A puncture resistant material is made from high modulus continuous filament polypropylene yarns which are twisted and woven into a tight weave. Batting materials are placed adjacent the woven layer (which may comprise one or more individual woven layers) to form a stack and the stack is needlepunched to form a consolidated material. The material is heat treated and calendared and the finished product may be used in applications where puncture resistance is required, such as in a shoe insole material.

A puncture resistant material is made from high modulus continuous filament polypropylene yarns which are twisted and woven into a tight weave. Batting materials are placed adjacent the woven layer (which may comprise one or more individual woven layers) to form a stack and the stack is needlepunched to form a consolidated material. The material is heat treated and calendared and the finished product may be used in applications where puncture resistance is required, such as in a shoe insole material.

Disclosed is a garment bag comprising: a first and second panel attached along three sides, defining a bag interior; wherein a plurality of receiving fasteners are provided in the bag interior on the first panel adjacent to a top edge. The receiving fasteners may be used to securely provide garments having hooks into the garment bag.

A web of nonwoven fabric suitable for, e.g., the loop portion of a hook-and-loop fastening system. The method for making this material relies on differential shrinkage of different layers to cause the loops to self-form. The method is robust and simpler than that previously used for similar constructions.

A drug delivery device comprising: a first layer comprising a first coaxially electrospun nanofiber membrane; a second layer comprising a second coaxially electrospun nanofiber membrane; a first therapeutic agent integrated into the first coaxially electrospun nanofiber membrane; and a second therapeutic agent integrated into the second coaxially electrospun nanofiber membrane. The second therapeutic agent is different from the first therapeutic agent.

A drug delivery device comprising: a first layer comprising a first coaxially electrospun nanofiber membrane; a second layer comprising a second coaxially electrospun nanofiber membrane; a first therapeutic agent integrated into the first coaxially electrospun nanofiber membrane; and a second therapeutic agent integrated into the second coaxially electrospun nanofiber membrane. The second therapeutic agent is different from the first therapeutic agent.

A wearable item comprising a conductive transfer applied to a surface of the wearable item is described. The conductive transfer comprises first and second non-conductive ink layers and an electrically conductive layer positioned between the two non-conductive ink layers. The transfer also has an adhesive layer which adheres the conductive transfer to the surface of the wearable item. The conductive transfer is configured to withstand elongation such that the resistance of the electrically conductive layer provides a resistance within a pre-specified range.

A conductive transfer for application to a surface is described. The conductive transfer comprises first and second non-conductive ink layers and an electrically conductive layer positioned between the first and second non-conductive ink layers. The conductive transfer also includes an adhesive layer for adhering the conductive transfer to the surface of an article.

A method of printing and processing a fabric having first material yarns forming a technical front, and second material yarns forming a technical back, first and second material yarns being held together by a ground; carding and polishing the technical front to increase the permeability of the fabric; printing an image on the technical front of the fabric, so that ink from the printing process penetrates to the ground of the fabric; brushing and napping the technical back, after the printing process, so that ink from the technical front is pulled through the ground to the technical back, so that a mirror image of the image from the technical front is formed on the technical back.

A method of printing and processing a fabric having first material yarns forming a technical front, and second material yarns forming a technical back, first and second material yarns being held together by a ground; carding and polishing the technical front to increase the permeability of the fabric; printing an image on the technical front of the fabric, so that ink from the printing process penetrates to the ground of the fabric; brushing and napping the technical back, after the printing process, so that ink from the technical front is pulled through the ground to the technical back, so that a mirror image of the image from the technical front is formed on the technical back.