A balloon coating method is disclosed, which includes an application step in which, where a flexible dispensing tube for supplying a coating solution containing the water-insoluble drug and a solvent is formed at its end portion with an opening portion for discharging the coating solution therethrough and when the opening portion-formed end portion side of the dispensing tube is kept in contact with the outer surface of the balloon in such a manner as to be oriented in a direction opposite to a rotating direction of the balloon while the balloon is rotated about an axis of the balloon, the coating solution is discharged through the opening portion and applied to the outer surface of the balloon while the dispensing tube is moved relative to the balloon in an axial direction X of the balloon.

A positioning method for balloon coating by which the thickness, morphological form and the like of a drug in a coating formed on a balloon can be suitably set. This method is a positioning method for balloon coating for forming a coating layer containing a water-insoluble drug on an outer surface of a balloon of a balloon catheter. The positioning method includes a positioning step in which the dispensing tube is positioned in such a manner that a virtual position at which an opening portion would be located if the dispensing tube is assumed to be non-flexible is located within the range of 0 degrees to 40 degrees from the reference plane toward the rotating direction side of the balloon, in a region extending from the reference plane in a direction opposite to the discharge direction of the dispensing tube.

A gripper for a fastener installation assembly includes a body having a passage extending from a first end of the body to a second end of the body. The gripper includes an inlet of the passage disposed at the second end of the body and an outlet of the passage disposed at the first end of the body. The first end of the body includes a lip configured to engage a fastener and the lip includes the outlet of the passage. The inlet is configured to couple to a sealant source to receive sealant into the passage. The gripper is configured such that sealant received at the inlet passes through the passage and is dispensed through the outlet onto the fastener engaged by the lip of the body.

A liner machine for applying a sealing compound to a can end or lid. The liner machine includes a motor drive dual turret system. The turret system is installed at the top of a table or platform surface and two turrets rotate in opposition directions from one another, simultaneously or independently at same or different times. Each turret includes a plurality of workstations which extend out from each turret facing away from each other. The workstations receive an individual lid, which is delivered via a starwheel from a downstacker to each turret system. Each rotates in a direction that is opposite the direction that its respective turret system rotates, and in a direction that is opposite the direction that the other starwheel rotates. Sealant injectors in the turret systems apply sealant to each lid as the lids rotate around each turret system.

An automated apparatus and method for coating medical devices such as an intravascular stent, are disclosed in the method, a 2-D image of a stent is processed to determine (1) paths along the stent skeletal elements by which a stent secured to a rotating support element can be traversed by a dispenser head whose relative motion with respect to the support element is along the support-element axis, such that some or all of the stent skeletal elements will be traversed (2) the relative speeds of the dispenser head and support element as the dispenser head travels along the paths, and (3), and positions of the dispenser head with respect to a centerline of the stent elements as the dispenser head travels along such paths The rotational speed of the support and relative linear speed of the dispenser are controlled to achieve the desired coating thickness and coating coverage on the upper surfaces, and optionally, the side surfaces, of the stent elements.

A container (1) for accommodating an ophthalmic lens during a lens treatment process has a longitudinal axis (11) and comprises as separate elements a containment element (2), a mounting element (3), and a retaining element (4). The containment element (2) comprises a tubular section (21) and a bottom (22) arranged at a distal end of the tubular section (21), the bottom (22) protruding convexly towards the outside at the distal end of the tubular section (21) and being provided with a number of apertures (23, 24), the tubular section (21) at a proximal end (25) thereof having a latch (26) protruding from the proximal end (25) of the tubular section (21) towards the mounting element (3). The mounting element (3) comprises a sidewall (31) extending along the longitudinal axis (11) of the container (1), the sidewall (31) being provided with recesses or orifices (32) which are in engagement with the latch (26) of the containment element (2). The mounting element (3) further comprises an access opening (37) arranged at a proximal end of the mounting element (3) remote from the containment element (2). The retaining element (4) is fixedly arranged in between the containment element (2) and the mounting element (3), the retaining element (4) being configured to prevent the ophthalmic lens from being washed out of the containment element (2) and to permit access for a gripper through the access opening (37) of the mounting element (3) into the containment element (2) for insertion and removal of the ophthalmic lens.

Methods for processing a vessel, for example to provide a gas barrier or lubricity, are disclosed. First and second PECVD or other vessel processing stations or devices and a vessel holder comprising a vessel port are provided. An opening of the vessel can be seated on the vessel port. The interior surface of the seated vessel can be processed via the vessel port by the first and second processing stations or devices. Vessel barrier and lubricity coatings and coated vessels, for example syringes and medical sample collection tubes are disclosed. A vessel processing system is also disclosed.

Various embodiments of methods and devices for coating stents are described herein.

A container (1) for accommodating an ophthalmic lens during a lens treatment process has a longitudinal axis (11) and comprises as separate elements a containment element (2), a mounting element (3), and a retaining element (4). The containment element (2) comprises a tubular section (21) and a bottom (22) arranged at a distal end of the tubular section (21), the bottom (22) protruding convexly towards the outside at the distal end of the tubular section (21) and being provided with a number of apertures (23, 24), the tubular section (21) at a proximal end (25) thereof having a latch (26) protruding from the proximal end (25) of the tubular section (21) towards the mounting element (3). The mounting element (3) comprises a sidewall (31) extending along the longitudinal axis (11) of the container (1), the sidewall (31) being provided with recesses or orifices (32) which are in engagement with the latch (26) of the containment element (2). The mounting element (3) further comprises an access opening (37) arranged at a proximal end of the mounting element (3) remote from the containment element (2). The retaining element (4) is fixedly arranged in between the containment element (2) and the mounting element (3), the retaining element (4) being configured to prevent the ophthalmic lens from being washed out of the containment element (2) and to permit access for a gripper through the access opening (37) of the mounting element (3) into the containment element (2) for insertion and removal of the ophthalmic lens.

An automated apparatus and method for coating medical devices such as an intravascular stent, are disclosed in the method, a 2-D image of a stent is processed to determine (1) paths along the stent skeletal elements by which a stent secured to a rotating support element can be traversed by a dispenser head whose relative motion with respect to the support element is along the support-element axis, such that some or all of the stent skeletal elements will be traversed (2) the relative speeds of the dispenser head and support element as the dispenser head travels along the paths, and (3), and positions of the dispenser head with respect to a centerline of the stent elements as the dispenser head travels along such paths The rotational speed of the support and relative linear speed of the dispenser are controlled to achieve the desired coating thickness and coating coverage on the upper surfaces, and optionally, the side surfaces, of the stent elements