An activation mechanism for an aerosol dispenser is presented having a first housing structure, an actuation member movably arranged in the first housing structure, wherein the first housing structure is provided with an actuation member opening in level with the axial position of the actuation member, and an activation member slidably attached to the first housing structure, the activation member slides between a non-triggering position and a triggering position relative to the first housing structure, wherein the activation member has a radially flexible tab portion that is offset from the actuation member opening when the activation member is in the non-triggering position, restricting radial flexing of the tab portion, and wherein the tab portion aligns with the actuation member opening when the activation member is in the triggering position, thereby enabling the tab portion to flex radially inwards to cause movement of the actuation member.

A locking mechanism for an aerosol dispenser is presented having a first body structure, a second body structure rotatably attached to the first body structure, a spindle rotatably attached to the second body structure, the spindle having an actuator rotationally cooperating with the first body structure such that rotation of the first body structure relative to the second body structure causes rotation of the actuator and of the spindle, a movable element arranged around the spindle, the spindle being rotatable relative to the movable element, wherein rotation of the spindle causes movement of the movable element along the spindle from an initial position to a final position, and a locking element, wherein in the final position the movable element applies a radial force onto the locking element causing the locking element to bend in the radial direction thereby preventing rotation between the first body structure and the second body structure.

Fluid delivery device for discharging a fluid, having: a housing; piston pump; biasing mechanism; and trigger mechanism. The housing has a basal end and a discharge end with outlet for discharging the fluid. The piston pump has a casing defining a pump chamber for storage of fluid, a piston slidably movable relative to the pump chamber, a piston plunger, and a delivery channel. The trigger mechanism is movable from a cocked configuration wherein the trigger mechanism prevents transfer of a biasing force of the biasing mechanism to the casing to a triggered configuration with the trigger mechanism enabling transfer of the biasing force to the casing to cause movement of the casing towards the housing outlet to discharge fluid from the pump chamber, along the delivery channel and out of the outlet of the housing. The biasing mechanism has one or more flexible catch members and a manually operable trigger.

A system for testing the proper functioning of an atomiser for dispensing a fluid in the form of an aerosol is proposed, wherein the system comprises the atomiser and a test apparatus, wherein the atomiser comprises a container holding the fluid, and a housing part for inserting and/or replacing the container, wherein the container is movable relative to the housing part in order to dispense the fluid and the test apparatus comprises a measuring device for measuring the movement of the container when the fluid is dispensed. In addition, a method for testing the proper functioning of an atomiser for dispensing a fluid in the form of an aerosol is proposed, wherein the atomiser comprises a container holding the fluid, and a housing part for inserting and/or replacing the container, wherein the container is moved relative to the housing part in order to dispense the fluid and the movement of the container is measured and/or analysed when the fluid is dispensed.

A system includes a nebulizer for nebulizing a fluid from a container and such a container containing a fluid and are proposed. The fluid is a non-newtonian fluid, in form of a suspension or emulsion or a liposomal fluid or a gel. The nebulizer includes a fluid pump for withdrawing the fluid in doses from the container and pressurizing the respective doses for nebulization through nozzle channels having a hydraulic diameter in the range of 3 to 20 microns at an operational pressure of 5 to 250 MPa.

A method for producing a cartridge is proposed, where a fluid is filled into an opening of a container and a closure part is inserted into the container, thereby moving a movable piston arranged within the container.

An inhaler, preferably for insertion into a nostril, in particular a horse's nostril, with a pressure generator, which has a tensioning device for the drive, and with a tensioning mechanism for tensioning the tensioning device, whereby the tensioning mechanism has a lever gear for tensioning the tensioning device.

An inhaler is proposed having an insertable container and a monitoring device for counting uses of the inhaler. The monitoring device is arranged in a detachable housing part or fitted onto a mouthpiece of the inhaler. A supply air current is detected by means of a pressure sensor. A position sensor may further be provided.

A device for delivering a predetermined amount of a substance within at least one body cavity of a subject, where the predetermined amount is at an effective amount for treatment of obesity or binge eating disorder. The device comprises: (a) A volume to contain the predetermined amount of the substance. (b) A delivery end placeable in proximity to the body cavity. The delivery end is in fluid communication with the volume and comprises at least one orifice. (c) A valve mechanically connected to the volume, with at least two configurations: (i) an active configuration configured to deliver the predetermined amount of the substance; and, (ii) an inactive configuration, in which the valve prevents delivery of the predetermined amount of the substance. (d) A fluid tight chamber configured to contain a predetermined volume of pressurized gas at a predetermined pressure.

The invention relates to a method for the surface modification of microstructured components having a polar surface, in particular for high-pressure applications. According to said method, a microstructured component is contacted, in particular treated, with a modification reagent, the surface properties of said component being modified by chemical and/or physical interaction of the component surface and of the modification reagent.