A system for safely delivering an efficient amount of oxygen to essential organs, during cardiopulmonary resuscitation (CPR) is described; a respective method and an endotracheal device for delivering a semi-spontaneous positive-pressure ventilation are further described; the system comprises; at least one limb compression device, a positive-pressure ventilation system, an endotracheal tube, a cardiac stimulation device, an intra-tracheal pressure sensor, a synchronizer; the method comprises; compressing at least one limb device and occluding a blood flow into the limb, delivering a mixture of gases, providing an endotracheal tube, conferring a deployed configuration, conferring a withheld configuration, performing a cardiac stimulation device, determining a pressure, synchronizing a timing; the endotracheal device comprises; an elongated tube, a sealing cuff assuming a deployed configuration and withheld

A CPR system includes a retention structure to retain the patient's body, and a compression mechanism to perform CPR compressions to the patient's chest. The CPR system further includes a processor to control the compression mechanism, and thus the performance of the CPR compressions. In embodiments, the CPR system compresses at a rate or frequency that is varied based on feedback gathered from physiological sensors that detect physiological characteristics of the patient during treatment.

A method, a system, or an apparatus for resuscitation can include a first sensor having a first output configured to provide a first sensor signal corresponding to optical attenuation of tissue at a site. The method, the system, or the apparatus can include a processor coupled to the first output. The processor can be configured to generate an output signal. The output signal can be determined based on a first parameter of the optical attenuation. The first parameter can correspond to blood circulation associated with externally applied stimulation of a cardiovascular organ. The method, the system, or the apparatus can include a system output coupled to the processor. The system output can be configured to provide a control signal determined using the output signal.

Embodiments of the present invention include a system having at least one sensor configured to monitor a muscle oxygen saturation (SmO2) level of a patient who is undergoing cardiac arrest and to generate a signal representing SmO2 level; a user interface device; a processor communicably coupled to the user interface device, the processor configured to cause the user interface device to present an array of two or more possible nodes of a clinical decision support tree, wherein at least one of the nodes indicates cardiopulmonary resuscitation (CPR) treatment of the patient with no ventilation, and wherein at least another of the nodes indicates CPR treatment of the patient with active ventilation; determine which of the two or more possible nodes should be emphasized based on the SmO2 level; and update the array of the two or more possible nodes based on the determination.

A medical system includes a manual patient ventilation unit defining an airflow path arranged so that when the unit is applied to a patient the airflow path is in fluid communication with the patient's airway. The patient ventilation unit includes a ventilation bag configured to enable manual ventilation of the patient by a rescuer, an airflow sensor in the airflow path positioned to sense the presence of ventilation airflow and measure a gas flow rate in the airflow path, and a pressure sensor in the airflow path positioned to sense gas pressure in the airflow path. The system also includes a processor arranged to receive data generated by the airflow sensor and the pressure sensor and determine one or more ventilation quality parameters based at least in part on a gas flow volume calculated based on the sensed gas flow rate and gas pressures.

Systems and methods related to the field of cardiac resuscitation, and in particular to devices for assisting rescuers in performing cardio-pulmonary resuscitation (CPR).

Systems, apparatuses, and methods directed to the collection and analysis of data related to a patient during an emergency advanced airway management process. The collected data may be obtained using various types of sensors, with the data collection process being managed or coordinated by a suitable system, such as a combination monitor-defibrillator. The monitor-defibrillator (alone or in combination with other system elements, such as a wired or wireless communications capability, a processor, data storage, etc.) may include a capability to process some or all of the acquired data, and in response indicate to a user when some of the collected data may be unreliable.

A medical system includes a manual patient ventilation unit defining an airflow path arranged so that when the unit is applied to a patient the airflow path is in fluid communication with the patient's airway. The patient ventilation unit includes a ventilation bag configured to enable manual ventilation of the patient by a rescuer, an airflow sensor in the airflow path positioned to sense the presence of ventilation airflow and measure a gas flow rate in the airflow path, and a pressure sensor in the airflow path positioned to sense gas pressure in the airflow path. The system also includes a processor arranged to receive data generated by the airflow sensor and the pressure sensor and determine one or more ventilation quality parameters based at least in part on a gas flow volume calculated based on the sensed gas flow rate and gas pressures.

A restraint configured to secure a patient to a mechanical cardiopulmonary resuscitation (CPR) device. The restraint includes a physiological sensor configured to detect a physiological parameter of the patient and to output a signal indicative of a value of the physiological parameter.