A catheter shaft is produced by forming a first polymeric layer onto a flexible inner core while maintaining the inner core in a solid state, and solidifying the first polymeric layer, wherein the solidified first polymeric layer fails to bond with the inner core and is slidable thereon upon flexion of the shaft. A second polymeric layer may be formed over the first polymeric layer, and is slidable thereon when the shaft bends.

A catheter shaft is produced by forming a first polymeric layer onto a flexible inner core while maintaining the inner core in a solid state, and solidifying the first polymeric layer, wherein the solidified first polymeric layer fails to bond with the inner core and is slidable thereon upon flexion of the shaft. A second polymeric layer may be formed over the first polymeric layer, and is slidable thereon when the shaft bends.

The invention comprises a peelable membrane for resealably closing a metal end comprising an outer layer, a tacky layer, and a heat seal layer. The heat seal layer is permanently sealed to the metal end to cover at least one opening in the metal end. The tacky layer causes the peelable membrane to be resealable onto the metal end.

An example medical device includes a balloon that is inflatable to an inflated configuration. The balloon includes a non-compliant layer coextruded on an inner layer, and an outer layer coextruded on the non-compliant layer. The non-compliant layer is configured to delaminate from the inner and the outer layers in the inflated configuration. The non-compliant layer may be configured to rupture in the inflated configuration. An example technique includes inflating the balloon to a predetermined pressure sufficient to rupture the non-compliant layer and insufficient to rupture both the inner and outer layers. The example technique further includes deflating the balloon, and introducing the balloon into a vasculature. Another example technique includes coextruding a non-compliant layer on an inner layer, coextruding an outer layer on the non-compliant layer, and forming a balloon from the inner layer, the non-compliant layer, and the outer layer.

An example medical device includes a balloon that is inflatable to an inflated configuration. The balloon includes a non-compliant layer coextruded on an inner layer, and an outer layer coextruded on the non-compliant layer. The non-compliant layer is configured to delaminate from the inner and the outer layers in the inflated configuration. The non-compliant layer may be configured to rupture in the inflated configuration. An example technique includes inflating the balloon to a predetermined pressure sufficient to rupture the non-compliant layer and insufficient to rupture both the inner and outer layers. The example technique further includes deflating the balloon, and introducing the balloon into a vasculature. Another example technique includes coextruding a non-compliant layer on an inner layer, coextruding an outer layer on the non-compliant layer, and forming a balloon from the inner layer, the non-compliant layer, and the outer layer.

A method of fabricating a balloon catheter configuration is provided, the method comprises: preparing one catheter body, the catheter body comprises one internal tube, one external tube, and one stripping agent; the internal tube comprises one longitudinal groove and one drain passageway, wherein the longitudinal groove is configured in the exterior surface of the internal tube, the drain passageway is configured inside the internal tube, the external tube covers the internal tube, and the stripping agent is configured between the internal tube and the external tube; removing the internal tube of the catheter to allow one end of the external tube of the catheter body beyond one end of the internal tube adjacent to the external tube; folding the end of the external tube toward the axial center of the catheter; and attaching the end of the external tube to one part of the inner wall of the drain passageway.

A method of fabricating a balloon catheter configuration is provided, the method comprises: preparing one catheter body, the catheter body comprises one internal tube, one external tube, and one stripping agent; the internal tube comprises one longitudinal groove and one drain passageway, wherein the longitudinal groove is configured in the exterior surface of the internal tube, the drain passageway is configured inside the internal tube, the external tube covers the internal tube, and the stripping agent is configured between the internal tube and the external tube; removing the internal tube of the catheter to allow one end of the external tube of the catheter body beyond one end of the internal tube adjacent to the external tube; folding the end of the external tube toward the axial center of the catheter; and attaching the end of the external tube to one part of the inner wall of the drain passageway.

It is disclosed a method for the production of a sealing module (1) for a pipe or a cable, the sealing module having a hollow body (10) and a plurality of inner layers (11a-11h) superimposed one to the other provided within said body (10), the layers (11a-11h) being removable one from the other to define the size of the cross-section of a housing (14) extending between two opposite surfaces (S1, S2) of the sealing module to house cables or pipes of different sizes, wherein said plurality of layers (11a-11h) are made of a thermoplastic material, or both said body (10) and said plurality of layers (11a-11h) are made of a thermoplastic material. It is also disclosed an apparatus for the production of a sealing module, and a sealing module made of thermoplastic material.

It is disclosed a method for the production of a sealing module (1) for a pipe or a cable, the sealing module having a hollow body (10) and a plurality of inner layers (11a-11h) superimposed one to the other provided within said body (10), the layers (11a-11h) being removable one from the other to define the size of the cross-section of a housing (14) extending between two opposite surfaces (S1, S2) of the sealing module to house cables or pipes of different sizes, wherein said plurality of layers (11a-11h) are made of a thermoplastic material, or both said body (10) and said plurality of layers (11a-11h) are made of a thermoplastic material. It is also disclosed an apparatus for the production of a sealing module, and a sealing module made of thermoplastic material.

A multi-layer visor system for a surgical hood or garment is provided. The system includes a base film layer and one or more removable film layers that are coextruded at high temperature to form a sterile surface between each of the film layers should the surgeon elect to peel away a soiled or splattered removable film layer during the course of a surgical procedure so that an unobstructed view can be maintained. Thus, no separate sterilization step is required in order to sterilize the layers of the visor system. Each of the removable film layers can additionally include a tab having distinctive features in order to enable a wearer to easily distinguish between the tabs in order to make it easier for a wearer to know which tab to pull first to remove the outermost removable film layer. Further, because the tabs are located about the perimeter of the removable films, viewing is not obscured, yet the film layers are held securely in place until easily removed from the underlying removable film layer or base film layer.