Abstract: A manual patient ventilation system includes a breathing bag manually compressed by a clinician to ventilate a patient via a patient interface device, a gas supply system supplying fresh gas to the breathing bag at a fresh gas flow rate, a pressure sensor measuring a patient airway pressure (PAW) throughout a compression and release cycle of the breathing bag by the clinician, a fresh gas controller comprising a processor, and a manual ventilation control module executable on the processor by the fresh gas controller. The manual ventilation control module includes instructions executable to receive the Paw measurements and determine a fresh gas flow rate based thereon. The gas supply system is then controlled to supply the fresh gas flow rate into the breathing circuit.

Abstract: A manual patient ventilation system includes a breathing bag manually compressed by a clinician to ventilate a patient via a patient interface device, a gas supply system supplying a fresh gas to the breathing bag at a fresh gas flow rate, and pressure sensor measuring a Paw throughout a compression and release cycle of the breathing bag by the clinician, a fresh gas controller comprising a processor, and a manual ventilation control module executable on the processor by the fresh gas controller. The manual ventilation control module includes instructions executable to receive the Paw measurements and determine a fresh gas flow rate based thereon. The gas supply system is then controlled to supply the fresh gas flow rate into the breathing circuit.

Abstract: A variable orifice fluid flow sensor is provided that includes a biasing member and a bending member positioned proximate the biasing member. The biasing member includes at least one biasing element extending from the biasing member into contact with a non-flapper portion of the bending member to exert a contact force on the bending member.

Abstract: A variable orifice fluid flow sensor is provided that includes a biasing member and a bending member positioned proximate the biasing member. The biasing member includes at least one biasing element extending from the biasing member into contact with a non-flapper portion of the bending member to exert a contact force on the bending member.

Abstract: A flow sensor for a medical ventilator system is disclosed herein. The flow sensor includes a valve assembly having a valve seat, and a valve flap attached to the valve seat. The valve flap is composed of an elastomeric material configured to generate a pre-load that biases the valve flap into engagement with the valve seat such that the valve assembly remains closed in the absence of an externally applied force. The flow sensor also includes a pressure transducer configure to measure a first pressure level at an upstream position relative to the valve assembly, and a second pressure level at a downstream position relative the valve assembly. The flow sensor also includes a processor configured to estimate the flow rate of a fluid passing through a medical ventilator system based on the first and second pressure levels.

Abstract: An anesthesia machine is disclosed herein in accordance with an embodiment. The anesthesia machine may include a gas mixer, and an anesthesia machine connector pneumatically coupled with the gas mixer. The anesthesia machine connector may be adapted to selectively receive a pneumatic circuit. The anesthesia machine may be operable in a first mode when the pneumatic circuit is decoupled from the anesthesia machine connector. The first mode may comprise the transfer of a gas from the gas mixer to a first destination. The anesthesia machine may be automatically converted to a second mode when the pneumatic circuit is coupled with the anesthesia machine connector. The second mode may comprise the transfer of the gas from the gas mixer to a second destination.

Abstract: A connector device to attach a pneumatic circuit tube to a first and second end fitting of a pneumatic system is provided. The device comprises a first connecting structure that positively attaches to pneumatic circuit tube to the first end fitting of the pneumatic system, and a second connecting structure that positively attaches to the pneumatic circuit tube to the second end fitting of the pneumatic system. A pull arm connects between the first connecting structure to the second connecting structure, and transmits a single application of force on the pull arm to release both the first connecting structure from attachment at the first end fitting and the second connecting structure from attachment at the second end fitting.

Abstract: An anesthesia system is disclosed herein, The anesthesia system may include a pneumatic circuit comprising an inspiratory limb, an expiratory limb, and an endotracheal tube. The endotracheal tube may be configured to form a pneumatic coupling between a patient, the inspiratory limb and the expiratory limb. The anesthesia system may also include an anesthesia machine connected to the pneumatic circuit. The anesthesia machine may include a controller configured to identify the presence of a leak in the pneumatic coupling.

Abstract: An anesthesia system is disclosed herein. The anesthesia system includes a pneumatic circuit comprising an inspiratory limb, an expiratory limb, and a sensor. The anesthesia system also includes an anesthesia machine comprising a controller. The controller is operatively connected to the sensor, and is configured to identify a respiratory phase of the patient based on feedback from the sensor. The controller is further configured to regulate the flow rate of a fresh gas in response to the identified respiratory phase.

Abstract: A flow sensor for a medical ventilator system is disclosed herein. The flow sensor includes a valve assembly having a valve seat, and a valve flap attached to the valve seat. The valve flap is composed of an elastomeric material configured to generate a pre-load that biases the valve flap into engagement with the valve seat such that the valve assembly remains closed in the absence of an externally applied force. The flow sensor also includes a pressure transducer configure to measure a first pressure level at an upstream position relative to the valve assembly, and a second pressure level at a downstream position relative the valve assembly. The flow sensor also includes a processor configured to estimate the flow rate of a fluid passing through a medical ventilator system based on the first and second pressure levels.

Abstract: A ventilator system is disclosed herein. The ventilator system includes a collapsible reservoir assembly comprising an outer reservoir and an inner reservoir disposed at least partially within the outer reservoir. The ventilator system also includes a source of gas pneumatically coupled with the outer reservoir, and a controller operatively connected to the source of gas. The controller is configured to regulate the transmission of gas from the source of gas to the outer reservoir in order to compress the inner reservoir and thereby automatically transfer the contents of the inner reservoir.