An automated chest compression device for performing CPR, with distance sensors disposed on a compressing mechanism and on a structure fixed relative to the CPR patient, for determining inferior/superior movement of the compressing mechanism over the course of multiple compressions.

A chest compression device for cardiopulmonary resuscitation may include a support structure for placement about a patient's chest and for holding a chest compressor above a patient's sternum; a chest compressor mounted on the support structure; and lateral chest supports attached to the support structure at points laterally on either side of the chest when the device is in use, such that the lateral chest supports will apply lateral pressure to the sides of the chest synchronised with a chest compression by the chest compressor.

An autonomous mechanical CPR device is disclosed having a CPR unit attached to a free-standing support assembly. In operation, a victim is placed in the support assembly such that the CPR unit can compress the victim's chest. The CPR device is preferably portable, and it provides the recommended depth of chest compression at the recommended rate.

In embodiments, a CPR chest compression system includes a retention structure that can retain the patient's body, and a compression mechanism that can perform automatically CPR compressions and releases to the patient's chest. The compression mechanism can pause the performing of the CPR compressions for a short time, so that an attendant can check the patient. The CPR system also includes a user interface that can output a human-perceptible check patient prompt, to alert an attendant to check the patient during the pause. An advantage can be when the attendant checks in situations where the condition of the patient might have changed, and an adjustment is needed. Or in situations where the patient may have improved enough to where the compressions are no longer needed.

The present invention provides a mattress system (1) devised to achieve a function of automatic detection, mainly comprising: a mattress (2) having a simple structure; a control unit (3) equipped with a unique user interface (31) for caregivers to simultaneously adjust three major functions, namely, therapy mode, therapy intensity and comfort level; and a connection pipe (4) for supplying air and power. The system (1) is further provided with a built-in auto-setting function to sense the body characteristics of the patient (39) lying on the mattress (2) and determine an effective supporting pressure range for the patient (39). By detecting a pressure difference representing the body characteristics of the patient (39) lying on the mattress (2) and comparing with the data stored in a built-in database, the system (1) can always provide the patient (39) with not only a well-proved therapeutic effect through the auto-setting function, but also an adjustable comfort level on the patient's request through the user interface (31).

An elevation device for the performance of CPR includes a base and a support coupled to the base that is configured to incline relative to the base so as to bend an individual at the individual's waist, thereby elevating an individual's heart, head, and shoulders relative to horizontal. The elevation device includes a chest compression device coupled with the support. The chest compression device includes a compression surface that is configured to interface with the individual's chest. The chest compression device is coupled to the support such that the chest compression device is configured to repeatedly compress the chest by applying force that is uniformly distributed across the compression surface during each chest compression and while the head, heart, and shoulders are elevated such that the compression surface does not shift position on the chest while the heart, head, and shoulders are elevated and chest compressions are being performed.

An elevation device used in the performance of cardiopulmonary resuscitation (CPR) includes a base and an upper support pivotably coupled to the base. The upper support is configured to elevate the individual's upper back, shoulders and head when pivoted. The upper support is expandable lengthwise. The upper support includes a neck support that is configured to support the individual's spine in a region of the individual's C7 and C8 vertebrae throughout elevation of the upper back, shoulders and head.

A patient support structure for assisting cardiopulmonary resuscitation (CPR) treatment of a patient is described. The patient support structure includes a base frame, one or more patient support sections supported by the base frame, at least one tilt adjuster coupled to at least one of the patient support sections and configured to tilt the at least one of the patient support sections, around a transverse axis of the patient support structure, to a tilt angle, and a chest compression (CC) device mount disposed on at least one of the patient support sections and configured to adjustably secure a CC device to the patient support structure. The tilt angle may be a target tilt angle and the patient support structure may further include a processor configured to determine the target tilt angle based on at least one of sensor input and user input.

An automated chest compression device has a housing for supporting a patient and a motor within the housing. A conical drive spool is operatively connected to the motor and a cable, is operatively connected to the conical drive spool. The cable is adapted to extend at least partially around the chest of the patient. A controller is operable to control the motor to compress the chest to variable thresholds.

A patient support apparatus for supporting a patient includes a mattress with an inflatable mattress portion with a plurality of states. The apparatus further includes a control system to control inflation or deflation of the mattress portion to change its state between two or more of the states. The apparatus further includes a user interface in communication with the control system, which is configured to allow a user to select an inflate or deflate function of the mattress portion to change the state of the mattress portion. Further, the control system is operable to inflate or deflate the mattress portion in response to the signal being generated when a user selects an inflate or deflate function at the user interface. The control system is configured to generate a notification indicative of the selected state of the mattress portion to remind to a caregiver to change the selected state.