The invention relates to a spherical receiving device for receiving at least one rotational mold, which is configured and intended to be driven to rotate in a rotational device by means of a drive wheel rolling on the outer side of the spherical receiving device. The spherical receiving device is distinguished by the fact that it has at least one guiding device which causes a drive wheel rolling on the outer side of the spherical receiving device to follow a predetermined rolling path on the outer side of the spherical receiving device. The invention also relates to a rotational device which has such a spherical receiving device and a drive wheel which is driven by means of a drive motor, said drive wheel rolling on the outer side of the spherical receiving device and driving the spherical receiving device to rotate.

Microneedle arrays and methods of forming the same can include one or more bioactive components bonded to a biocompatible material such that the one or more bioactive components are cleavable in vivo to release the bioactive component from the biocompatible material.

Microneedle arrays and methods of forming the same can include one or more bioactive components bonded to a biocompatible material such that the one or more bioactive components are cleavable in vivo to release the bioactive component from the biocompatible material.

The invention relates to a method for producing rotomolded products, and to an installation for carrying out such a method. The method is characterized by the simultaneous use of a plurality of spherical receptacle members, each without a dedicated rotary drive, each of which containing at least one molding die that is suppliable with raw material, and by the simultaneous use of a plurality of processing devices which are operated in a mutually independent manner, each for carrying out at least one of a plurality of production steps, using in each case one of the spherical receptacle members, wherein a plurality of processing devices which are configured as rotating stations are used in a temporally parallel or temporally overlapping manner, and/or wherein a plurality of processing devices which are configured as cooling stations are used in a temporally parallel or temporally overlapping manner, and/or wherein a plurality of processing devices which are configured as supply stations are used in a temporally parallel or temporally overlapping manner, and/or wherein a plurality of processing devices which are configured as retrieval stations are used in a temporally parallel or temporally overlapping manner, and wherein the spherical receptacle member conjointly with the content thereof and without the rotary drive is in each case retrieved from the processing device which has just terminated a processing step, said spherical receptacle member thereafter being fed to a processing device that is immediately vacant for the respective next processing step.

Microneedle arrays and methods of forming the same can include one or more bioactive components bonded to a biocompatible material such that the one or more bioactive components are cleavable in vivo to release the bioactive component from the biocompatible material.

Microneedle arrays and methods of forming the same can include one or more bioactive components bonded to a biocompatible material such that the one or more bioactive components are cleavable in vivo to release the bioactive component from the biocompatible material.

An apparatus for spin casting lenses includes a rotatable tube, the rotatable tube defining a longitudinal cavity, wherein the longitudinal cavity is configured to receive molds. According to one exemplary embodiment, the rotatable tube is made of metal and includes a plurality of apertures configured to permit the transmission of actinic radiation.

An apparatus for spin casting lenses includes a rotatable tube, the rotatable tube defining a longitudinal cavity, wherein the longitudinal cavity is configured to receive molds. According to one exemplary embodiment, the rotatable tube is made of metal and includes a plurality of apertures configured to permit the transmission of actinic radiation.

The present disclosure relates to a method of fabricating an article. This method involves obtaining a non-planar surface model of an article to be fabricated; creating X and Y coordinates of the surface to create an X-Y plane; creating planes orthogonal to the X-Y plane to obtain lines of intersection between the surface and said planes; correlating coordinates of intersecting lines to create non-planar print paths; and printing along the print paths to fabricate the article. Also disclosed are a system and a computer program product that functions to control a system to carry out the methods of the present disclosure.

Disclosed is a silicone dipped glove, comprising a glove core and a dipping layer. The dipping layer is a silicone mixed compound layer, and the silicone mixed compound layer is composed of the following components at the following proportions by weight: 70-90% of silicone, 5-20% of a curing agent, 5-20% of a diluent, and 0-10% of a color paste. The silicone mixed compound layer of the present invention is composed of silicone, a curing agent and a diluent.