Abstract: A CPR guidance device for placement and use on the chest of an adult patient. The device guides a rescuer in the application of an adult CPR protocol. The device also senses patient characteristics indicative of an infant patient. If the device senses that the patient in an infant, it appropriately warns the rescuer that the device is for adult patient use only.

Abstract: A system for providing control signals for ventilating or compressing, respectively, includes an information receiving device that receives, for a resuscitation, information regarding a compression parameter and/or ventilation parameter, as function of a parameter indicative of blood circulation, a processing component for evaluating the different values of the chest compression parameter and/or ventilation parameter as function of the parameter indicative of blood circulation and deriving based on said information a value for the ventilation parameter and/or chest compression parameter respectively, and a control signal generator for generating control signals according to the derived ventilation parameter or chest compression parameter.

Abstract: In one embodiment, the invention provides a medical method for treating a person and comprises repeatedly compressing the person's chest. While repeatedly compressing the person's chest, the method further includes repeatedly delivering a positive pressure breath to the person and extracting respiratory gases from the person's airway using a vacuum following the positive pressure breath to create an intrathoracic vacuum to lower pressures in the thorax and to enhance blood flow back to the heart.

Abstract: The present disclosure discloses an apparatus of cardiopulmonary resuscitator that is operated through a driving mechanism controlled and driven by air power. The driving mechanism functions to actuate a belt adapted to extend around a chest of a patient to generate reciprocating movement of pressing and releasing so as to achieve a purpose of cardiopulmonary resuscitation for recovering heartbeat and breathing of the patent.

Abstract: Devices and methods for performing CPR on a patient within an imaging field of an imaging device. The device has a compression belt and a belt tensioning mechanism, both located on or in the device such that the head, neck, thorax and abdomen of the patient may be place within the imaging field with the compression belt installed about the patient and the belt tensioning mechanism will be located outside of the imaging field.

Abstract: The invention is a manual CPR or CCC continuous chest compression assist device for use on a person suffering cardiac arrest. The assist device has a compressible body structure and an audible signal element, visual signal assembly or both. The audio signal element is interposed in the body structure to announce or generate an audible sound or “click” at a predetermined deflection of the compressible portions. The visual signal assembly is interposed in the body structure to announce or generate a visible light at a predetermined deflection of the compressible portions. The activation of the visual or audio signal corresponds to a predetermined deflection of the compressible portions pressing against the breastbone and alerts the person administering to initiate decompressing to relax the body structure for the next compression, upon relaxation the device decompresses and a second audible or visual signal or both indicates a reset of the device.

Abstract: A system for processing chest compression signals is disclosed including a processing unit, a depth signal device, and a threshold device comprising upper and lower thresholds. The system may also include a force signal device. The processing unit is adapted to output a signal depending on values of depth and force signals with respect to the thresholds.

Abstract: A piston-based automated CPR chest compression device with accelerometer feedback.

Abstract: A piston-based automated CPR chest compression device with accelerometer feedback.

Abstract: A patient interface kit for a system for providing cardiopulmonary resuscitation or circulatory support to a patient, the system including a control unit, the kit including an inflatable abdominal cuff adapted to extend over a patient's abdomen and including an elongated flexible strap, an inflatable bladder and a fastener system to secure the abdominal cuff in position for use on a patient; an inflatable chest cuff adapted to extend over a patient's chest and including an elongated flexible strap, an inflatable bladder and a fastener system to secure the chest cuff in position for use on a patient; a patient platform or backboard configured for disposition against the patient's back during use; and a cuff prepositioning system configured to secure the chest and abdomen compression cuffs to the patient platform in a ready position and to facilitate rapid deployment of the cuffs for use on the patient.

Abstract: A cardio pulmonary CPR device and method that provides enhanced circulation by an optimal combination and sequencing of maximal positive and maximal negative intrathoracic pressures, while maintaining a degree of passive ventilation to the patient. Namely, the embodiments of the invention provide for an optimal positive thoracic pressure compression state, with passively or actively filled lungs, achieved by either passive chest recoil with an open airway, or an active inflation mechanism. Said embodiments also provide for an optimal negative pressure decompression state, combined with actively emptied lungs (by chest compression).

Abstract: The compression measurement and feedback system measures the magnitude and the angle of manual CPR force applied to a patient and provides the measured magnitude and direction information as compression data feedback to the person applying CPR to the patient. Any variation in the magnitude or direction of the compression force applied may be calculated from the compression data measured by the compression sensor. A monitor receives the compression data and processes the compression data to generate feedback data to the CPR provider indicating the magnitude and direction of the applied CPR compression along with ideal CPR compression characteristics for comparison.

Abstract: A manual CPR apparatus for increasing the flow of blood in a patient suffering cardiac arrest. A force multiplier mounts to a base contoured to seat near a central region of the patient's chest. The force multiplier connects to a manual actuator and belt connectors which, in turn, connect to opposite ends of a substantially inelastic belt wrapped around the patient's chest. The force multiplier doubles the force manually applied to the actuator and directs it through the base toward the chest. The force multiplier includes two assemblies. The first has a pair of arms rigidly connected in the same plane to a trolley assembly and two grippable handles extending perpendicularly from either side of the trolley assembly. The second assembly has a pair of vertical struts that attach to opposite sides of the base on either side of the pair of arms of the first assembly.

Abstract: Disclosed is a device, method and computer readable media for determining the adequacy of Cardiopulmonary Resuscitation (CPR). The device comprises an electrical source generator, an electrical signal sensor receiving a signal from the electrical source generator and a microprocessor. The microprocessor determines changes in impedance of the patient based on the signal received from the electrical signal sensor. Software executing on the microprocessor determines at least one of intrathoracic volume, change in intrathoracic volume, rate of compression, depth of compression, respiratory volume, and respiratory rate based on the change of impedance of the patient and outputs a signal indicating the adequacy of ventilation and compressions.

Abstract: Cardiopulmonary resuscitation being provided to a subject is monitored. An enhanced measurement of the effectiveness of the cardiopulmonary resuscitation received by the subject is determined by correlating chest compressions with changes in movement and/or composition of gas at or near the airway of the subject. For example, one or more therapy parameters may be measured with an enhanced accuracy and/or precision, and/or one or more therapy parameters not monitored in conventional cardiopulmonary resuscitation monitoring systems may be measured.

Abstract: Methods to control the delivery of CPR to a patient through a mechanical CPR device are described. The method generally allows for a gradual increase in the frequency of CPR cycles. The gradual increase can be regulated by protocols programmed within the CPR device such as intermittently starting and stopping the delivery of CPR, accelerating the delivery of CPR, stepping up the CPR frequency, increasing the force of CPR, and adjusting the ratio of compression and decompression in a CPR cycle. Combinations of each of these forms may also be used to control the delivery of CPR. This manner of gradually accelerating artificial blood flow during the first minutes of mechanical CPR delivery can serve to lessen the potential for ischemia/reperfusion injury in the patient who receives mechanical CPR treatment.

Abstract: Systems and methods for applying enhanced guided active compression decompression cardiopulmonary resuscitation are provided. Exemplary systems include a load cell, a handle, an adhesive pad. The handle and the adhesive pad are configured for magnetic coupling.

Abstract: A method is provided for resuscitating a patient from cardiac arrest. This may be done by (a) performing chest compressions for a first period of time at a depth of between about 1.5 to about 3 inches, and (b) ceasing chest compressions for a second period of time. Steps (a) and (b) may be repeated at least two times in order to prevent reperfusion injury after cardiac arrest.

Abstract: A method for monitoring chest compressions using a compression member includes measuring a force exerted by the compression member, measuring a displacement of the compression member, providing a chest stiffness function representing the relationship between force and displacement based on values derived from the measured force and the measured displacement, and analyzing linearity of the chest stiffness function. Embodiments of the invention also include devices for performing the method.

Abstract: A method and a device (1) for controlled cardio pulmonary resuscitation is presented with the submitted invention, which is capable of performing a quick and uncomplicated reanimation of a human body in case of cardiac arrest. The geometric dimensions of the inventive device 1 are between about 10 and 20 cm in diameter and about 6 to 12 cm in height. A mechanical pressure (K) is exerted on the pressure transfer agent (2) in an application, wherein the pressure generates a signal (S3, S3?) perceivable with human organs upon reaching of a maximum force exertion (Kmax).

Abstract: A method of controlling the amount of compressed gas used for driving a reciprocating apparatus for cardio-pulmonary resuscitation (CPR) comprising a valve means for controlling the provision of driving gas comprises operation of the valve means during the compression phase to stop provision of driving gas, which operation is separated in time from the venting of the driving gas from the apparatus at the end of the compression phase. Also disclosed are; a CPR apparatus operated by the method; a method of compression depth sensing.

Abstract: A rechargeable power cell having no voltage across its positive and negative power terminals unless the power cell is inserted into a device configured to accept the power cell is described. The power cell includes a battery management processor and battery insertion detection circuitry that cooperate to determine when the power cell is inserted into the device and then drive an electronic switch to provide for conduction of current from the power cell to the positive terminal of the cell.

Abstract: A resuscitation device for automatic compression of a victim's chest using a compression belt operably attached to a platform upon which a patient rests. In use, the compression belt is wrapped around the patient and at least one spindle operably attached to the platform.

Abstract: A cardiopulmonary resuscitation device that combines ventilation of a patient's lungs with chest compressions on the patient's sternum area. The device includes a self-inflating bag having a flat top side as a proper position on the self-inflating bag for applying force to the top side of the self-inflating bag, a flat bottom side on the self-inflating bag for properly positioning the bag on the patient's sternum area, an outlet port through which the content of the bag is forced when the flat top side of the bag is pushed toward the flat bottom side of the bag, a connector connecting the bag with a tube extending from the outlet port, a headband face mask for placement over the patient's mouth and nose, and a second connector positioned between the tube and the face mask.

Abstract: A patient resuscitation/respiratory system includes a system control unit with a timer module controlling a plurality of air pressure modules. In an exemplary embodiment, the air pressure modules include a first air pressure module for controlling a first flow of pressurized gas from a first pressurized gas supply to an inflatable abdominal cuff, a second air pressure module for controlling a second flow of pressurized gas from the first gas supply to an inflatable chest cuff, and a third air pressure module for controlling a third flow of pressurized gas from the first gas supply to an inflatable leg cuff. The control unit in this embodiment includes a ventilator supply module for controlling a flow of breathable gas from a second pressurized gas supply to a patient ventilator module to periodically connect the patient ventilator module and the patient's lungs to the breathable gas supply.

Abstract: The present invention concerns a pad device for the transfer of force to an anterior chest wall during cardiopulmonary resuscitation (CPR), comprising at least two pads elements adapted to be positioned on an anterior chest wall surface, a hinge mechanism connecting the at least two pad elements, the at least two pad elements being movably mounted to the hinge mechanism, such that the hinge mechanism cooperatively responds to a force applied when the patient is receiving a CPR.

Abstract: An apparatus for reanimation of a patient that includes a plunger driven by a drive to perform a compressive massage on the patient's body, a position measuring device that measures the respective position of the plunger during its compressive massaging motion, and a holding device for the drive and the plunger.

Abstract: Time after time studies find that often, even when administered by trained professionals, cardiopulmonary resuscitation (CPR) compression rates and depth are inadequate. Too week, shallow or too forceful compressions may contribute to suboptimal patient outcome. Several parameters are crucial for optimal and properly-administered CPR. Crucial parameters include proper hand positioning on the patient's chest, depth of compression of 4-5 cm, and compression rate of 100 compressions per minute. The crucial parameters are often affected by patient parameters, and relative to the patient, rescuer parameters, such as patient thoracic volume; weight; age; gender; and rescuer's, relative to the patient's, parameters, such as weight, height; physical form, etc. Proposed is an automated CPR feedback device with user programmable settings for assisting with real-time feedback and subsequently correcting rescuers patient customized CPR technique.

Abstract: An embodiment of the support structure includes a back plate, a central part adapted to recite an automatic compression/decompression unit, and a front part. The front part includes two legs coupled between the central part and the back plate. The support structure is arranged to automatically compress or decompress a patient's chest when the front part is attached to the back plate and when the compression/decompression unit is received in the central part.

Abstract: A method for increasing blood flow to vital organs during cardiopulmonary resuscitation of a person experiencing a cardiac arrest may include performing standard or active compression decompression cardiopulmonary resuscitation on a person to create artificial circulation by repetitively compressing the person's chest such that the person's chest is subject to a compression phase and a relaxation or decompression phase. The method may also include administering one or more vasodilator drugs to the person to improve the artificial circulation created by the cardiopulmonary resuscitation. The method may also include binding at least a portion of the person's abdomen, either manually or with an abdominal compression device. Performing cardiopulmonary resuscitation on a person may include ventilating the person with either an impedance threshold device or a intrathoracic pressure regulator.

Abstract: A chest compressions monitor for measuring the depth of chest compressions achieved during CPR. A displacement detector produces a displacement indicative signal indicative of the displacement of the CPR recipient's chest toward the recipient's spine. A signaling mechanism provides chest compression indication signals directing a chest compression force being applied to the chest and a frequency of such compressions.

Abstract: A resuscitation device for automatic compression of victim's chest using a compression belt which exerts force evenly over the entire thoracic cavity. The belt is constricted and relaxed through a motorized spool assembly which repeatedly tightens the belt and relaxes the belt to provide repeated and rapid chest compression. An assembly includes various resuscitation devices including chest compression devices, defibrillation devices, and airway management devices, along with communications devices and senses with initiate communications with emergency medical personnel automatically upon use of the device.

Abstract: A HFCWO system includes an air pulse generator having a blower inlet in communication with a blower and an air port in communication with an inflatable garment. The air pulse generator includes a housing and an air pulse assembly coupled to the housing. The air pulse assembly has at least one diaphragm, at least one driver operable to move the at least one diaphragm and at least one spring arranged to bias the at least one diaphragm away from a portion of the housing.

Abstract: A method of automatically determining which type of treatment is most appropriate for a cardiac arrest victim, the method comprising transforming one or more time domain electrocardiogram (ECG) signals into a frequency domain representation comprising a plurality of discrete frequency bands, combining the discrete frequency bands into a plurality of analysis bands, wherein there are fewer analysis bands than discrete frequency bands, determining the content of the analysis bands, and determining the type of treatment based on the content of the analysis bands.

Abstract: A chest compression monitor for measuring the depth of chest compressions achieved during CPR. A displacement detector produces a displacement signal indicative of the displacement of the CPR recipient's chest toward the recipient's spine. A signaling mechanism provides chest compression indication signals prompting a CPR provider to provide a chest compression force at a desired depth and rate. The device is held to the dorsal surface of the hand during use and provides a display for feedback, which is readily visible to the CPR provider.

Abstract: Devices and methods for attaching a belt cartridge to a belt drive platform. A clip attached to the belt is inserted into a slot in the drive spool of the belt drive platform. The cover plate of the belt cartridge fits into a channel beam in the housing of the belt drive platform, thereby securing the cartridge to the housing. Belt guards, for protecting the cartridge, belt drive platform, patient and rescuer, are rotatably attached to the cover plate and are secured around spindles disposed on the sides of the housing.

Abstract: Embodiments of the present concept are directed to medical devices. For example, a medical device including a display for providing feedback to a rescuer who is performing Cardio Pulmonary Resuscitation (CPR) chest compressions to a patient. The display is structured to graphically indicate an instantaneous value of a measured compression depth of the chest of the patient. The display includes an indicator range that corresponds at least in part to a compression depth range of some of the measured compression depths. An indicator is represented as progressing along the indicator range as the depth changes within the compression depth range to represent a value of the measured compression depth in relation to the indicator range. Depending on the measured compression depth, the indicator progresses at a variable rate relative to a difference in the measured compression depth.

Abstract: A system for performing chest compression for Cardiopulmonary Resuscitation. The system includes a motor, drive spool and associated couplings which allow for controlling and limiting the movement of the compressing mechanism and includes a control system for controlling the operation and interaction of the various components to provide for optimal automatic operation of the system.

Abstract: In one embodiment, an external second medical device is capable of being attached to a patient. The second medical device includes an operation module that is capable of operating at different capacities, such as at a first capacity and a second capacity. The second medical device also includes a receiver for receiving a warning about an impending administration of a first treatment to the patient, by a first medical device that does not know about the second medical device being attached to the patient. In response to receiving the warning, the second medical device undertakes a defensive action, whereby the operation of the operation module is capable of being performed at the second capacity. This way, the first treatment, when administered, will impact the second medical device less or not at all.

Abstract: In one embodiment, an external first medical device includes a treatment module for administering a first treatment. The first medical device also includes a warning module for transmitting, before the first treatment is administered, a warning about the impending administration of the first treatment. The warning is suitable for receipt by a second medical device that could be attached to the patient unbeknownst to the first device, and which could be impacted by the first treatment. As such, the second medical device is given the opportunity to take a defensive action.

Abstract: An automatic external defibrillator including: a sensor for detecting when a rescuer is delivering a CPR chest compression to the patient; electrodes for application to the thorax of the patient for delivering a defibrillation shock to the patient and for detecting an ECG signal; defibrillation circuitry for delivering a defibrillation shock to the electrodes; and a processor and associated memory for executing software that controls operation of the defibrillator. The software provides: ECG analysis for analyzing the ECG signal to determine if the cardiac rhythm is shockable; CPR detection for analyzing the output of the sensor to determine when a CPR chest compression has been delivered, and integration of the ECG analysis and CPR detection so that the determination of whether the cardiac rhythm is shockable is based only on time periods of the ECG signal during which there has not been a CPR chest compression delivered.

Abstract: A CPR device for aiding a user in the performance of chest compressions, which is adapted to be placed on the chest of a patient and has means for measuring the compression force applied. The device has an electrically conductive means (5, 6) forming a first part of a capacitor, wherein a second part of said capacitor comprises an electrically conductive material (11) in a tape (15) adapted to be placed between the device and the patient, said tape (15) also having a compressible layer (10) between the electrically conductive material (11) and the device, and a capacitance measuring means (20) for measuring changes in the capacitance of the capacitor when the compressible layer (10) is compressed during chest compressions.

Abstract: A wearable cardiopulmonary resuscitation assist device or system including: a wearable article to be worn by a cardiopulmonary resuscitation performer or a patient, for assisting administration of cardiopulmonary resuscitation by the performer; at least one sensor for measuring at least one parameter to assist in cardiopulmonary resuscitation; at least one feedback component for conveying feedback information based on the parameter to the performer for assisting the performer in performing cardiopulmonary resuscitation; and a processing unit, the processing unit being configured to receive the at least one parameter from the at least one sensor and to send information based on the parameter to the at least one feedback component. Also a method for training or improving cardiopulmonary resuscitation procedures using the device.

Abstract: Embodiments of the present concept are directed to medical devices for use by a rescuer who is caring for a patient and includes a bottom device for use with a top device to measure the depth of Cardio Pulmonary Resuscitation (CPR) chest compressions delivered to the chest of a patient. The top device is intended for placement on the chest of the patient and has a top mechanism that is moveable up and down as the chest compressions are delivered to the patient. The bottom device includes a generally elongate member having a handle at one end and a bottom mechanism near the opposite end. The elongate member is structured to be placed under the patient during delivery of CPR. The top mechanism and the bottom mechanism cooperate to generate a value for a net depth of the compressions of the patient chest with reference to each other.

Abstract: A chest compressions monitor for measuring the depth of chest compressions achieved during CPR. A displacement detector produces a displacement indicative signal indicative of the displacement of the CPR recipient's chest toward the recipient's spine. A signaling mechanism provides chest compression indication signals directing a chest compression force being applied to the chest and a frequency of such compressions.

Abstract: A resuscitation device for automatic compression of victim's chest using a compression belt which exerts force evenly over the entire thoracic cavity. The belt is constricted and relaxed through a motorized spool assembly which repeatedly tightens the belt and relaxes the belt to provide repeated and rapid chest compression. An assembly includes various resuscitation devices including chest compression devices, defibrillation devices, and airway management devices, along with communications devices and senses with initiate communications with emergency medical personnel automatically upon use of the device.

Abstract: A backboard for an automated cardio pulmonary resuscitation system, said backboard comprising a board element, the board element defining a plane and having a top edge, a bottom edge a first side edge and a second side edge; a set of connectors adapted for connection of the backboard to an automated cardio pulmonary resuscitation unit, said connectors being provided at said side edges; and at least one set of stabilizing elements extending away from an edge and transversely to said plane.

Abstract: Devices and methods for attaching a belt cartridge to a belt drive platform. A clip attached to the belt is inserted into a slot in the drive spool of the belt drive platform. The cover plate of the belt cartridge fits into a channel beam in the housing of the belt drive platform, thereby securing the cartridge to the housing. Belt guards, for protecting the cartridge, belt drive platform, patient and rescuer, are rotatably attached to the cover plate and are secured around spindles disposed on the sides of the housing.

Abstract: Apparatus for automatic delivery of chest compressions and ventilation to a patient, the apparatus including: a chest compressing device configured to deliver compression phases during which pressure is applied to compress the chest and decompression phases during which approximately zero pressure is applied to the chest a ventilator configured to deliver positive, negative, or approximately zero pressure to the airway; control circuitry and processor, wherein the circuitry and processor are configured to cause the chest compressing device to repeatedly deliver a set containing a plurality of systolic flow cycles, each systolic flow cycle comprising a systolic decompression phase and a systolic compression phase, and at least one diastolic flow cycle interspersed between sets of systolic flow cycles, each diastolic flow cycle comprising a diastolic decompression phase and a diastolic compression phase, wherein the diastolic decompression phase is substantially longer than the systolic decompression phase.

Abstract: A cardiac resuscitation device that includes a pulse sensor configured to detect pulse information characterizing the cardiac pulse in the patient, an accelerometer configured to detect chest movements of the patient during chest compressions, and memory and processing circuits configured to process the outputs of the pulse sensor and accelerometer to monitor the effect that chest compressions have on the patient's pulse.