A method of determining a duration of safe apnoea. Information is obtained relating to a respiratory indicator, and a duration of safe apnoea is determined from the obtained information. A respiratory therapy system has one or more patient interfaces. A processor is configured to determine a duration of safe apnoea based on obtained information relating to a respiratory indicator.

A system for calculating cardiac output (CO) of a patient undergoing veno-arterial extracorporeal oxygenation includes measuring first oxygenated blood flow rate by a pump in the extracorporeal blood oxygenation circuit as introduced into an arterial portion of the patient circulation system and a corresponding arterial oxygen saturation, then changing the pump flow rate, such as decreasing, to produce a corresponding change in arterial oxygen saturation (wherein such change is outside of normal operating variances, operating errors or drift), which change in the arterial oxygen saturation is measured. From the first flow rate and the second flow rate along with the corresponding measured arterial oxygen saturation, the CO of the patient can be calculated, without reliance upon a measure of venous oxygen saturation. Alternatively, the CO of the patient can be calculated, without reliance upon a change in flow rate by changing a gas exchange with the blood in the extracorporeal blood oxygenation circuit to impart corresponding changes in a blood parameter in the arterial portion of the patient circulation system and the blood delivered from the extracorporeal blood oxygenation circuit.

A breath analyzer for detecting breathing events of a person ventilated with a respiratory gas, comprising an electronic computing and storage unit configured to receive a signal corresponding to a ventilation pressure and/or a respiratory flow and/or a tidal volume of the respiratory gas delivered to the person and, during a predetermined analysis duration, to detect a curve of the signal by a curve analyzer. A ventilator for ventilating a person with a respiratory gas, which ventilator comprises the breath analyzer and a method for detecting breathing events of a person ventilated with a respiratory gas is also described.

A system and method to configure a rule set used in connection with a medical monitoring system for monitoring patients and patient care equipment, especially medication delivery pumps, based on a variety of conditions and parameters associated with monitored biometric information and equipment information and for providing user-defined responses to those conditions and parameters.

A method of estimating a parameter indicative of respiratory flow of a patient being administered flow therapy, comprising: optionally administering a gas at a flow rate to the patient using a flow therapy apparatus with a patient interface, determining a terminal pressure in, at or proximate the outlet of the patient interface or in, at or proximate the nares of the patient, determining nasal RTF, determining a nasal flow parameter being or indicative of nasal flow based on the pressure and a nasal RTF, and optionally outputting the nasal flow parameter or parameter derived therefrom.

A ventilator system configured to switch between one or more invasive ventilation modes and one or more non-invasive ventilation modes is provided, the ventilator system comprising: an externally pressurized source of pre-mixed gas comprising air and oxygen; one or more inspiratory valves configured to deliver incoming pre-mixed gas to a patients breathing circuit; and one or more expiratory valves configured to remove outgoing gas from the patients breathing circuit; wherein in the one or more invasive ventilation modes, the inspiratory valves and the expiratory valves are configured to open and close to allow or prevent the passage of gas as needed in order to enforce a respiration cycle within the patient; and wherein in the one or more non-invasive ventilation modes, the inspiratory valves and the expiratory valves are kept open in order to allow the gas to pass freely through the system.

A ventilation management system stores an initial configuration profile including a set of operating parameters for operating one or more respective ventilation devices. The system receives first ventilator data from a first ventilation device at a first location, and second ventilator data from a second ventilation device at a second location, the first and second ventilation devices being configured to operate based on the initial configuration profile, wherein the received first ventilator data comprises one or more current operating parameters of the first ventilation device, or physiological data obtained from a patient associated with the first ventilation device. The system modifies the initial configuration profile for use by the first ventilation device based on the received first ventilation data and provides the modified configuration profile to the first ventilation device. The modified configuration profile is implemented by the first ventilation device when approved by a clinician or the patient.

A processor obtains input of a logistically attainable end tidal partial pressure of gas X (PetX[i].sup.T) for one or more respective breaths [i] and input of a prospective computation of an amount of gas X required to be inspired by the subject in an inspired gas to target the PetX[i].sup.T for a respective breath [i] using inputs required to utilize a mass balance relationship, wherein one or more values required to control the amount of gas X in a volume of gas delivered to the subject is output from an expression of the mass balance relationship. The mass balance relationship is expressed in a form which takes into account (prospectively), for a respective breath [i], the amount of gas X in the capillaries surrounding the alveoli and the amount of gas X in the alveoli, optionally based on a model of the lung which accounts for those sub-volumes of gas in the lung which substantially affect the alveolar gas X concentration affecting mass transfer.

A processor obtains input of a logistically attainable end tidal partial pressure of gas X (PetX[i].sup.T) for one or more respective breaths [i] and input of a prospective computation of an amount of gas X required to be inspired by the subject in an inspired gas to target the PetX[i].sup.T for a respective breath [i] using inputs required to utilize a mass balance relationship, wherein one or more values required to control the amount of gas X in a volume of gas delivered to the subject is output from an expression of the mass balance relationship. The mass balance relationship is expressed in a form which takes into account (prospectively), for a respective breath [i], the amount of gas X in the capillaries surrounding the alveoli and the amount of gas X in the alveoli, optionally based on a model of the lung which accounts for those sub-volumes of gas in the lung which substantially affect the alveolar gas X concentration affecting mass transfer.

A control system controlling blood gas values in blood processed by an oxygenator, wherein the oxygenator generates arterial blood by exposing venous blood to oxygen from an oxygenation gas supply, comprises a monitoring arrangement to determine a level of the blood gas values in the arterial blood and a controller that is responsive to the monitoring arrangement and configured to control parameters of the oxygenation gas supply to the oxygenator. This allows the blood gas values to be adjusted toward a pre-determined level.