An applicator for inserting a micro needle array (4) into skin includes a holding part (211) that holds the micro needle array (4), and an insertion assist part (223) that forms an insertion complete state in which a central array region of the micro needle array (4) further protrudes on the skin side than a peripheral array region provided closer to a peripheral side of the micro needle array (4) than the central array region.

An apparatus includes a housing coupled to a medicament container, which is coupled to a needle. An injection assembly is disposed within the housing and includes an energy storage member and an actuation rod. A distal end portion of the actuation rod is disposed within the medicament container. The energy storage member can produce a force on a proximal end portion of the actuation rod sufficient to move the distal end portion of the actuation rod within the medicament container. This can convey at least a portion of a substance from the medicament container via the needle when a distal tip of the needle is disposed within a first region of a target location. The force is insufficient to move the distal end portion of the actuation rod within the medicament container when the distal tip of the needle is disposed within a second region of the target location.

The present invention relates to a kit comprising: at least one microneedle sheet (1) comprising a substrate layer and a plurality of microneedles on the substrate layer, the microneedles comprising at least one water-soluble or water-dispersible polymer; and a device comprising an applicator (2-3) comprising an application surface, a container (2-1) comprising a cosmetic composition and a valve, wherein the microneedle sheet (1) is capable being attached to the applicator (2-3) by attaching the substrate layer of the microneedle sheet to the application surface, the applicator (2-3), the container (2-1) and the valve are configured to supply the cosmetic composition via the valve onto the microneedle sheet (1). The kit according to the present invention can prevent the repeated use of microneedles (1), and can apply a cosmetic product in an easy and sanitary manner.

A fluid delivery apparatus includes a collet assembly having an upper and lower wall attached at a central portion of the collet. The central portion defines an inner step, and the lower wall includes circumferentially-spaced flexible tabs. The fluid delivery apparatus also includes a fluid distribution assembly coupled to the collet assembly. The fluid distribution assembly is positionable relative to the collet between a pre-use configuration and a pre-activated configuration. The fluid distribution assembly has a plenum that includes a sleeve component having an exterior ledge extending thereabout. A lower wall portion of the sleeve component includes protrusions corresponding to the flexible tabs of the collet. In the pre-use configuration the exterior ledge of the sleeve component is engaged with the inner step of the collet assembly, and each flexible tab engages a respective protrusion to provide a snap-fit between the fluid distribution assembly and the collet assembly.

Methods for performing non-invasive thrombolysis with ultrasound using, in some embodiments, one or more ultrasound transducers to focus or place a high intensity ultrasound beam onto a blood clot (thrombus) or other vascular inclusion or occlusion (e.g., clot in the dialysis graft, deep vein thrombosis, superficial vein thrombosis, arterial embolus, bypass graft thrombosis or embolization, pulmonary embolus) which would be ablated (eroded, mechanically fractionated, liquefied, or dissolved) by ultrasound energy. The process can employ one or more mechanisms, such as of cavitational, sonochemical, mechanical fractionation, or thermal processes depending on the acoustic parameters selected. This general process, including the examples of application set forth herein, is henceforth referred to as “Thrombolysis.”

An introducer is provided for introducing a sensor into the body of a patient. The introducer connects to a sensor hub. When the sensor hub and introducer are connected, the introducer needle is exposed. When the sensor hub and introducer are disconnected, a needle cover and the needle move with respect to each other so that the needle cover substantially covers the needle, protecting a user from being injured by the needle.

A microneedle patch applicator housing, being formed from a single sheet or film having a top surface and an undersurface, the housing including a flat peripheral base part and a raised part surround by the peripheral base part and bulging vertically, with respect to the peripheral base part, from the undersurface toward the top surface, an undersurface portion of the raised part forming a surface supporting a microneedle patch, the raised part including a plurality of concavely bent parts, and the concavely bent parts each having a concave bottom toward a direction away from a center portion of the raised part.

A microneedle patch applicator housing, being formed from a single sheet or film having a top surface and an undersurface, the housing including a flat peripheral base part and a raised part surround by the peripheral base part and bulging vertically, with respect to the peripheral base part, from the undersurface toward the top surface, an undersurface portion of the raised part forming a surface supporting a microneedle patch, the raised part including a plurality of concavely bent parts, and the concavely bent parts each having a concave bottom toward a direction away from a center portion of the raised part.

The present invention provides a solution to increase the drug loading capacity and drug delivery precision of dissolving microneedles. These solutions include: (a) increasing the base of the microneedle cavities without substantially changing the microneedle's height and geometry, (b) use of drug suspension and sedimentation of drug by centrifugation, and (c) a specific centrifugation order for filling drug and matrix material. In the first preferred embodiment, a microneedle master mould comprising a plurality of pyramidal microneedles (5100), wherein each of the pyramidal microneedles further comprising a chamfered base (5200) which extends to and adjoins with its neighbouring chamfered bases is provided. In the second preferred embodiment, a method of making dissolving microneedles is provided, comprising (a) providing a microneedle template comprising a plurality of pyramidal microneedle cavities, wherein each of the pyramidal microneedle cavities further comprising a chamfered base which extends to and adjoins with its neighbouring chamfered bases; (b) loading a drug suspension in the substrate cavity on the microneedle template; (c) centrifuging the microneedle template which is loaded with a drug suspension, (d) loading a matrix material solution in the substrate cavity on the microneedle template; (d) centrifuging the microneedle template loaded with the drug suspension and the matrix material solution; and (e) drying the centrifuged microneedle template in a controlled environment.

A gas mixing system for providing mixed gas for intraocular injection. In some embodiments, a first fixed-volume chamber is automatically purged and filled with gas from a first gas supply input, to a first predetermined pressure. A second fixed-volume chamber is purged and filled with gas from a second gas supply input, to a second predetermined pressure. The first and second predetermined pressures are determined based on a desired concentration of gases in the final mix, and the respective volumes of the first and second fixed-volume chambers and of a third fixed-volume chamber. Gas from the first fixed-volume chamber is then allowed to mix with gas in the third fixed-volume chamber, which was previously purged. Next, gas from the second fixed-volume chamber is allowed to mix with gas in the third fixed-volume chamber. Finally, the mixture of gases in the third fixed-volume chamber is expressed into an intraocular syringe.