to the transverse direction. A power system is configured to selectively actuate each of the flexion linear actuator and the extension linear actuator.

A system for assisting cardio-pulmonary resuscitation (CPR) treatment of a patient includes a defibrillator system including a defibrillator communicatively coupled to a local computing device and configured to receive signals from treatment sensors, a patient support section, and a tilt adjuster coupled to the patient support section. The tilt adjuster is configured to communicatively couple with the defibrillator system, receive a control signal indicative of a target tilt angle from the local computing device, and automatically tilt the patient support section, around a transverse axis, to the target tilt angle in response to the control signal from the local computing device. The system also includes a chest compression device mount disposed on the patient support section and configured to adjustably secure a chest compression device to the patient support section.

The present invention relates to a cardiopulmonary resuscitation system (1; 2) comprising a chest compression device (11; 12), a support frame (21) of the chest compression device (11; 12) and coupling means (31) of the chest compression device (11; 12) to a patient (200), wherein the chest compression device (11; 12) is pneumatically operated and solidly coupled to the support plate (21) at a side (121) of it support plate (21), and wherein the coupling means (31) comprise a pairs of anchoring devices (131, 231) arranged on opposite ends (321, 421) of the support plate (21) and suitable for anchoring the support plate (21) to the ground (100), wherein the pairs of anchoring devices (131, 231) consist of belts provided with at least an end operatively coupled respectively to one of the opposite ends (321, 421) of the support plate (21), and wherein each of the anchoring devices (131, 231) defines at least a loop allowing an operator to hold them onto the ground (100) by inserting the terminal segment of the upper or lower limbs of the operator within the loops.

A time saving sit on cardio pulmonary resuscitation device and method wherein the said device for providing cpr is adopted with an arrangement to seat a person and enable the start of cpr within five minutes of a heart attack affecting a patient, comprising of a reciprocating resuscitation force applicator where a counter force to the reactive force arising on applying compression force for resuscitation, said counter force being provided by the weight of a person sitting on the seating means and a belt based drive conveyance means forming a loop from top of a enclosure box allowing cpr without latching. A very clearly understandable, unambiguous, two step method of sitting on the device placed around the patient body, no confusion, no decision steps, no mental thinking on what to do. The device takes care of most decisions automatically.

A respiration-assistance apparatus or method can include or use a lifting element such as to cyclically push, pull, or lift, toward a superior direction of the subject, at least one subject region during an inhalation portion of a respiration cycle of the subject. A cyclical member can couple the lifting element to a fixed reference. Abdominal or ribcage compression can be provided. A multi-action or other cam can be used, such as together with a reciprocating element. Examples can be configured for use with a wheelchair, a bed, a vacuum or suction affixation element, a wearable garment, etc.

A CPR machine (100) is configured to perform, on a patient's (182) chest, compressions that alternate with releases. The CPR machine includes a compression mechanism (148), and a driver system (141) configured to drive the compression mechanism. A force sensing system (149) may sense a compression force, and the driving can be adjusted accordingly if there is a surprise. For instance, driving may have been automatic according to a motion-time profile, which is adjusted if the compression force is not as expected (850). An optional chest-lifting device (152) may lift the chest between the compressions, to assist actively the decompression of the chest. A lifting force may be sensed, and the motion-time profile can be adjusted if the compression force or the lifting force is not as expected.

Apparatuses and methods for snore disrupting and prevention are disclosed. One apparatus includes: an inflatable bladder assembly configured to inflate and deflate to move a head of a user; a conduit connected to the bladder assembly and configured to extend at a distance from the bladder assembly; an air inflator connected to the conduit for inflating the bladder assembly through the conduit, the air inflator being at the distance from the bladder assembly when in use to minimize noise, radiation or discomfort for the user a controller in communication with the air inflator to actuate the air inflator to inflate the bladder assembly; and an audio processor in communication with the controller, the audio processor being configured to detect sound waves and transmit control commands to the controller to trigger cyclical actuation of the air inflator upon a trigger event.

The present invention relates to a device (100) wearable at a user's neck, which device (100) comprises:—a main body (10) provided with movable pushing means (11),—a control unit (20) configured to receive as input data associated with the user's heart rate and to generate a corresponding output signal (20′), wherein said output signal (20) determines a pulsating movement of said pushing means (11) according to the heart rate and wherein said pushing means (11) is positioned so as to compress and decompress the neck at the jugular veins.

Examples of the disclosure are directed to mechanical compression devices that can adjust a location of a compression position relative to a patient. One or more of the mechanical compression devices can adjust the compression position in an adjustment plane that is generally perpendicular to a patient. Some of the mechanical compression include support columns that have actuators that can be set asymmetrically to adjust the compression position and/or can be tilted relative to the backboard to adjust the compression position. Other examples includes mechanical compression devices that have multiple actuators that can be used to adjust the compression position as well as provide compressions.