A ventilator system is presented. The ventilator system includes a controller configured to generate a first control signal for a first time-period and a second control signal for a second time-period during an inspiration time. Also, the ventilator system includes a rotary pump configured to change one of a pressure and a flow rate of the drive gas to a first value if the first control signal is received and change the one of the pressure and the flow rate of the drive gas to a second value if the second control signal is received. Further, the rotary pump is configured to deliver the drive gas to cause supply of a medical gas during the inspiration time, wherein the medical gas is supplied based on the one of the pressure and the flow rate of the drive gas delivered from the rotary pump.

A medical measuring device (2), as well as to a ventilator (1), as well as to a method for operating a medical measuring device (2) or a ventilator are provided. The medical measuring device (1) includes a sensor system (14) and measuring, signal processing and calculating device (21), to detect an inspiratory measured variable, which represents an indicator for the transport of breathing gases into the lungs of a patient (80), and an expiratory measured variable, which represents an indicator for the transport of breathing gases out of the lungs of a patient (80), and to determine an indicator for a ventilation-related shifting of secretion from the expiratory measured variable and the inspiratory measured variable.

A CPAP device includes a flow generator including an outlet, a humidifier including an inlet, and an adaptor connector between the outlet of the flow generator and the inlet of the humidifier. The connector includes a flexible and conformable sealing portion that is movable to accommodate misalignment.

A patient interface for delivering breathable gas to a patient includes a sealing portion including a nose tip engagement portion adapted to form a seal with the patient's nose tip, an upper lip engagement portion adapted to form a seal with the patient's upper lip and/or base of the patient's nares, and nostril engagement flaps adapted to form a seal with the patient's nares. The nose tip engagement portion, the upper lip engagement portion, and the nostril engagement flaps are all structured to extend or curve outwardly from a supporting wall defining an air path.

A novel method and device for the destruction of nitrous oxide in gases such as those resulting from exhaled breath during dental, medical, and veterinary procedures are described. The method employs processing steps including the collection of gases containing constituents such as water vapor, carbon dioxide, oxygen, nitrogen, and nitrous oxide from exhaled breath or from ambient room air, optional removal of moisture from the collected gas, catalytic decomposition of nitrous oxide gas to nitrogen and oxygen, heat exchange to reduce high temperatures in gases exiting the reactor, and sorbents to remove traces of reaction byproducts. Instrumentation and controls are employed to monitor and regulate temperatures, pressures, gas compositions, and flow rates while also providing measures to automatically shut down in the event of off-nominal conditions. The method and device are capable of operating with variable anesthetic or patient exhaled breath flow rates while inducing no significant pressure or vacuum on the patient as they exhale. The method is carried out in a compact device suitable for operation in dental offices, hospitals, and other locations where nitrous oxide is administered as an anesthetic.

The invention concerns a gas delivery device (1) comprising an inner gas passage (100) in fluid communication with a deformable reservoir (27), and a processing unit (51), such as an electronic board with a microcontroller. It further comprises a first differential pressure sensor (281) cooperating with the processing unit (51) for determining a pressure (P) in the deformable reservoir (27), and a proportional valve (22) arranged on the inner gas passage (100) for controlling the flowrate of gas in said inner gas passage (100). The processing unit (51) controls the proportional valve (22) for adjusting the flowrate of gas passing through said proportional valve (22) on the basis of said pressure (P) in the deformable reservoir (27). The gas can be a mixture of oxygen and nitrous oxide useable for relieving anxiety, for providing light sedations or for treating pain.

An exercise with oxygen therapy (EWOT) apparatus for rejuvenating oxygen-depleted cell tissue and simulating high altitude oxygen conditions. The EWOT apparatus includes a first cylindrical bladder for providing oxygen-enriched air and a second bladder for providing lower-purity hypoxic air. The first bladder is retained within an open, lightweight rectangular-shaped frame having vertical frame members. An air supply source provides the oxygen-enriched and hypoxic air to the first and second bladders, respectively. A control switch, which can be manually and/or programmed to automatically operate, selectively delivers the oxygen-enriched and/or hypoxic air to a breathing mask worn by a user while exercising on exercise equipment. The first bladder includes a plurality of weights which provide a positive pressure to the air therein. The cylindrical first bladder is attached to the vertical frame members with slidable rings and expands and collapses in a vertical direction when being filled or during use, respectively.

An embodiment in accordance with the present invention provides a monitor for use with a bag valve mask (BVM). In some embodiments, the monitor can take the form of an inline electronic spirometer using a bi-directional digital turbine for the BVM with volume, pressure, and respiratory rate alarms and active real time monitoring in order to prevent volutrauma/barotrauma and hypoxia. Alternatively, an out of line electronic spirometer using a variable orifice or fixed orifice flowmeter (pitot tube) and two tubes connected to a portable device can be used. The monitor can come with a BVM or can be a separate device configured for coupling to an existing BVM.

A breathing assistance apparatus includes an inner volumetric member pressurizable from a first pressure to a second pressure and an outer volumetric member surrounding at least a portion of the inner expandable volumetric member. The inner volumetric member pressurizes the outer volumetric member as the inner volumetric member is pressurized from the first pressure to the second pressure. In another embodiment, a breathing assistance apparatus includes exhalation and inhalation chambers with respective biasing members providing for the exhalation chamber to apply a pressure to the inhalation chamber and thereby provide assisted inhalation. Methods for assisting breathing are also provided.

The present disclosure pertains to a system and method for facilitating pressure support therapy, mechanical inexsufflation therapy, and suctioning therapy for a subject. The system and method described herein offer a novel combination of mechanical inexsufflation with suctioning from a vacuum system. The invasive nature of current closed suctioning systems poses many potential risks, such as tissue trauma, less optimum secretion clearance at the peripheral airway, and lung decruitment. The system and method described herein provide a non-invasive method of suctioning with a suctioning volume measurement and a monitoring alarm to ensure a baseline lung volume and a positive end expiratory pressure (PEEP) level are maintained. This non-invasive method of suctioning is provided together with mechanical inexsufflation and pressure support therapy.