A medicine vaporizer apparatus comprises a base with an upwardly extending heating element disposed within a rigid tube. Air is drawn into the rigid tube through an aperture in the rigid tube below the heating element and directed over the heating element to then be drawn through a flexible tube and through a filter or screen comprising an amount of medicine. Heated air flows over the amount of medicine and vaporizes the same, wherein the medicine is thereafter drawn into the lungs of a patient pulling the air therethrough with his or her mouth. Thermal separation and cooling of various parts prevents accidental injury to users and provides an inert air path for the air therethrough. The apparatus further provides controlled incineration and/or vaporization of the medicine.

A hydrotherapy device for treating a wound on a surface of a patient's body is provided. A body of the hydrotherapy device includes a wall having an outer surface, an inner surface, and a chamber defined by the inner surface. The wall further includes an internal void, a first port extending fully through the wall and in communication with the void, a second port extending from the outer surface partially through the wall and in communication with the void, and a plurality of channels, each extending from the void to the inner surface. A central axis of each channel forms an angle at the inner surface.

A method and system for separating a flow of matter is shown and described. The system includes one or more flow separation devices, one or more surgical instruments, and one or more suction sources. In some embodiments, the flow of matter comprises biological material. In some embodiments, the flow of matter comprises surgical waste.

A dry powder delivery device may be configured to provide micronized dry powder particles to airways of a user. The device may include a cylindrical container delimiting a chamber containing at least one magnetically-responsive object, a motor external to said chamber, a magnet external to the chamber and rotatably coupled with the motor, and an outflow member configured to direct airflow to a user. The magnetically-responsive object may be coated with micronized dry powder particles, and the motor may be operable to rotate the magnet about an axis. Rotation of the magnet creates a magnetic field that causes the magnetically-responsive object to move in response to the magnetic field and collide with a side wall of the container to deaggregate the dry powder particles and aerosolize the dry powder in the chamber.

Disclosed are dry powder inhalers for delivering medicament to a user from a blister pack, the blister pack having a plurality of spaced-apart blister pockets containing doses of the medicament. The inhalers comprise: a housing for accommodating unused and used portions of the blister pack together with a dispensing mechanism for selectively opening the blister pockets; and a manifold component through which air can be drawn in use of the inhaler. The manifold component comprises: a primary air inlet opening for receiving first external air; an air outlet opening for providing the external air from the primary air inlet opening into an opened blister pocket, the primary air inlet opening being fluidly connected to the air outlet opening by a primary air delivery conduit formed in the manifold component; a medicament inlet opening for receiving air-entrained medicament from the opened blister pocket, the air outlet opening and the medicament inlet opening being arranged side-by-side to enable simultaneous communication with the opened blister pocket; and a medicament outlet opening for delivery of the air-entrained medicament from the opened blister pocket to the user, the medicament inlet opening being fluidly connected to the medicament outlet opening by a medicament delivery conduit formed in the manifold component. The disclosed inhalers embodiments provide a variety of improvements to the design of the manifold component.

Disclosed is a dry powder inhaler for delivering medicament from at least one blister pack, each blister pack having a plurality of spaced-apart blister pockets containing doses of the medicament. The inhaler comprises: a housing for accommodating unused and used portions of the at least one blister pack together with a dispensing mechanism for simultaneously opening at least two blister pockets at a time; and a manifold component through which air can be drawn in use of the inhaler. The manifold component comprises: first and second air inlet openings for receiving external air a first air outlet opening for providing the external air to a first opened blister pocket and a first medicament inlet opening for receiving air-entrained medicament from the first opened blister pocket, the first air outlet opening and the first medicament inlet opening being arranged side-by-side to enable simultaneous communication with the first opened blister pocket; a second air outlet opening for providing the external air to a second opened blister pocket and a second medicament inlet opening for receiving air-entrained medicament from the second opened blister pocket, the second air outlet opening and the second medicament inlet opening being arranged side-by-side to enable simultaneous communication with the second opened blister pocket; and a medicament outlet opening for delivery of the air-entrained medicament from the first and second opened blister pockets to the user, the first and second medicament inlet openings being fluidly connected to the medicament outlet opening by a medicament delivery conduit formed in the manifold component. The first and second air inlet openings are fluidly connected to the first and second air outlet openings by respective first and second air conduits in the manifold component, wherein the air conduits are separately provided so that the external air from each of the first and second air inlet openings does not mix with the external air from the other of the first and second air inlet openings before reaching the first and second opened blister pockets.

Disclosed herein are aspects of portable vaporizers to deliver aliquots of heated air to material in a furnace. The furnace is multipurposed reducing heat loss, air leakage and delays in availability of air aliquots at the proper temperature for use. By dividing the furnace with an air permeable divider and placing material in the chamber a controller selectively providing electrical power to a heating element configured to heat air furnace. Upon application of suction to the fluid passage heated air passes through a divider which shapes the head of the heated plume before the aliquot of air reaches the material. A controller in signal communications with at least one temperature sensor controls the power flow to a heater to control the temperature produced by heating element(s).

A dispenser for powdery substances contained in a separate package that has a container part with removable container cover, wherein an aspirated air flow is further sucked predominantly through the container part after removal of the container cover from the container part, such that two air flows entering through slits in a lid that can be pivoted around a pivoting axis evacuate the container part from its two ends, and after merging enter a vortex chamber upstream from a mouthpiece. Outside air inlet openings for a third air flow are formed in a housing part covered by the lid in a radial extension to the pivoting axis.

A system may include an external device and an inhaler. The external device may include a processor, a communication circuit, and memory. The inhaler may include a mouthpiece, medicament, a mechanical dose counter, and an electronics module comprising a processor and a communication circuit. The electronics module may record a dosing event when the inhaler is actuated, such as when the mouthpiece cover is opened, and send a signal indicating the dosing event to the external device. The external device may receive a mechanical dose reading of the mechanical dose counter, determine an electronic dose reading based on the signal indicating the dosing event, determine that a discrepancy between the mechanical dose reading and the electronic dose reading exceeds a threshold, and notify the user of the discrepancy, for example, by providing a notification to the user by way of a mobile application residing on the external device.

An inhaler article includes a body extending along a longitudinal axis from a mouthpiece end to a distal end and a capsule cavity defined within the body. A mouthpiece air channel extends from the capsule cavity to the mouthpiece end. An end cap is disposed within the distal end and extends to the capsule cavity. The end cap extends from an end cap distal end to an end cap inner end. The end cap includes an air channel extending from the end cap distal end to the end cap inner end. The air channel is non-parallel with the longitudinal axis.