Fusion bonding of cathether components

Plastic and nonmetallic article shaping or treating: processes – Laser ablative shaping or piercing

Reexamination Certificate

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Details

C264S248000, C264S482000, C264S483000, C156S272800, C156S314000

Reexamination Certificate

active

06596217

ABSTRACT:

BACKGROUND OF THE INVENTION
This invention relates to the field of intravascular catheters, and more particularly to the means to sealingly affix catheter components together.
Intravascular balloon catheters such as those used in percutaneous transluminal angioplasty (PTA) and percutaneous transluminal coronary angioplasty (PCTA) generally have an inflatable balloon mounted along the distal region of the catheter, surrounding the catheter shaft. A catheter shaft lumen is configured for the delivery of inflation media to the interior of the balloon, to inflate the balloon once it is positioned at the desired location within the patient's vasculature.
Typically, the balloon catheter has an outer tubular member with a distal extremity terminating within the balloon interior and an inner tubular member with a distal extremity extending through and slightly beyond the distal end of the balloon. The annular space between the inner and outer members defines the inflation lumen in communication with the balloon interior. The integrity of the balloon interior is maintained, thereby enabling the balloon interior to hold inflation media, by fluid tight bonds located at proximal and distal extremities of the balloon which secure the balloon to the outer tubular member and the inner tubular member respectively. However, a variety of catheter designs are known. For example, the balloon can be coextruded with the catheter outer tubular member with a fluid tight bond securing the balloon distal extremity to the inner tubular member. Similarly, a single catheter shaft provided with a plurality of lumens can be used in place of the inner and outer membered shaft.
In the manufacture of balloon catheters, a number of techniques may be used to bond the balloon to the catheter shaft, including use of heat shrinkable balloon material, adhesives or fusion bonding. One attractive method of fusion bonding involves the use of laser energy. In this instance, the balloon and shaft mating surfaces are rapidly heated by a laser at the desired location of the bond. The temperature of the surfaces exposed to the intense and focused heat of the laser beam changes at a rate of approximately 10
10
degrees C. per second. This heat from the application of the laser beam melts the interface of the two surfaces, which fuse together upon subsequently cooling down and a solid fusion bond is formed.
While laser bonding is a known technique for bonding balloons to catheter shafts, see for example U.S. Pat. No. 4,958,634 (Jang) and also U.S. Pat. No. 5,267,959 (Forman), one difficulty has been forming a balloon catheter using laser bonds between immiscible polymeric materials. Laser bonding typically requires the use of polymeric materials which are materially soluble or miscible when in the molten state. For example, materials from the same polymer family, such as polyethylene terephthalate (PET) and HYTREL® which are both polyesters, will form strong laser bonds together, whereas, PET and nylon will not.
Laser bonding provides bonds suitable for use in balloon catheter manufacture which are fluid tight, and sufficiently strong to withstand the fluid pressures produced by the inflation media which sometimes can exceed 400 psi. Moreover, because laser bonding generally provides superior repeatability in manufacturing, it is a preferred bonding method. However, because the ideal catheter shaft and balloon materials are chosen based on factors such as strength, flexibility and stiffness, the ideal materials are not necessarily compatible polymeric materials capable of being effectively fusion bonded together. Therefore, what has been needed is the ability to fusion bond dissimilar materials together to form the invention claimed, which is a catheter with a fusion bond. The present invention satisfies these and other needs.
SUMMARY OF THE INVENTION
The invention is directed to a catheter having a first polymeric component fusion bonded to a second polymeric component.
The catheter of the invention generally has a first catheter part formed of a first polymeric material and a second catheter part formed of a second polymeric material fusion bonded to the first catheter part, with the fusion bond containing a compatibilizing material which enhances the miscibility of the polymeric materials during the fusion bonding. Although the polymer materials of the catheter parts may not be compatible and therefore completely miscible in the molten state, a fusion bond is formed due to the compatibilizing material which is itself miscible with the polymeric materials of both catheter parts in the molten state.
In one aspect of the invention, the catheter of the invention is a balloon catheter generally having an elongated catheter shaft comprising at least one tubular member with at least one lumen extending therein. An inflatable balloon on a distal portion of the shaft has an interior in fluid communication with the shaft lumen. The balloon is secured to the catheter shaft by one or more fusion bonds, as when a distal skirt of the balloon is sealed about and secured to a tubular member of the catheter shaft by a distal fusion bond, and a proximal skirt of the balloon is sealed about and secured to the catheter shaft by a proximal fusion bond at a point proximal to the distal fusion bond. Alternatively, the balloon may be formed from the same tubing as the catheter shaft with the distal skirt of the balloon sealed about and secured to the distal end of an inner tubular member of the catheter by a single fusion bond.
A compatibilizing agent is provided between the shaft and balloon which facilitates the laser bonding of the balloon to the shaft. Even if the shaft and balloon are made of dissimilar polymeric materials which normally are not capable of being fusion bonded together, a fluid tight fusion bond can be created by selecting the compatibilizing agent that generates sufficient miscibility between the two dissimilar polymer materials so that an effective fusion bond can be formed between the two. The shaft and balloon are bonded together when heat is applied which is sufficient to melt the opposed surfaces with the compatibilizing agent present between the two members. The melted materials are subsequently allowed to cool down and solidify into a fusion bond containing the compatibilizing material.
The compatibilizing agent must be in intimate contact with both the balloon and shaft surfaces for the fusion bond to form. In one presently preferred embodiment, well known extrusion techniques are used to form a polymer compatibilizer as a short cylindrical collar configured to be slidingly received within the annular interface between the catheter shaft and balloon. Alternatively, the compatibilizing agent can be in a solution which is solvent cast onto the surface of the catheter shaft and/or balloon using conventional techniques for applying solutions to surfaces, such as spraying, dipping or painting, or the compatibilizing agent may be added as an integral co-component of one or both of the catheter parts.
The compatibilizing agent, which is the compatibilizing material prior to fusion bonding, melts along with the balloon and shaft surfaces during fusion bonding. After cooling, the fusion bond is formed which contains balloon, shaft, and compatibilizing material intimately intermixed with no remaining compatibilizing agent independent of the shaft and balloon material. The compatibizing agent interface with the balloon and shaft surfaces is fused to each of the balloon and shaft. A balloon-compatibilizer-shaft interface is thereby created by the fusion bond which results in a fused molten polymer interface.
The polymer compatibilizing agent may be used alone or in combination with a surface treatment of one or both of the opposed surfaces to provide improved miscibility with the compatibilizing agent. In accordance with one embodiment of the invention, the surface treatment consists of a plasma treatment applied to either the surface of the balloon, the surface of the shaft, or both. A suitable plasma treatment is achieve

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