A metallic bottle can including a metallic base material of the bottle shape that has a mouth portion having a threaded portion, a shoulder portion, a body portion and a bottom portion, wherein, on the outer surface of said mouth portion, a finishing varnish layer is provided directly on said metallic base material, and said finishing varnish layer has an MEK extractability of 2 to 8% by mass.

A method and a device for printing onto containers, in particular bottles, made of glass are described. Containers that have been heated and coated by hot end coating are received from a transport section and transferred to a printing machine. The containers are cooled to a printing temperature in the region of the transport section and/or of the printing machine are provided with a printed image in the printing maching by direct printing. This allows for high-quality direct printing with sufficient resistance to mechanical stresses without cold end coating of the containers prior to the direct printing and/or without the resulting effort of improving the adhesive action of the print or of removing the cold end coating in the print region at least in part.

Containers are provided that include a body structure having a top end that defines an opening, a sealed base end, and a sidewall structure extending between the top and base ends, in which the sidewall structure has an interior surface and an exterior surface, the interior surface defining an interior space, and a protective coating that includes a diamond-like carbon on at least a portion of the exterior surface of the sidewall structure. Methods for enhancing the mechanical strength of containers are also provided.

A coated glass container having a Type 1 chemical durability according to USP 660 (2011), a class A2 base resistance or better according to ISO 695, and a type HGB2 hydrolytic resistance or better according to ISO 719. The glass body having an interior surface and an exterior surface. A lubricous coating having a thickness of <100 microns positioned on the exterior surface. The portion of the exterior surface with the coating having a coefficient of friction that is at least 20% less than an uncoated glass container formed from the same glass composition and does not increase by more than 30% after undergoing depyrogenation at about 260 C. for 30 minutes. A horizontal compression strength of the coated glass container is at least 10% greater than an uncoated glass container formed from the same glass composition and is not reduced by more than 20% after heat treatment at about 260 C. for 30 minutes.

A liquid formulation of an ophthalmic drug in a pre-filled pharmaceutical package, for example a syringe, cartridge, vial or any other vessel made in part or in whole of a thermoplastic polymer, coated on the interior with a tie coating or layer, a barrier coating or layer, a pH protective coating or layer, and optionally a lubricity coating or layer. A blister, a pouch, a bag, a tray or a tub may encompass as a secondary packaging the syringe, vial, cartridge, tube or any other vessel. The package is suitable for sterilization (e.g., surface and/or terminal sterilization) with sterilization gas residuals being minimal and/or lower than required by ISO 10993-7; and/or the stability of the ophthalmic drug is maintained, during a prolonged time period following the sterilization. The sterilization gas may be EO, propylene oxide, chlorine dioxide, nitrogen dioxide, or vaporized hydrogen peroxide (VHP), among others.

The disclosure relates to a container comprising fibers, wherein the container further comprises a coating that is biodegradable. The disclosure further relates to a method for coating a container comprising fibers for producing the container.

A glass container for packaging a pharmaceutical composition including a glass tube with a first end and a second end, the glass tube having a wall thickness d.sub.w, a glass bottom having an outer area, and the glass bottom closes the glass tube at the first end. The glass container further including a curved glass heel extending from the outer area of the glass bottom to the first end of the glass tube. The curved glass heel is defined by an outer radius r.sub.o, an inner radius r.sub.i and a thickness of the glass d.sub.h in the curved glass heel, further wherein d.sub.h.sup.3/(r.sub.od.sub.w)>0.8 mm.

A glass container for storing pharmaceutical formulations may include a glass body formed from a Type IA or Type IB glass composition according to ASTM Standard E438-92(2011). The glass body may include a wall portion with an inner surface and an outer surface, a heel portion and a floor portion, wherein the inner surface of the glass container is formed by the inner surface of the glass body. The glass body may include at least a class A2 base resistance or better according to ISO 695, at least a type HGB2 hydrolytic resistance or better according to ISO 719 and Type 1 chemical durability according to USP <660>. The glass container does not comprise a boron-rich layer on the inner surface of the glass body in as formed condition.

A coated glass pharmaceutical package includes a glass body having a Type 1 chemical durability according to USP 660, at least a class A2 base resistance or better according to ISO 695, and at least a type HGB2 hydrolytic resistance or better according to ISO 719, the glass body having an interior surface and an exterior surface and a wall extending therebetween. A lubricous coating having a thickness of less than or equal to 90 nm may be positioned on at least a portion of the exterior surface of the glass body but not on any portion of the interior surface. The portion of the coated glass package with the lubricous coating comprises a coefficient of friction that is at least 20% less than an uncoated glass package and the coefficient of friction does not increase by more than 30% after undergoing a depyrogenation cycle including exposure to a temperature of 250? C. for a time period of 30 minutes. A horizontal compression strength of the coated glass package is at least 10% greater than an uncoated glass package and the horizontal compression strength is not reduced by more than 20% after undergoing the depyrogenation cycle including exposure to a temperature of 250? C. for a time period of 30 minutes and then being abraded. The lubricous coating comprises a polymer.

The disclosure relates to ink compositions for digital printing on an external surface of a plastic article. The ink compositions comprise an ink removal-promoting additive. In some aspects, the ink removal-promoting additive can facilitate the separation or loosening of the image from the external surface of the article when the image is exposed to a liquid-based solution at an elevated temperature. Also disclosed are recyclable plastic articles having an external surface with an image printed thereon using the disclosed ink composition and methods for removing cured ink from a plastic container. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present invention.