Method of forming a co-extruded balloon for medical purposes

Abstract
A method of forming a balloon for medical purposes including co-extruding in a tubular shape a base structural layer of polyamides, polycarbonates, polyesters and copolymers thereof and a heat sealable layer of polyethylene and copolymers thereof. The tubular member is then biaxially oriented by inflating the tube with a gas to a predetermined central diameter greater then the initial diameter of the tube and simultaneously heating the inflated tube to a temperature sufficient to biaxially orient the base structural layer. The member is then cooled the inflated tubular member and then elevated in temperature for a second time to the biaxially orienting temperature. The twice-heated tube is allowed to cool and the gas is withdrawn whereby the tubular member will assume a generally tubular shape and the main structural layer will remain biaxially orientated and the heat sealable layer will not be biaxially orientated.
Description

BACKGROUND OF THE INVENTION
The present invention relates to balloons for medical devices and medical devices utilizing such balloons. More particularly, the present invention relates; to medical or surgical balloons and catheters using such balloons, particularly those designed for angioplasty, valvuloplasty and urological uses and the like. The balloons of the present invention can be tailored to have expansion properties which are desired for a particular use and can be inflated to a predetermined diameter and still be resistant to the formation of pin holes and leakage.
DESCRIPTION OF THE PRIOR ART
In the past, polyethylene, polyethylene terephthalate and polyamide balloons have been used with medical catheters. Polyethylene balloons are particularly advantageous because they can be heat bonded to a like-material substrate and have a relatively low tip diameter, that is the profile of the tip at the connecting joint between the balloon and the catheter can be fairly small. Also, the polyethylene balloons are soft so that they can pass through blood vessels without trauma. Moreover, polyethylene balloons are resistant to the propagation of pin holes, primarily because the walls are thick. But since they are thick, they are large and pass by tight lesions only with great difficulty.
Balloons of polyethylene terephthalate provide low deflated profiles and can have thin walls because such materials have high tensile strengths and adequate burst strength. On the other hand, polyethylene teraphthalate balloons require adhesives to bond them to the catheters and adhesive bonding frequently is not dependable and it thickens the catheter at the point of the bond. Moreover, polyethylene teraphthalate can have poor pin hole resistance largely due to the very thin walls.
SUMMARY OF THE INVENTION
According to the present invention I have found a balloon for medical purposes can be formed by co-extruding in a tubular shape a base structural layer of a polyamide, a polycarbonate, a polyester, or copolymers thereof together with a heat-sealable layer of polyethylene and copolymers thereof. The base structural layer is biaxially oriented by inflating the tube with a gas to a predetermined central diameter that is greater than the initial diameter of the tubular shape while simultaneously heating the inflated tube to a temperature that is sufficient to biaxially orient the base structural layer. The heated tube is then cooled and elevated in temperature again to a biaxially orienting temperature. Then, the twice heated tube is allowed to cool and the gas is withdrawn so that the tubular member will assume a generally tubular shape and the main structural layer will remain biaxially oriented and the heat-sealable layer will not be biaxially oriented.
According to the present invention, it has been discovered that the drawbacks of the polyethylene and the polyethylene teraphthalate balloons of the prior art can be remedied through the use of laminated balloon constructions which comprise a tubular body formed of a plurality of co-extruded and coextensive layers of different polymeric materials.
According to one aspect of the invention, the multi-layered balloon combines the advantages of both materials in a balloon, but does not have the disadvantages of either. The balloon includes a layer of a relatively thick, biaxially oriented ethylenic polymeric material such as polyesters, polycarbonates, polyethylene teraphthalate and their copolymers, or polyamides such as Nylon. These materials constitute a base structural layer (or layers) and give the balloon its tensile strength and provide for "wear" resistance. The base structural layer may have a thickness between about 0.2 and 1.0 mil. or higher. A second layer is co-extruded with the base structural layer and is coextensive therewith. The second layer preferably is a polyolefin such as polyethylene and copolymers thereof and can be heat-bonded to a catheter, that is adhesives need not be used. The heat bondable second layer can be disposed on one and preferably both sides of the base structural layer.
In accordance with another aspect of the present invention, the base structural layer again is a material that does not itself readily thermally bond to a polyethylene catheter tubing. In those cases, sleeves of mutually bondable materials are slipped over the joints between the catheter and the balloon and the sleeves are heated to join the balloon to the sleeve and simultaneously join the sleeve to the catheter whereby to act as a fluid-tight seal between the catheter and the balloon.
With regard to multilayered balloons, the second layer (or layers) which is disposed on the base structural layer and co-extruded therewith can also serve as a barrier between the base structural layer and the environment. For example, when a polyamide such as Nylon is used as the base structural layer, a thin layer of maleic anhydride-modified ethylenic polymers such as Plexar can also be co-extruded with it. When layers are disposed on both sides of the base structural layer they keep moisture from effecting the Nylon's properties. Additional layers sometimes may also be co-extruded to bind and tie dissimilar layers together in the co-extrusion operation. When Nylon is used, for example, no tying layers are necessary between it and the heat bondable layer. In other cases, however, as when polyester or polycarbonate polymers are used as the base structural layer, adhesion enhancement may be necessary. Such adhesive enhancement may take the form of ultraviolet light irradiation of the product or the incorporation of a co-extruded tying adhesive layer.
With regard to the use of a multilayered sleeve to join the balloon to the catheter, any conventional medical balloon material can be used that does not bond to the catheter without adhesives. The multilayered sleeve can be formed of a base layer of the same material as the balloon with a polyethylene layer disposed on at least the inner side of the sleeve. The polyethylene will adhere to both the catheter and the balloon and form a joint with heat treatment alone.
According to the present invention, the balloons have advantages of both the polyethylene and the materials of the base structural layer. When polyethylene teraphthalate is the base, very thin walls can be used with high burst strength. For example, when a typical 3.0 mm. diameter maleic anhydride-modified ethylenic polymer is coated on a Nylon base structural layer, the resulting balloon can have a wall thickness of 0.5 mil. and a low deflated profile which is comparable with polyethylene terephthalate balloons and is much lower than polyethylene balloons. When using Nylon, the material that is used is biaxially orientable and has higher tensile strength than polyethylene material, thereby resulting in a much thinner wall for comparative burst strength.
It has been found that pin hole resistance of the construction of the present invention is comparable to polyethylene and substantially superior to polyethylene terephthalate. A balloon co-extruded with Selar has superior abrasion resistance and pin hole resistance then polyethylene terephthalate balloons. Polyamide material is superior to polyethylene terephthalate and polyethylene materials in pin hole resistance. The balloon itself is soft for non-traumatic passage through blood vessels and is comparable to polyethylene because polyamide is not as stiff as polyethylene terephthalate.
In a specific embodiment of a multilayered extruded balloon, it has been found that the use of the above mentioned Selar PT resin, a trademarked compound (preferably available as Selar PT 4368 from E.I. Dupont de Nemaurs Co. of Wilmington, Del.) as a layer disposed on the base structural layer (or blended with polyethylene terephthalate) will make the balloon more resistant to abrasion and provide it with a softer feel. Selar co-extrusion in multi-layered balloons diminishes pin hole formation and will minimize failure when working with calcified lesions. Moreover, the Selar may be used as the inner layer of the balloon for use with procedures which include internal electrodes or radiopaque markers which could puncture it.





BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side elevational view of a catheter with a multi-layered balloon. The balloon is :shown in the distended condition;
FIG. 2 is a view of the same catheter in the folded condition;
FIG. 3 is a cross-sectional view of the balloon of the present invention taken along the line 3--3 of FIG. 1 showing the polymeric layers in the balloon;
FIG. 4 is a cross-sectional view taken along the line 4--4 of FIG. 2 showing the balloon in its folded condition.
FIG. 5 is a cross sectional view of a distended balloon disposed at the end of a catheter and joined to the catheter by a sleeve.





DESCRIPTION OF THE PREFERRED EMBODIMENTS
An illustrative catheter 1 is shown in FIGS. 1 and 2. Catheter 1 includes a catheter tube 3 having a proximal end 5, a distal end 6 and a tip 7. A distended coextruded medical balloon 8 of the present invention is shown in FIG. 1 secured to the outside of the distal end 6 and the tip 7, the co-extrusion being critical to the present invention. The interior of the balloon 8 is in communication with at least one lumen (not shown in this Figure) of the catheter tube 3. To form the tip 7 (and the portion of the catheter between the distal end 6 and the tip 7 to support the balloon 8) a portion of the catheter tube 3 is cut away so that only the lumen that houses an internal guide wire 14 remains (as shown in dotted lines within the balloon 8).
Extending through the interior of the tube 3 are a plurality of lumens (shown in FIGS. 3 and 4) which can serve a variety of functions, for example, housing the guide wire 14, inserting materials into the blood stream or inflating or deflating the balloon. Except for the balloon 8, all of the various components perform functions which are generally appreciated and known in the art.
To use, the catheter 1 (as shown in FIG. 2) is inserted into the cardiovascular system until the co-extruded balloon 8 is located at the site of an occlusion. At this stage, the balloon 8 is typically folded and collapsed and has an external diameter less than the inflated diameter, as can be seen by a comparison of FIGS. 1 and 2. Once the balloon 8 is maneuvered to the location of the occlusion, a pressurizing fluid is inserted at the proximal end 5 of the catheter tube 3 for inflation of the balloon 8. The fluid unfolds the balloon 8 until it presents a relatively smooth expanded profile for imparting forces that are radially outwardly directed at the desired site within the body in order to achieve the desired result of lesion dilation, restriction reduction or similar treatment.
Inserting the catheter 1 in an artery requires that the tube 3 be of a semi-flexible material. Tube 3 preferably is composed of a polyolefin copolymer, for example a conventional high density polyethylene. The diameter of the tubing is between about 12 and 16 French and may be coated on the inside and outside surfaces with, for example, a silicone based material to promote slippage in an aqueous environment.
As seen in FIGS. 3 and 4, the co-extruded balloon 8 results in a laminated construction. The laminates of the construction include a main structural layer 8B which is generally between about 0.2 and 2.5 mil. or thicker, and formed of one or more biaxially oriented polymers such as polyamides, polyesters, polycarbonates and their copolymers. Co-extruded with and bonded to the structural layer 8B is an inner layer 8C of heat bondable polyolefin such as Plexar. Plexar is an anhydride-modified polyethylene and a trademarked product sold by Quantum Chemical Corporation of Cincinnati, Ohio. The heat bondable layer 8C is attached directly to the distal end 6 of catheter tube 3 and is secured to the balloon 8 by a heat seal joint 11. A similar joint 11 is formed between the balloon 8 and the catheter tip 7.
The heat bondable layer 8C is co-extruded with the structural layer 8B and has a thickness of between about 0.5 and 1.0 mil. Preferably, two heat bondable layers are co-extruded with the structural layer 8B. The inner layer 8B serves as a mechanism to provide a heat seal joint 10 between the distal end 6 of the catheter tube 3 and the structural layer 8B of the balloon 8. When two layers are co-extruded with the structural layer 8B, the inner layer 8C forms the heat bondable layer and the outer layer 8A forms a protective sheath for the main structural layer 8B. When polyamides such as Nylon are used as the structural layer 8B, Plexar can be used as the heat bonding layer 8C. The outer layer 8A can be formed of the same material and provide for softness for non-traumatic passing through vessels and good pin hole resistance.
An alternative to the construction shown in FIG. 1, another construction is to dispose a balloon formed of a base structural layer 8B of polyethylene terephthalate and an outer layer 8A of polyethylene around the distal end 6 of the catheter tube 3 and then place a sleeve 20 formed of heat bonding layer 20C of high density polyethylene on a base layer 20B of Nylon over the end of the balloon 8 whereby the polyethylene of the balloon seals to the polyethylene of the sleeve and the Nylon seals to the catheter 3. In cases where additional strength is needed, an innermost layer can be formed of high density polyethylene and an outermost layer is formed of Nylon with Plexar sandwiched therebetween.
It has been found that where strength, abrasion resistance and/or "feel" are important in medical balloons, that a co-extrusion which includes Selar resin can be used to provide for these characteristics. The Selar can be used by itself as the inner and/or outer layer or it can be blended with polyethylene terephthalate. Tests of a 1.6 mil. thick balloon with a Selar outer layer (a 50/50 blend of Selar and polyethylene terephthalate) were conducted by rubbing a balloon inflated to 6 atm. and rubbing it back and forth over medium grade emery cloth until failure.
The balloons with Selar or 50/50 blend layers exceeded 200 cycles while a 1.8 mil. thick polyethylene terephthalate balloon failed in 87 cycles. Selar is a toughened grade of polyethylene terephthalate and it can be co-extruded with the base structural layers herein disclosed according to known techniques.
Referring to FIGS. 3 and 4, the interior of the co-extruded balloon 8 is shown in cross section. In FIG. 3, the balloon is shown in its distended or inflated condition whereas in FIG. 4 the balloon is shown in its deflated or folded condition. The balloon 8 can typically have an outer diameter that can be on the order of roughly three to six and even more times the outer diameter of the catheter tube 3. Pressurized fluids used to inflate the balloon include those conventionally used in the art, such as the well known aqueous solutions if they do not pose a problem of leaving residual fluids or chemically reacting with the balloon. Such fluids are introduced into the balloon 8 and removed therefrom through a lumen L.sup.1 which is in fluid flow relationship with the interior thereof. Venting of gasses initially trapped in the catheter and the balloon prior to introduction of the inflation fluids is accomplished by expelling them through a second lumen L.sup.2 also formed in the interior of the catheter tube 3. Preferably, lumen L.sup.1 and L.sup.2 are cut off at joint 10 so as to leave only a third lumen L.sup.3.
The third lumen L.sup.3 houses a guide wire 14 that passes through the balloon 8 and the tip 7. The third lumen L.sup.3 is different then the other two lumens, L.sup.1 and L.sup.2, in that it extends entirely through the balloon 8 from the distal end 6 to the tip 7 so as to sheath the guide wire. In some embodiments, it may be desirable to combine the functions of lumens, L.sup.1 and L.sup.2, to only have a single lumen for inflating or deflating the balloon. Lastly, the lumen defined by L.sup.3 provides for a housing for a guide wire 14 which is removably housed in it. Guide wire 14 passes through the entire length of the catheter 3 and through the balloon 8 (while preferably sheathed in lumen L.sup.3) and thence into an axial bore (not shown) in tip 7 to emerge from the end of tip 7 (as shown in FIGS. 2 and 3).
Each of the lumens L.sup.1, L.sup.2 and L.sup.3 is formed by walls 15 and 16 that are extruded as the catheter tube is extruded from an extrusion machine, as is well known in the art. The thickness of the walls 15 and 16 can be between 0.5 and 10 mil., as is well known.
As shown in FIG. 4, the diameter of the folded balloon 8 is substantially the same or less than the diameter of the catheter tube 3 so as to provide for easy passage of the catheter through blood vessels. The extruded tubing 3 has a nominal wall thickness that generally is on the order of six to twelve times the desired wall thickness of the balloon 8.
To form the co-extruded balloons, the materials initially are melted separately in extrusion machines. When melted, the materials are separately forced into an extrusion head and extruded so that they are forced out as a plurality of layers in the form of a single tube which critically forms the balloon of the present invention. A Nylon-Plexar or polyethylene-polyethylene terephthalate balloon may be formed by taking a six inch Length of the three layered tubing which is to be manufactured into a balloon and placing it in a holding fixture. The left hand end of the tube is attached to a Touhy Borst adapter. The right hand end of the tube is heat sealed to temporarily prevent pressurized air from escaping. The right hand end is attached to a tension line which is pulled for the force of a least 150 grams (for a 3.0 mm. diameter balloon). The tubing is heated under a pressure of between about 100 and 400 psi to about 210.degree. F. for several seconds. Afterwards, the heated area is cooled and the support frame is spread apart slightly so as to expose a pre-determined section of tubing to permit the balloon area to be reheated to a temperature between about 210.degree. and 220.degree. F. to permit the balloon to be expanded to a desired diameter under pressure for about 35 seconds. The pressure is then stopped and the deflectors are slid to the ends of the balloon and the balloon is heated for a third time to about 310.degree. F. to heat set the balloon and biaxially orient the polymeric matrix. This third heating prevents the balloon layers from flaking and prevents the balloon from expanding beyond the size at which it will set during the heat setting period. The heat setting takes about 8 seconds.
For a Nylon-Plexar balloon, the deflectors from the tubes are then removed and another unheated tube is mounted into the fixture. The catheter tube is slid inside the balloon so that it engages the heat bondable polyethylene layer. The balloon is bonded to the polyethylene shaft by heat bonding in a temperature of about 310.degree. F. which is long enough to the melt the polyethylene end and the inner layer of the polyethylene together.
It is quite important to recognize that the heat treatment steps as described herein essentially prevent the delamination of the heat bondable layers 8C and 8A from the main structural layer 8B as is required when a laminated construction is used as a catheter. Flaking and delamination is not a problem, however, with polyethylene terephthalate and Selar layers.
While it is apparent that modifications and changes may be made within the spirit and scope of the present invention, it is intended, however, only to be limited by the scope of the appended claims.
Claims
  • 1. A method of manufacturing a medical catheter, the method comprising:
  • coextruding a first layer and a second layer to form a tube having an outside diameter, said first layer comprised of polyethylene terephthalate and said second layer comprised of a material selected from the group consisting of Nylon and polyethylene terephthalate;
  • simultaneously pressurizing and heating at least a region of said tube to inflate said region to an outer diameter greater than said outside diameter of said tube;
  • forming a balloon for medical purposes from said inflated region of said tube;
  • providing a catheter shaft having at least one lumen disposed therethrough; and
  • attaching said balloon to said catheter shaft so that said at least one lumen is in fluid communication with an interior region of said balloon.
  • 2. The method recited in claim 1 wherein said coextruding step comprises coextruding three layers to form the coextruded tube.
  • 3. The method recited in claim 1 wherein said first layer has a composition different than that of said second layer.
  • 4. The method recited in claim 1 further comprising the step of heat setting said inflated region of said tube.
  • 5. The method recited in claim 1 wherein said first layer comprises a toughened grade of polyethylene terephthalate.
  • 6. The method recited in claim 3 wherein the second layer is comprised of polyethylene terephthalate.
  • 7. The method recited in claim 6 wherein the second layer is polyethylene terephthalate.
  • 8. The method recited in claim 1, wherein the first layer comprises a blend of polyethylene terephthalate and another material.
  • 9. The method recited in claim 1, wherein the first layer is disposed radially outside the second layer.
  • 10. The method recited in claim 9, wherein the first layer comprises a blend of polyethylene terephthalate and another material and the second layer is polyethylene terephthalate.
RELATION TO OTHER APPLICATIONS

This is a continuation of application Ser. No. 08/013,340, filed Feb. 4, 1993, now abandoned, which is a division of application, Ser. No. 07/691,999, filed Apr. 26, 1991, now U.S. Pat. No. 5,195,969.

US Referenced Citations (328)
Number Name Date Kind
RE33561 Levy Mar 1991
1643289 Peglay Sep 1927
1690995 Pratt Nov 1928
2499045 Walker et al. Feb 1950
2548602 Greenburg Apr 1951
2616429 Merenlender Nov 1952
2688329 Wallace Sep 1954
2690595 Raiche Oct 1954
2799273 Oddo Jul 1957
2823421 Scarlett Feb 1958
2936760 Gants May 1960
2981254 Vanderbilt Apr 1961
3045677 Wallace Jul 1962
3053257 Birtwell Sep 1962
3141912 Goldman et al. Jul 1964
3173418 Baran Mar 1965
3292627 Harautuneian Dec 1966
3304353 Harautuneian Feb 1967
3348542 Jackson Oct 1967
3426744 Ball Feb 1969
3432591 Heffelfinger Mar 1969
3539674 Dereniuk et al. Nov 1970
3543758 McWhorter Dec 1970
3543759 McWhorter Dec 1970
3561493 Maillard Feb 1971
3562352 Nyilas Feb 1971
3618614 Flynn Nov 1971
3707146 Cook et al. Dec 1972
3707151 Jackson Dec 1972
3731692 Goodyear May 1973
3733309 Wyeth et al. May 1973
3745150 Corsover Jul 1973
3769984 Muench Nov 1973
3771527 Ruisi Nov 1973
3799172 Szpur Mar 1974
3807408 Summers Apr 1974
3814137 Martinez Jun 1974
3833004 Vazquez et al. Sep 1974
3837347 Tower Sep 1974
3861972 Glover et al. Jan 1975
3889685 Miller, Jr. et al. Jun 1975
3924634 Taylor et al. Dec 1975
3959426 Seefluth May 1976
3962519 Rusch et al. Jun 1976
3996938 Clark, III Dec 1976
4011189 Keil Mar 1977
4035534 Nyberg Jul 1977
4047868 Kudo et al. Sep 1977
4061707 Nohtomi et al. Dec 1977
4079850 Suzuki et al. Mar 1978
4085757 Pevsner Apr 1978
4105022 Antoshkiw et al. Aug 1978
4140126 Choudhury Feb 1979
4141364 Schultze Feb 1979
4144298 Lee Mar 1979
4174783 Abe et al. Nov 1979
4182457 Yamada Jan 1980
4183102 Guiset Jan 1980
4195637 Gruntzig et al. Apr 1980
4198981 Sinnreich Apr 1980
4211741 Ostoich Jul 1980
4213461 Pevsner Jul 1980
4222384 Birtwell Sep 1980
4233022 Brady et al. Nov 1980
4238443 Levy Dec 1980
4244914 Ranalli et al. Jan 1981
4251305 Becker et al. Feb 1981
4256789 Suzuki et al. Mar 1981
4261339 Hanson et al. Apr 1981
4263188 Hampton et al. Apr 1981
4265276 Hatada et al. May 1981
4265848 Rusch May 1981
4271839 Fogarty et al. Jun 1981
4282876 Flynn Aug 1981
4292974 Fogarty et al. Oct 1981
4296156 Lustig et al. Oct 1981
4299226 Banka Nov 1981
4300550 Gandi et al. Nov 1981
4301053 Wolfrey Nov 1981
4306998 Wenzel et al. Dec 1981
4318947 Joung Mar 1982
4323071 Simpson et al. Apr 1982
4324262 Hall Apr 1982
4326532 Hammar Apr 1982
4327736 Inoue May 1982
4330497 Agdanowski May 1982
4335723 Patel Jun 1982
4338942 Fogarty Jul 1982
4346698 Hanson et al. Aug 1982
4351341 Goldberg et al. Sep 1982
4378803 Takagi et al. Apr 1983
4385089 Bonnebat May 1983
4403612 Fogarty Sep 1983
4406656 Hattler et al. Sep 1983
4411055 Simpson et al. Oct 1983
4413989 Schjeldahl et al. Nov 1983
4417576 Baran Nov 1983
4422447 Schiff Dec 1983
4423725 Baran et al. Jan 1984
4424242 Barbee Jan 1984
4434797 Silander Mar 1984
4439394 Appleyard Mar 1984
4444188 Bazell et al. Apr 1984
4451256 Weikl et al. May 1984
4456011 Warnecke Jun 1984
4472129 Siard Sep 1984
4479497 Fogarty et al. Oct 1984
4484971 Wang Nov 1984
4490421 Levy Dec 1984
4497074 Rey et al. Feb 1985
4521564 Solomon et al. Jun 1985
4531997 Johnston Jul 1985
4540404 Wolvek Sep 1985
4551292 Fletcher et al. Nov 1985
4553545 Maass et al. Nov 1985
4559951 Dahl et al. Dec 1985
4572186 Gould et al. Feb 1986
4573470 Samson et al. Mar 1986
4573966 Weikl et al. Mar 1986
4576142 Schiff Mar 1986
4576772 Carpenter Mar 1986
4578024 Sicka et al. Mar 1986
4579879 Flynn Apr 1986
4581390 Flynn Apr 1986
4582762 Onohara et al. Apr 1986
4585000 Hershenson Apr 1986
4596563 Pande Jun 1986
4606347 Fogarty et al. Aug 1986
4608984 Fogarty Sep 1986
4610662 Weikl et al. Sep 1986
4613517 Williams et al. Sep 1986
4614188 Bazell et al. Sep 1986
4627436 Leckrone Dec 1986
4627844 Schmitt Dec 1986
4634615 Versteegh et al. Jan 1987
4636346 Gold et al. Jan 1987
4636442 Beavers et al. Jan 1987
4637396 Cook Jan 1987
4638805 Powell Jan 1987
4640852 Ossian Feb 1987
4642267 Creasy et al. Feb 1987
4648871 Jacob Mar 1987
4650466 Luther Mar 1987
4651721 Mikulich et al. Mar 1987
4655745 Corbett Apr 1987
4655771 Wallsten Apr 1987
4656070 Nyberg et al. Apr 1987
4657024 Coneys Apr 1987
4660560 Klein Apr 1987
4664657 Williamitis et al. May 1987
4666437 Lambert May 1987
4677017 DeAntonis et al. Jun 1987
4681564 Landreneau Jul 1987
4684363 Ari et al. Aug 1987
4685447 Iversen et al. Aug 1987
4685458 Leckrone Aug 1987
4686124 Onohara et al. Aug 1987
4693243 Buras Sep 1987
4699611 Bowden Oct 1987
4702252 Brooks et al. Oct 1987
4705502 Patel Nov 1987
4705517 DiPesa, Jr. Nov 1987
4705709 Vailancourt Nov 1987
4706670 Andersen et al. Nov 1987
4710181 Fuqua Dec 1987
4723936 Buchbinder et al. Feb 1988
4729914 Kliment et al. Mar 1988
4732152 Wallsten et al. Mar 1988
4737219 Taller et al. Apr 1988
4743257 Tormala et al. May 1988
4744366 Jang May 1988
4751924 Hammerschmidt et al. Jun 1988
4753765 Pande Jun 1988
4762129 Bonzel Aug 1988
4762130 Fogarty et al. Aug 1988
4762589 Akiyama et al. Aug 1988
4763653 Rockey Aug 1988
4771776 Powell et al. Sep 1988
4771778 Mar Sep 1988
4775371 Mueller, Jr. Oct 1988
4776337 Palmaz Oct 1988
4786556 Hu et al. Nov 1988
4787388 Hofmann Nov 1988
4790831 Skribiski Dec 1988
4795458 Regan Jan 1989
4796629 Grayzel Jan 1989
4800882 Gianturco Jan 1989
4801297 Mueller Jan 1989
4803035 Kresge et al. Feb 1989
4807626 McGirr Feb 1989
4810543 Gould et al. Mar 1989
4811737 Rydell Mar 1989
4814231 Onohara et al. Mar 1989
4816339 Tu et al. Mar 1989
4818592 Ossian Apr 1989
4819751 Shimada et al. Apr 1989
4820349 Saab Apr 1989
4821722 Miller et al. Apr 1989
4824618 Strum et al. Apr 1989
4834702 Rocco May 1989
4834721 Onohara et al. May 1989
4838876 Wong et al. Jun 1989
4840623 Quackenbush Jun 1989
4846812 Walker et al. Jul 1989
4856516 Hillstead Aug 1989
4857393 Kato et al. Aug 1989
4863426 Ferragamo et al. Sep 1989
4868044 Tanaka et al. Sep 1989
4869263 Segal et al. Sep 1989
4871094 Gall et al. Oct 1989
4878495 Grayzel Nov 1989
4880682 Hazelton et al. Nov 1989
4886062 Wiktor Dec 1989
4896669 Bhate et al. Jan 1990
4898591 Jang et al. Feb 1990
4900303 Lemelson Feb 1990
4906237 Johansson et al. Mar 1990
4906241 Noddin et al. Mar 1990
4906244 Pinchuk et al. Mar 1990
4909252 Goldberger Mar 1990
4913701 Tower Apr 1990
4921479 Grayzel May 1990
4921483 Wijay et al. May 1990
4923450 Maeda et al. May 1990
4932956 Reddy et al. Jun 1990
4932958 Reddy et al. Jun 1990
4933178 Capelli Jun 1990
4934999 Bader Jun 1990
4938676 Jackowski Jul 1990
4941877 Montano, Jr. Jul 1990
4946464 Pevsner Aug 1990
4950227 Savin et al. Aug 1990
4950239 Gahara et al. Aug 1990
4952357 Euteneuer Aug 1990
4954126 Wallsten Sep 1990
4960410 Pinchuk Oct 1990
4963306 Weldon Oct 1990
4963313 Noddin et al. Oct 1990
4964853 Sugiyama et al. Oct 1990
4973301 Nissenkorn Nov 1990
4986830 Owens et al. Jan 1991
4994033 Shockey et al. Feb 1991
4994047 Walker et al. Feb 1991
4994072 Bhate et al. Feb 1991
4995868 Brazier Feb 1991
5000734 Boussignac et al. Mar 1991
5002531 Bonzel Mar 1991
5002556 Ishida et al. Mar 1991
5006119 Acker et al. Apr 1991
5015231 Keith et al. May 1991
5017325 Jackowski et al. May 1991
5026607 Kiezulas Jun 1991
5035694 Kasprzyk et al. Jul 1991
5037392 Hillstead Aug 1991
5041089 Muelier et al. Aug 1991
5041100 Rowland et al. Aug 1991
5041125 Montano, Jr. Aug 1991
5042985 Elliott et al. Aug 1991
5049132 Shaffer et al. Sep 1991
5057092 Webster, Jr. Oct 1991
5057106 Kasevich et al. Oct 1991
5059269 Hu et al. Oct 1991
5061424 Karimi et al. Oct 1991
5071406 Jang Dec 1991
5071686 Genske et al. Dec 1991
5074840 Yoon Dec 1991
5074845 Miraki et al. Dec 1991
5075152 Tsukuda et al. Dec 1991
5077352 Elton Dec 1991
5078702 Pomeranz Jan 1992
5084315 Karimi et al. Jan 1992
5087244 Wolinsky et al. Feb 1992
5087246 Smith Feb 1992
5090958 Sahota Feb 1992
5091205 Fan Feb 1992
5094799 Takashige et al. Mar 1992
5100381 Burns Mar 1992
5100721 Akao Mar 1992
5100992 Cohn et al. Mar 1992
5102416 Rock Apr 1992
5108415 Pinchuk et al. Apr 1992
5108420 Marks Apr 1992
5114423 Kasprzyk et al. May 1992
5116318 Hillstead May 1992
5125913 Quackenbush Jun 1992
5137512 Burns et al. Aug 1992
5147302 Euteneuer et al. Sep 1992
5156857 Wang et al. Oct 1992
5160321 Sahota Nov 1992
5163949 Bonutti Nov 1992
5171221 Samson Dec 1992
5176697 Hasson et al. Jan 1993
5179174 Elton Jan 1993
5183613 Edwards Feb 1993
5195970 Gahara Mar 1993
5195972 Inoue Mar 1993
5201706 Noguchi et al. Apr 1993
5209728 Kraus et al. May 1993
5223205 Jackowski et al. Jun 1993
5226880 Martin Jul 1993
5248305 Zdrahala Sep 1993
5254090 Lombardi et al. Oct 1993
5254091 Aliahmad et al. Oct 1993
5263962 Johnson et al. Nov 1993
5270086 Hamlin Dec 1993
5272012 Opolski Dec 1993
5277199 DuBois et al. Jan 1994
5279560 Morrill et al. Jan 1994
5279594 Jackson Jan 1994
5290306 Trotta et al. Mar 1994
5304171 Gregory et al. Apr 1994
5304197 Pinchuk Apr 1994
5306246 Sahatjian et al. Apr 1994
5312356 Engelson et al. May 1994
5318041 DuBois et al. Jun 1994
5318587 Davey Jun 1994
5330428 Wang et al. Jul 1994
5330429 Noguchi et al. Jul 1994
5334146 Ozasa Aug 1994
5342307 Euteneuer et al. Aug 1994
5344401 Radisch et al. Sep 1994
5358486 Saab Oct 1994
5364357 Aase Nov 1994
5366472 Hillstead Nov 1994
5372603 Acker et al. Dec 1994
5413559 Sirhan May 1995
5417671 Jackson May 1995
5509899 Fan et al. Apr 1996
Foreign Referenced Citations (55)
Number Date Country
0 101 216 A2 Feb 1984 EPX
0 166 998 Jan 1986 EPX
0 174 206 A2 Mar 1986 EPX
0 201 331 A2 Nov 1986 EPX
0 214 721 A1 Mar 1987 EPX
0 266 957 A2 May 1988 EPX
274411 Jul 1988 EPX
0 276 908 A1 Aug 1988 EPX
0 292 587 A1 Nov 1988 EPX
0 303 487 A2 Feb 1989 EPX
0 329 041 A2 Aug 1989 EPX
0 357 562 Mar 1990 EPX
0 358 445 A2 Mar 1990 EPX
0 359 489 A2 Mar 1990 EPX
0 414 350 B1 Mar 1990 EPX
0 380 102 A1 Aug 1990 EPX
0 383 429 Aug 1990 EPX
0 399 712 A1 Nov 1990 EPX
0 419 291 A1 Mar 1991 EPX
0 420 488 A1 Apr 1991 EPX
0 428 479 A1 May 1991 EPX
0 439 202 A2 Jul 1991 EPX
0 457 456 A1 Nov 1991 EPX
0 461 474 A1 Dec 1991 EPX
998035 Jan 1952 FRX
2 328 482 May 1977 FRX
28 48 854 A1 May 1979 DEX
36 38 828 A1 May 1988 DEX
31 24 198 A1 Apr 1992 DEX
50-75256 Jun 1975 JPX
53-042256 Apr 1978 JPX
58-38778 Mar 1983 JPX
58-188463 Nov 1983 JPX
63-087219 Apr 1988 JPX
2-43036 Feb 1990 JPX
3-277374 Dec 1991 JPX
4-34590 Feb 1992 JPX
51-084877 Jul 1996 JPX
069826 Jan 1984 RUX
1477423 May 1989 RUX
693244 Jun 1953 GBX
1533204 Nov 1978 GBX
1556242 Nov 1979 GBX
1600963 Oct 1981 GBX
2 077 111 Dec 1981 GBX
2 078 114 Jan 1982 GBX
2130093 May 1984 GBX
2 140 437 Nov 1984 GBX
2 163 386 Feb 1986 GBX
2 209 121 May 1989 GBX
WO 8401327 Apr 1984 WOX
WO 9104068 Apr 1991 WOX
WO 9117788 Nov 1991 WOX
WO 9208512 May 1992 WOX
WO 9211893 Jul 1992 WOX
Non-Patent Literature Citations (57)
Entry
Paul, Polymer Blends, 1986.
Levy, J. Clinical Eng., 1986.
Article from Design Ovine Hoestche Celen USC, pp. 2-2, 3-1 to 3-4, 1991.
"Extruded Tubing is Called on to Perform More Complex and Critical Surgical Jobs", Modern Plastics International, pp. 40-41, 1990.
LeMay et al., "Pinhole Balloon Rupture of the Coronary Angioplasty Causing Rupture of the Coronary Artery", Catherization and Cardiovascular Diagnosis 19:91-92, 1990.
Davey, "Pleated Balloon Catheter", Biomedical Materials, Apr., 1991.
Chin et al., "Long-term Results of Intraoperative Balloon Dilatation", The Journal of Cardiovascular Surgery, 30:454-458, 1989.
Article from Plastics & Rubber Weekly, "Chemistry Advance Offers New Materials", p. 8, "One Piece Catheter", p. 8, Dec. 3, 1988.
"New Silicone-modified TPE Combined Best of Both Worlds", Biomedical Elastomers, pp. 28-30, Nov. 1988.
Article from Plastics World, "New Tie Layers Brighten Life for Coextruders", 46n, Jul. 7, 1988.
"Film Laminate Key to Record Setting Balloon Flight", Plastics Design Forum, pp. 66-68, Mar./Apr. 1988.
Mobley et al., "Effects of Organophosphorus Agents on Sarcoplasmic Reticulum in Skinned Skeletal Muscle Fibres", Toxicology and Applied Pharmacology, 94:407-413, 1988.
Carley, "A Plastics Primer", Modern Plastics Encyclopedia, pp. 4-8, 1988.
Shedd, Rader, Edenbaum et al., Willwerth et al., Gabbett, Peters, Tomanek et al., Clark, Modern Plastics Encyclopedia, pp. 93-109, 1988.
Woods, "Polyurethanes" and Torkelson "Silicones", Modern Plastics Encyclopedia, pp. 122-124, 1988.
Irwin, Belcher, Bruning and Suit, Modern Plastics Encyclopedia, pp. 203-210, 1988.
Reckner, "Testing by ASTM Methods", Modern Plastics Encyclopedia, pp. 318-320, 1988.
Wholey, "A Newly Designed Angioplasty Catheter: `The Gemini Balloon`", CardioVascular and Interventional Radiology, 11:42-44, 1988.
"Surface Analysis of Biomedical Materials and Devices--Part 1", Biomedical Polymers, vol. 4, No. 7, pp. 1-15, 1988.
"In Vivo Assessment of Vascular Dilatation During Percutaneous Transluminal Coronary Angioplasty", American Journal of Cardiology, 60:968-982, Nov., 1987.
Articles from Plastics Technology, "Multi-Lumen Medical Tubing Line" and "Satellite Extruders for Coextrusion", pp. 39-41, Aug., 1987.
M-D-D-I Reports, "Polymed's One-Step Balloon Catheter Manufacturing Process," p. 15, Mar. 16, 1987.
Elastomerics, EuroNews by Maurice Botwell, "DuPont Uses New Design Concepts To Boost TP Elastomers In Europe", pp. 38-39, Nov., 1986.
Simpfendorfer et al., "Balloon Rupture During Coronary Angioplasty", Journal of Vascular Disorders, vol. 37, No. 11, pp. 828-831, Nov., 1986.
Levy, "Improved Dilation Catheter Balloons", Journal of Clinical Energy, pp. 291-296, Jul./Aug. 1986.
Article from Plastics and Rubber International, "Medical Uses of Polymers", vol. 11, No. 3, Jun. 1986.
Jain et al., "Effects of Inflation Pressures on Coronary Angioplasty Balloons", American Journal of Cardiology, 57:26-28, Jan. 1, 1986.
Palmaz et al., "Expandable Intrahepatic Portacaval Shunt Stents: Early Experience in the Dog", AJR 145:821-825, Oct. 1985.
Palmaz et al., "Expandable Intraluminal Graft: A Preliminary Study", Radiology, vol. 156 No. 1, Jul. 1985.
Inoue, "A New Balloon Catheter for Percutaneous Transluminal Angioplasty", AJR 144:1069-1071, May 1985.
Giesy et al., "Coaxial and Linear Extrusion Balloon Catheters Compared to Guidewires . . . Urinary Tract", The Journal of Urology, vol. 133, No. 4, p. 238A, Apr. 1985.
Kinney et al., "Shear Force in Angioplasty: Its Relation to Catheter Design and Function", American Journal of Roentgenology, 144:115-122, Jan. 1985.
Letter from Modern Plastics, "Coextrusion Measurement by IR Sensors", Jun. 1984 14:8.
Giesy et al., Ureteral Access: Bypassing Impacted Stones . . . Balloon Catheter, The Journal of Urology, vol. 131, No. 4, 152A, 79th Annual Meeting of American Urological Association, Inc., May 6-10, 1984.
Giesy et al., "Coaxial Balloon Dilation and Calibration of Urethral Strictures", The American Journal of Surgery, 147:611-614, May 1984.
Fogarty et al., "Intraoperative Coronary Artery Balloon Catheter Dilatation", American Heart Journal vol. 107, No. 4, pp. 845-851, Apr., 1984.
Inoue et al., "Clinical Application of Transvenous Mitral Commissurotomy by a New Balloon Catheter", Journal of Thoracic and Cardiovascular Surgery, vol. 87, No. 3, pp. 394-402, Mar. 1984.
Kennedy et al., "Interventional Coronary Arteriography", Annual Review of Medicing: Selected Topics in the Clinical Sciences, 35:513-516, 1984.
Broad, "Plastics Revolution: A Rush of New Uses", The New York Times, Tuesday, Nov. 1, 1983.
"The Gamma Bottle", Food & Drug Packaging, vol. 47, No. 10, Oct. 1983.
"Award Caps Bottle's Introduction", USA Today, Friday, Oct. 7, 1983.
Forcinio, "Squeezable bottle ends long wait for ketchup", Food & Drug Packaging, vol. 47, No. 10, Oct. 1983.
"Rigid Plastics Are Getting a Foot in the Kitchen Door", Chemical Week, Oct. 12, 1983.
Kent et al., "Percutaneous Transluminal Coronary Angioplasty: Report From . . . Blood Institute", The American Journal of Cardiology, vol. 49, pp. 2011-2020, Jun. 1982.
Dobrin, "Balloon Embolectomy Catheters in Small Arteris, I Lateral Wall Pressures and Shear Forces", Surgery, vol. 90, No. 2, pp. 177-185, Aug. 1981.
Fogarty et al., "Adjunctive Intraoperative Arterial Dilation", Arch. Surg., 116:1381-1397, 1981.
Jekell et al., "Balloon Catheters", Acta Radiological Diagnosis, 21:47-52, 1980.
Katzen et al., "Percutaneous Transluminal Angioplasty With the Gruntzig Balloon Catheter", Arch Surg., vol. 114, No. 12, pp. 1389-1399, Jun. 1979.
Gruntzig et al., "Technique of Percutaneous Transluminal Anoplasty with the Gruntzig Balloon Catheter", American Journal of Roentgenology, vol. 132, No. 4, pp. 547-552, Apr. 1979.
Jensen, "Double-Lumen Balloon Catheter", Acta Radiological Diagnosis, 17:886-890, Nov. 1976.
Supplements to Circulation, An Official Journal of the American Heart Association, vols. 53 and 54, p. II-81, Jan.-Dec. 1976.
Radiology, vol. 115, No. 3, Jun. 1975.
Sweeting et al., "Auxiliary Film Treatments" & "Polyethylene Terephthalate Film Structure and Analysis", The Science and Technology of Polymer Films, vol. II John Wiley & Sons, Inc., pp. 639, 1971.
Adrova et al., "Polymides: A new Class of Heat-Resistant Polymers", Academy of Sciences of the USSR, Chapter 1, "Synthesis and Transformations of Polymides", pp. 1-36, 1969.
Fogarty, "The Balloon Catheter in Vascular Surgery", Review of Surgery, vol. 24, No. 1, pp. 9-19, 1967.
Encyclopedia of Polymer Science and Engineering, vol. 2, Biaxial Orientation, pp. 339-373.
Encyclopedia of Polymer Science and Engineering, vol. 2, Anionic Polymerization to Cationic Polymerization, p. 202; vol. 10, Molecular Weight . . . Polymers, pp. 619-636.
Divisions (1)
Number Date Country
Parent 691999 Apr 1991
Continuations (1)
Number Date Country
Parent 013340 Feb 1993