The various embodiments of the subject invention included herein provide devices, systems and methods for aiding the regrooming or refolding of balloons upon deflation. The scope of the inventions in this specification includes methods and devices that reduce the profile of balloons after deflation, reduce or eliminate wings, high-points, irregularities, bunching, thickening, and the like, and facilitate passage of a deflated balloon through a body void or lumen, or through a medical device such as a guide catheter, guide sheath, femoral or radial introducer sheath, and the like.

An apparatus for rolling a bladder includes a support structure, a rolling pin, and a bladder-mounting pin. The apparatus optionally includes a rolling initiator Rolling a bladder includes inserting the bladder while unrolled into an apparatus for rolling a bladder, inserting the bladder between a rolling pin and a bladder-mounting pin of the rolling machine, and rotating the rolling pin to (a) advance a portion of the bladder between the rolling pin and the bladder-mounting pin, (b) roll the portion of the bladder around the bladder-mounting pin, and (c) drive the bladder-mounting pin to rotate in an opposite direction from that of the rolling pin.

A balloon catheter is provided that may be used to dilate hardened regions of a stenosis. The balloon catheter is provided with one or more dilation elements that extend along a surface of a balloon. Each dilation element is monolithically connected to an outer surface of the balloon by a connector. The connector is sufficiently sized and designed to undergo stress-induced plastic deformation incurred during blow molding so that a significant portion of each of the dilation elements does not become absorbed into the wall of the final blow molded balloon, thereby maintaining the structural integrity of each of the dilation elements. The dilation element has a flattened outer surface along at least proximal and distal neck portions of the balloon.

The present disclosure describes implantable medical devices comprising covers, such as a balloon cover. Such devices can comprise a first layer of a porous polymeric material, such as ePTFE, surrounded by layers of a porous polymeric material having an imbibed elastomer, such as polyurethane. The cover can be used to assist in deployment of an expandable implant, such as a stent-graft, within the body of the patient.

The present invention is intended to provide a carrying support that grasps work tubes different in length and type such that the lower ends are at the same height, is easy for the worker to carry by hand and realize automatic carrying, and is further capable of fixing the tube end portions to be processed in many cases at a constant height, thereby to assure the degree of freedom of designing manufacturing devices when the carrying support is also used as a jig for the devices. The carrying support is provided with a first grasping part (11) and a second grasping part (12) that grasp both end sides of work tubes (W) bent in middle parts at an upper position and extending downward.

The present disclosure describes implantable medical devices comprising covers, such as a balloon cover. Such devices can comprise a first layer of a porous polymeric material, such as ePTFE, surrounded by layers of a porous polymeric material having an imbibed elastomer, such as polyurethane. The cover can be used to assist in deployment of an expandable implant, such as a stent-graft, within the body of the patient.

The present disclosure describes implantable medical devices comprising covers, such as a balloon cover. Such devices can comprise a first layer of a porous polymeric material, such as ePTFE, surrounded by layers of a porous polymeric material having an imbibed elastomer, such as polyurethane. The cover can be used to assist in deployment of an expandable implant, such as a stent-graft, within the body of the patient.

A metal balloon catheter having a main tubular body, a metal balloon proximate a distal end of the main tubular body, a central annulus extending along an entire longitudinal aspect of the catheter for accommodating a guidewire therethrough and an inflation annulus adjacent the central annulus which extends along the longitudinal axis of the main tubular body and terminates in fluid flow communication with an inflation chamber of the metal balloon. The metal balloon catheter may be either unitary integral metal catheter in which the main tubular body and the balloon are fabricated of metal, or it may consist of a polymeric main tubular body and a metal balloon.

A portable apparatus including a storage and a support arrangement that is convertible to a resting platform defined as a back pack or a suitcase.

A medical balloon comprises a first end, a second end spaced apart from the first, and a generally cylindrical balloon wall extending therebetween to define an inflation chamber. The balloon wall is adapted for inflation from a first folded configuration having a first plurality of pleats to an expanded, unpleated configuration, and deflation therefrom to a second folded configuration having a second plurality of pleats. The balloon wall includes a first layer formed of a polymer and having a substantially constant radial thickness. A second layer is firmly attached to the first layer and has a plurality of first regions of greater radial thickness interleaved with a plurality of second regions of reduced radial thickness. During deflation from the expanded, unpleated configuration to the second folded configuration, the balloon wall folds along the regions of reduced radial thickness of the second layer to form the second plurality of pleats.