A device for minimizing obstruction in a medical device that carries fluids includes a housing defining a channel configured to receive and secure a section of the medical device such that the section of the medical device extends coaxially with a central longitudinal axis of the channel. The device also includes components supported in the housing, including a motor, wherein the components are configured to be operated to impart motion to the housing and the attached medical device. The motion is configured to produce oscillatory motion of a frequency sufficient to concentrate shear stresses in a fluid boundary layer adjacent an inner wall of the medical device. The housing and the components supported in the housing are configured and arranged so that a device center of mass lies along or near the longitudinal axis of the channel.

A tattoo device is provided comprising a housing having a first oscillator which is coupled, in use, to a needle assembly having a sharps end. The first oscillator is arranged and adapted to induce vibrations at a frequency from 1-1000 Hz substantially longitudinally along an axis of the needle assembly in order to cause, in use, the sharps end to penetrate skin. The tattoo device further comprises a second oscillator which is also coupled, in use, to the needle assembly, wherein the second oscillator is arranged and adapted simultaneously to induce vibrations at a higher frequency than the first oscillator and in particular at a frequency from 5-200 kHz in order to lower the insertion force required to penetrate skin layers.

An anesthetic administration device comprising an infusion device, which is in fluid connection with a regional anesthetic needle by means of a feed tube. The infusion device comprises one or more anesthetic flow devices capable of triggering forward flow, and optionally backward flow, of the local anesthetic through the regional anesthetic needle. Forward, and optionally backward flow, of the local anesthetic through the regional anesthetic needle is controlled by a controller that comprises one or more actuator switches. The one or more actuator switches are positioned on the device 1 such that they may be operated by hand.

A respiratory ventilator device is described herein. The respiratory ventilator device includes an inhaled air assembly, an exhaled air assembly, and a control system operatively coupled to the inhaled air assembly and the exhaled air assembly. The inhaled air assembly is coupled to a patient respiratory circuit and configured to channel a volume of inhalation air to the patient's lungs to assist in patient inhalation. The exhaled air assembly is coupled to the patient respiratory circuit and configured to remove air from the patient's lungs to assist in a patient exhalation. The control system is configured to operate the respiratory ventilator system in an inhalation mode and an exhalation mode.

The present invention relates to an electrically operable resuscitation device comprising a piston/cylinder assembly including a rigid cylinder including at least one gas inlet and at least one gas outlet, a piston to travel in said cylinder, and at least one valve, the or each valve configured to allow gas to be displaced into said cylinder through said at least one gas inlet during at least one of a first stroke direction and second stroke direction of said piston in said cylinder, and for allowing gas to displaced through said at least one gas outlet during an opposite of said at least one of the first stroke direction and second stroke direction of said piston in said cylinder; a motor, selected from one of a stepper motor and feedback motor and stepper motor with feedback and linear motor, operatively connected to said piston to move said piston in said cylinder; a patient interface in ducted fluid connection with said piston/cylinder assembly to receive gas via said at least one gas outlet and to deliver said gas to said patient.

A check valve can include a pressure actuator or an electromagnetic actuator. The check valve includes a valve inlet, a valve outlet, and flap disposed between the valve inlet and the valve outlet. The pressure actuator in fluid communication with the valve inlet. The check valve has an open state and a closed state. The check valve is configured to allow an input gas to flow from the valve inlet to the valve outlet when the check valve is in the open state. The check valve is configured to preclude the input gas from flowing from the valve inlet to the valve outlet when the check valve is in the closed state. Upon actuation of the pressure actuator or the electromagnetic actuator, the flap moves away from the valve inlet to allow the inlet gas to move from the valve inlet to the valve outlet.

An aerosol-generating system comprising: an aerosol-generating article (1), the aerosol-generating article comprising a single metered dose of an aerosol-forming substrate; an airflow pathway (108) arranged between an air inlet (110) and an air outlet (112); an aerosolisation chamber (116) arranged at a location along the airflow pathway (108) such that the airflow pathway passes through at least a portion of the aerosolisation chamber (116); and a flow controller (122, 124) for selectively controlling the flow of air through the airflow pathway (108), the flow controller (122, 124) having an open configuration in which air can flow into and out of the aerosolisation chamber (116) and a closed configuration in which air is substantially prevented from flowing into and out of the aerosolisation chamber (116); wherein the aerosolisation chamber (116) is configured to open to receive only one aerosol-generating article (1) at a time; wherein the aerosolisation chamber (116) is configured to close to contain the aerosol-generating article (1); the aerosol-generating system further comprising a heating element (118, 120) arranged to heat the aerosolisation chamber (116) when an aerosol-generating article (1) is received within the aerosolisation chamber (116); wherein the aerosol-generating system is configured to heat the aerosolisation chamber (116) containing the aerosol-generating article (1) only when the flow controller (122, 124) is in the closed configuration.

An aerosol provision system comprising: a substrate comprising aerosol generating medium, the substrate including a first surface and a second surface facing the first surface; a source of energy for heating arranged to face the second surface of the substrate, wherein the source of energy for heating is configured to cause heating of the aerosol generating medium to form an aerosol; and a movement mechanism arranged to enable movement of the aerosol generating medium relative to the source of energy for heating, wherein the aerosol generating medium is rotationally movable relative to the source of energy for heating such that portions of the aerosol generating medium are presented to the source of energy for heating, and wherein the aerosol generating medium is rotated around an axis at an angle to the first surface.

The present disclosure provides a drug discharge assembly including a drive piece linearly reciprocated along one direction, a rotating unit being in contact with an end of the drive piece and rotating in one direction according to a linear reciprocating motion of the drive piece, a flexible tube disposed adjacent to the rotating unit and having a curved section at least partially extending in a circumferential direction, and a pressing unit mounted on the rotating unit and rotating while pressing the tube according to a rotation of the rotating unit, and a drug injection device comprising the same.

The present disclosure generally relates to the field of aerosol generation devices, and more particularly to electronic cigarettes configured to generation of aerosols from aqueous formulations of nicotine or cannabis products. The present disclosure further provides aqueous cannabinoid compositions for use in the aerosol generation devices.