An herb vaporizing apparatus includes an herb receiving port, a grinder to grind the herb, and a heating chamber for heating the ground herb to create a vapor. A first end of the heating chamber is positioned closer to a top of the apparatus than a second end of the heating chamber, such that the ground herb generally moves in at least a partially downward direction as it travels through the heating chamber. The apparatus further includes a screw feeder positioned within the heating chamber that rotates and moves the ground herb within the heating chamber. The apparatus further includes an air pump for pumping vapor out of the heating chamber and a valve positioned along an airway between the heating chamber and a vapor output. The valve permits air and the vapor to move from the heating chamber to the vapor output only while the air pump is activated.

The present disclosure is directed to systems and methods of providing a mixed-gas inhalant to a patient via a gas recirculation loop. The gas recirculation loop receives a first mixed-gas exhalant having a first carbon dioxide concentration from the patient, one or more carbon dioxide removal devices discharge a second mixed-gas exhalant having a second carbon dioxide concentration that is less than the first carbon dioxide concentration. The second mixed-gas exhalant is combined with a mixed-gas supply to provide a mixed-gas inhalant. The mied-gas supply includes a first gas and a second gas. The mixed-gas supply is pressure and flow controlled to produce a mixed-gas inhalant having a defined composition delivered to the patient at a defined volumetric flow rate. The first gas may include a gas containing oxygen and the second gas may include a gas mixture containing a noble or inert gas and oxygen.

Systems and methods are provided for delivering anesthetic agent to a patient. In one embodiment, an anesthetic vaporizer includes a housing defining a sump, the sump configured to hold a self-contained supply of liquid anesthetic agent, a heating element electrically coupled to an electrical mating component, a gas inlet passage and a gas outlet passage, a manifold fluidically coupled to the gas inlet passage and the gas outlet passage, the manifold coupled to the housing and forming a gas-tight seal with the sump, and a quick disconnect pneumatic system coupled to the gas inlet passage and the gas outlet passage, sealing the gas inlet passage and the gas outlet passage from atmosphere.

A ventilation system for ventilation of a patient includes a patient interface device for attaching to the patient and a measuring and analysis device for measuring and analyzing breathing of the patient. The measuring and analysis device includes a connector housing defining a passage. A first portion of the connector housing is connected to the patient interface device. The measuring and analysis device further includes an air flow sensor and a pressure sensor disposed in the connector housing for measuring an air flow rate through the connector housing and a pressure in the connector housing respectively. The present device also includes a processor configured for data acquisition, data storage, data processing, and data output based on the air flow rate and the pressure, whereby the ventilation system is operable with real-time feedback based on the data output. A method for administering cardiopulmonary resuscitation is also provided.

There is provided a ventilator to ventilate an airway of a patient. The ventilator has a conduit having an inlet and an outlet, said outlet configured to be connected to said airway; a gas delivery element in fluid communication with said inlet, said gas delivery element configured to deliver air in a sequence of ventilation cycles, each ventilation cycle defined by a corresponding tidal volume to be delivered to said airway via said conduit, each tidal volume corresponding to a difference between a start volume and an end volume of said gas delivery element for that ventilation cycle; a pressure sensor monitoring pressure within said conduit; a controller communicatively coupled to said gas delivery element and said pressure sensor, said controller performing reducing said tidal volume between a first ventilation cycle and a successive second ventilation cycle contingent upon said pressure exceeding a pressure threshold in said first ventilation cycle.

Systems for use in assisted respiration can permit insertion of one or more elongated medical instruments into the proximal and/or distal airway of a patient during administration of assisted respiration, which may, in some instances, proceed with a patient awake or only minimally sedated. In some systems, a bite block is coupled with a mask and is movable relative to the mask such that the system is capable of accommodating differing patient anatomies.

Provided is an article for protection configured with at least one perforable, modifiable access point positioned to allow airway management procedures. Also provided is a method for maintaining the sterile environment during airway management procedures by covering a subject in need thereof with the article for protection.

A respiratory device for providing respiratory support to a patient includes an expandable bag and a rigid valve housing portion. The expandable bag includes an air intake valve, an adjustable predetermined tidal volume and a hinge configured to maintain the expandable bag in a predetermined tidal volume in an uncompressed configuration. The rigid valve housing portion in fluid communication with the expandable bag, the valve housing portion includes a peak inspiratory pressure (PIP) mechanism, an adjustable dial configured to adjust both the tidal volume of the expandable bag and a value of the PIP mechanism, a two-way valve configured to allow air to move from the expandable bag in a first direction through a first portion and directs air in an opposing direction through a second portion to create positive end-expiratory pressure (PEEP), and a PEEP controller comprising a PEEP dial configured to select a predetermined PEEP value provided by the two-way valve. The valve housing portion is capable of connecting to a patient breathing interface.

A patient airway dome including an adjustable frame having a hinge such that the hinge allows the frame to adjust between an erected position to create an airway dome and a collapsed position that allows the frame to lay flat, a dome covering located over the retractable frame, a suction port which is connected to a conventional device in order to provide negative pressure to patient airway dome, and an arm access assembly operatively connected to the dome covering, wherein the arm access assembly includes an opening in the dome covering and a closure assembly located adjacent to the opening.

Respiratory diseases affect a large part of world population, especially in developing world. In this invention, we present a breathing support system to provide life-saving support to such patients. The system automates and regulates the use of a bag valve mask (commonly known as an ambu bag). The system uses mechanical actuators, sensors and a smart feedback control mechanism to automate and regulate the operation of the ambu bag to implement core functions of mechanical ventilation for life-saving applications. The system can also be used to provide better breathing support to newborns (e.g. to prevent hypoxia). The system can be used to save hundreds of thousands of lives in the developing world, in emergencies and during transportation globally.