A system and method for monitoring a subject receiving supplemental oxygen and controlling supplemental oxygen delivery thereto, which includes utilizing one or more sensors to monitor physiologic parameters of the subject, analyzing the monitored physiologic parameters, and subject specific data and/or population data, to determine whether modification of treatment parameters, and/or attention of a caregiver, is required, and automatically modifying one or more of the treatment parameters or alerting the caregiver and/or subject, such that the treatment parameters of the subject may be modified to optimize the supplemental oxygen treatment. The method and system provided herein facilitate personalization of oxygen delivery to a subject in a need thereof.

A respiratory ventilators system having an inlet configured to be connected to a pressurized air or gas source; an outlet configured to be connected to a patient interface; a valve in-line between the inlet and the outlet; and a control unit configured to control the valve for controlling flow of pressurized air or gas from the source to the patient, wherein the valve includes an air or gas reservoir or accumulator incorporated into the valve body.

A surgical gas delivery system is disclosed for gas sealed insufflation and recirculation, which includes a gaseous sealing manifold for communicating with a gas sealed access port, an insufflation manifold for communicating with the gas sealed access port and with a valve sealed access port, a compressor for recirculating gas through the gas sealed access port by way of the gaseous sealing manifold, a first outlet line valve associated with the insufflation manifold for controlling a flow of insufflation gas to the gas sealed access port, a second outlet line valve associated with the insufflation manifold for controlling a flow of insufflation gas to the valve sealed access port, and a proportional valve associated the insufflation manifold and located upstream from the first and second outlet line valves for dynamically controlling the flow of insufflation gas to the first and second outlet line valves.

Apparatus and methods for delivering humidified breathing gas to a patient are provided. The apparatus includes a humidification system configured to deliver humidified breathing gas to a patient. The humidification system includes a vapor transfer unit and a base unit. The vapor transfer unit includes a liquid passage, a breathing gas passage, and a vapor transfer device positioned to transfer vapor to the breathing gas passage from the liquid passage. The base unit includes a base unit that releasably engages the vapor transfer unit to enable reuse of the base unit and selective disposal of the vapor transfer unit. The liquid passage is not coupled to the base unit for liquid flow therebetween when the vapor transfer unit is received by the base unit.

A ventilator (100) configured to control a pressure and gas mixture for an air flow. The ventilator include: a gas source (220); a proportional valve (210) configured to control a gas flow rate from the gas source; a mix controller (170) in communication with the proportional valve, the mix controller configured to monitor a flow of gas through the blower, and further configured to control a percentage of oxygen in the output flow; a blower motor (160); and a blower motor controller (162) configured to control a speed of the blower motor using a current feedback loop, a blower speed feedback loop, a flow feedback loop, and a pressure feedback loop. The ventilator can also include, for example, a pseudo-derivative feedback compensator, a complimentary filter, and/or a speed controller.

A medical vaporizer is provided. In one embodiment, dual-purpose sensors are employed, such as in a configuration in which one is positioned in the mixed gas flow channel and one is positioned in the main gas flow channel. The sensors provide measurements that may be used to determine both gas flow and gas concentration in the mixed and main gas channels, even when the identity and/or properties of the gas in the main gas channel are unknown. The measurements derived from the dual-purpose sensors may be used to measure and report the total anesthetic being delivered at the vaporizer output and/or improve vaporizer accuracy.

A device provides respiratory treatment such as for sleep disordered breathing and other respiratory conditions in a discreet configuration to provide a minimally invasive system. The system may include a flow pressurizer apparatus configured to generate a pressurized flow of air through a small bore delivery conduit toward a patient interface. The system may further include a treatment compensator coupled with the fine bore delivery conduit. The treatment compensator may be configured at the patient interface to reduce pressure for patient inspiration. A processor may control adjustments to the pressure generated by the flow pressurizer apparatus.

Discloses are an electronic control circuit for alleviating altitude sickness and an oxygen supply device. The electronic control circuit includes an oxygen sensor installed in an oxygen supply channel, a breathing frequency sensor installed to the front of a head of a human body, and a microcontroller coupled to a control button, a flow proportion electromagnet, a bypass electromagnet and an air pump motor. The oxygen sensor and breathing frequency sensor detect analog signal and transmit the signal to the microcontroller after an analog-to-digital conversion, and an ON/OFF signal of the control button is transmitted to the microcontroller. The microcontroller has a flow control end coupled to a flow proportion electromagnet, a bypass control end coupled to a bypass electromagnet, and a pneumatic control end coupled to an air pump motor, and further includes a vibrating element electrically coupled to the microcontroller.

Exhalation valve including a diaphragm for opening and closing an outlet of an exhalation flow path for guiding exhaled air to the outside air, a back chamber provided opposite the exhalation flow path in the diaphragm and forming a space together with the diaphragm, and a pump unit fixed to the circumference of the back chamber for adjusting the air pressure inside the back chamber by feeding and discharging of air to and from the back chamber. The diaphragm closes the outlet of the exhalation flow path when the air pressure inside the exhalation flow path is lower than the air pressure inside the back chamber, and opens the outlet of the exhalation flow path when the air pressure inside the exhalation flow path is higher than the air pressure inside the back chamber.

A respiratory device for supplying breathing air to a patient, including an oxygen inlet to be connected to an oxygen supply, and a compressed air inlet to be connected to a compressed air supply. The respiratory device also includes a turbine for sucking in ambient air. Switching between the individual operating modes can be done automatically or manually.