The present disclosure relates to polymer resins, fibers, and yarns with permanent antimicrobial activity, and a method of producing the same. In one embodiment, the antimicrobial polymer resin comprises a polymer having less than 2500 ppm of zinc dispersed within the polymer, less than 1000 ppm of phosphorus, wherein the weight ratio of zinc to phosphorus is at least 1.3:1 or less than 0.64:1.

The invention relates to an adhesive tape, in particular wrapping tape, for sheathing automotive cables, having a mostly textile support and at least one adhesive coating layer applied to one side or both sides of the textile support, and the textile support being manufactured entirely or partially from bio-based polymer fibers and/or polymer yarns, characterized in that the textile support is a velours support or includes such a velours support.

A transparent static-dissipative polycarbonate (PC) resin composition includes the following components: 70-95 parts by weight of PC resin, 5-30 parts by weight of antistatic agent masterbatch and 0.5-1.5 parts by weight of a transesterification inhibitor. The antistatic agent masterbatch includes the following components by mass percentage: 40-60% of an antistatic agent, 0.5-1.6% of a transesterification accelerator, 1-3% of an assistant cross-linkinger, and the balance of PC resin. A method for preparing the transparent static-dissipative PC resin composition includes the following steps: (I) preparing the components of the transparent static-dissipative PC resin composition according to the formulation, and mixing the components evenly to obtain a premix; and (II) adding the premix into a twin-screw extruder, melting, extruding, cooling and pelletizing, to obtain a target product.

A transparent static-dissipative polycarbonate (PC) resin composition includes the following components: 70-95 parts by weight of PC resin, 5-30 parts by weight of antistatic agent masterbatch and 0.5-1.5 parts by weight of a transesterification inhibitor. The antistatic agent masterbatch includes the following components by mass percentage: 40-60% of an antistatic agent, 0.5-1.6% of a transesterification accelerator, 1-3% of an assistant cross-linkinger, and the balance of PC resin. A method for preparing the transparent static-dissipative PC resin composition includes the following steps: (I) preparing the components of the transparent static-dissipative PC resin composition according to the formulation, and mixing the components evenly to obtain a premix; and (II) adding the premix into a twin-screw extruder, melting, extruding, cooling and pelletizing, to obtain a target product.

A curable composition includes a perfluoro(poly)ether group-containing silane compound represented by the general formula (I) (wherein, definitions of each group are as described in the specification); (b) an organic silicon compound having at least two OR.sup.2 groups bonded to Si atom (here, R.sup.2s are each independently a hydrogen atom or a monovalent organic group at each appearance) or a partially hydrolyzed condensate thereof; and (c) a condensation catalyst.

A curable composition includes a perfluoro(poly)ether group-containing silane compound represented by the general formula (I) (wherein, definitions of each group are as described in the specification); (b) an organic silicon compound having at least two OR.sup.2 groups bonded to Si atom (here, R.sup.2s are each independently a hydrogen atom or a monovalent organic group at each appearance) or a partially hydrolyzed condensate thereof; and (c) a condensation catalyst.

A charging member includes a conductive base material; an elastic layer that is provided on the conductive base material and has a storage elastic modulus G of 5.0 MPa or less at 100 Hz; and a surface layer that is provided on the elastic layer, in which in a Cole-Cole plot obtained by measuring the charging member in a range of 1 MHz to 0.1 Hz by an alternating current impedance method, a resistance component Ra of a capacitive semicircle including 2.5 kHz is 6.3×104Ω or less.

A charging member includes a conductive base material; an elastic layer that is provided on the conductive base material and has a storage elastic modulus G of 5.0 MPa or less at 100 Hz; and a surface layer that is provided on the elastic layer, in which in a Cole-Cole plot obtained by measuring the charging member in a range of 1 MHz to 0.1 Hz by an alternating current impedance method, a resistance component Ra of a capacitive semicircle including 2.5 kHz is 6.3×104Ω or less.

Provided herein in some embodiments is an apparatus including a composite balloon with a tubular fiber layer and a polymeric balloon layer over the fiber layer. Also provided herein in some embodiments is a method including inserting a collapsed fiber tube into an expanded polymeric balloon, expanding the collapsed fiber tube to provide an expanded fiber tube, and securing an outer surface of the expanded fiber tube to an inner surface of the expanded polymeric balloon. The method can further include inserting a distal portion of an elongate catheter body through a center of the composite balloon and securing the composite balloon to the distal portion. Thereby, the method can include forming the catheter body with the composite balloon configured to apply a pressure to surrounding walls of an anatomical vessel in an inflated state of the composite balloon to modify one or more intravascular lesions in the anatomical vessel.

Provided herein in some embodiments is an apparatus including a composite balloon with a tubular fiber layer and a polymeric balloon layer over the fiber layer. Also provided herein in some embodiments is a method including inserting a collapsed fiber tube into an expanded polymeric balloon, expanding the collapsed fiber tube to provide an expanded fiber tube, and securing an outer surface of the expanded fiber tube to an inner surface of the expanded polymeric balloon. The method can further include inserting a distal portion of an elongate catheter body through a center of the composite balloon and securing the composite balloon to the distal portion. Thereby, the method can include forming the catheter body with the composite balloon configured to apply a pressure to surrounding walls of an anatomical vessel in an inflated state of the composite balloon to modify one or more intravascular lesions in the anatomical vessel.