Ex Parte Schwarz

Patent Trial and Appeal BoardNov 1, 2012

10934844 (P.T.A.B. Nov. 1, 2012)

UNITED STATES PATENT AND TRADEMARK OFFICE UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www.uspto.gov APPLICATION NO. FILING DATE FIRST NAMED INVENTOR ATTORNEY DOCKET NO. CONFIRMATION NO. 10/934,844 09/03/2004 Marlene C. Schwarz 03-578 (4010/86) 5936 27774 7590 11/01/2012 MAYER & WILLIAMS PC 251 NORTH AVENUE WEST Suite 201 WESTFIELD, NJ 07090 EXAMINER HELM, CARALYNNE E ART UNIT PAPER NUMBER 1615 MAIL DATE DELIVERY MODE 11/01/2012 PAPER Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE PATENT TRIAL AND APPEAL BOARD __________ Ex parte MARLENE C. SCHWARZ __________ Appeal 2011-011404 Application 10/934,844 Technology Center 1600 __________ Before FRANCISCO C. PRATS, MELANIE L. McCOLLUM, and JEFFREY N. FREDMAN, Administrative Patent Judges. McCOLLUM, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims to a therapeutic-agent-releasing medical device. The Examiner has rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. STATEMENT OF THE CASE The Specification discloses “a medical device that comprises a rate controlling release region and a therapeutic agent” (Spec. ¶ [0004]). In particular, the Specification discloses: The release region comprises a biodisintegrable agent (which can correspond, for example, to a therapeutic agent or to a non- Appeal 2011-011404 Application 10/934,844 2 therapeutic agent) and a biostable low Tg polymer. Upon contact of the medical device with a subject (e.g., upon implantation or insertion of the device), the release region becomes depleted, at least at its surface, with respect to the biodisintegrable agent. The low Tg polymer selected naturally migrates, at body temperature, to occupy at least a portion of the volume that is created by the departure of the biodisintegrable agent from the surface. This migration, or consolidation, creates a rate controlling membrane/barrier for therapeutic agent remaining within the device. (Id.) The Specification also discloses that a “„low Tg polymer‟ is a polymer which displays a glass transition temperature (Tg) . . . that is below ambient temperature, more typically below 25°C, 0°C, -25°C, or even -50°C (id. at ¶ [0015]). Claims 1, 5-7, 11-15, 17, 18, 20, 21, 24, 25, 28, and 29 are on appeal (App. Br. 2). 1 The claims have not been argued separately and therefore stand or fall together. 37 C.F.R. § 41.37(c)(1)(vii). Claim 1 is representative and reads as follows: 1. A therapeutic-agent-releasing medical device comprising a rate controlling release region that comprises a biodisintegrable agent and a biostable low glass transition temperature polymer having a glass transition temperature below -50°C, which is selected from alkylene homopolymers and acrylate homopolymers, wherein upon contact of said medical device with a subject, the release region becomes depleted with respect to the biodisintegrable agent, and the low glass transition temperature polymer migrates to occupy at least a portion of the volume that is created by the departure of the biodisintegrable agent, thereby forming a barrier layer for therapeutic agent remaining within the device, wherein said medical device is a stent. 1 Claims 2-4, 8, 10, 16, 19, and 26 are also pending but have been withdrawn from consideration (App. Br. 2). Appeal 2011-011404 Application 10/934,844 3 Claims 1, 5-7, 11-15, 17, 18, 20, 21, 24, 25, 28, and 29 stand rejected under 35 U.S.C. § 103(a) as obvious over Eury 2 in view of Berg, 3 Fearnot, 4 and Kamath, 5 as evidenced by Jiang 6 (Ans. 4). 7 The Examiner relies on Eury for teaching “a coating with a therapeutic containing polymeric material for an intravascular stent,” specifically, “a multi-layered coating that comprises a polymer, in combination with a porosigen (biodisintegrable agent) that dissolves or degrades when in contact with body fluids” (id. at 4-5). The Examiner finds that Eury teaches “that the preferred means of combining the polymer, porosigen, and therapeutic agent is via extrusion” and “that the polymers utilized have a relatively low processing temperature and name[s] 40 o C, 80 o C, and 100 o C as qualifying temperatures” (id. at 5). In particular, the Examiner finds that “[p]oly(caprolactone), polyorthoesters, polyimino- carbonates, polyphosphazenes, poly(L-lactic acid), and poly(DL-lactic acid) are exemplified polymers” and that “[p]olymers other than those explicitly named are also envisioned . . . as long as they are able to be processed at low temperature” (id.). The Examiner relies on Berg for teaching “stents with a drug containing polymeric coating” and that “[p]oly(caprolactone), 2 Eury et al., US 5,605,696, Feb. 25, 1997. 3 Berg et al., US 7,419,696 B2, Sep. 2, 2008. 4 Fearnot et al., US 5,609,629, Mar. 11, 1997. 5 Kamath et al., US 6,335,029 B1, Jan. 1, 2002. 6 C.-Y. Jiang et al., The Use of Model Polyisobutylene Networks to Study Strain-Induced Crystallization, 11 POLYMER BULLETIN 319-324 (1984). 7 Claims 9, 22, and 23 are also listed as rejected (Ans. 4). However, these claims were canceled (App. Br. 2). Appeal 2011-011404 Application 10/934,844 4 polyorthoesters, polyiminocarbonates, polyphosphazenes, poly(L-lactic acid), poly(DL-lactic acid), as well as polyisobutylene are named as suitable polymers for such a coating” (id. at 6). The Examiner relies on Jiang as evidence “that polyisobutylene has a melting temperature of 5 o C” (id.). The Examiner relies on Fearnot and Kamath for teaching features of dependent claims (id.). The Examiner finds: Since polyisobutylene melts at 5 o C, it would have been able to be processed by an extruder at a temperature considered low by Eury et al. (e.g. 100 o C or less). Berg et al. demonstrate that the polymers exemplified by Eury et al. function in the same drug delivery capacity as polyisobutylene. It then would have been obvious to one of ordinary skill in the art at the time of the invention to select polyisobutylene as a low processing temperature polymer for the coatings of Eury et al. since it was functionally equivalent to those exemplified and met their processing requirements. (Id. at 6-7.) The Examiner also finds: “Appellant identifies polyisobutylene as a polymer with a glass transition temperature below -50 o C. . . . Since the polyisobutylene and the biodisintegrable agent (porosigen) are the same as that claimed, they must have the same properties (e.g. ability to migrate and occupy volume left by departure of biodisintegrable agent).” (Id. at 7.) FINDINGS OF FACT 1. Eury discloses “a polymeric material containing a therapeutic drug, for application to a thin reinforcement or structural member of [a] stent on at least one side, for carrying and releasing the therapeutic drug” (Eury, col. 2, ll. 7-11). Appeal 2011-011404 Application 10/934,844 5 2. Eury also discloses that the “polymer coating can be formed to include pores or to contain a material which will dissolve or degrade to form pores in the polymeric material” (id. at col. 2, ll. 16-18). 3. In addition, Eury discloses: In a preferred aspect of the method of the invention, the polymeric material in which the therapeutic drug is incorporated has a relatively low processing temperature, such as polycaprolactone, having a processing temperature of approximately 80° C., poly(ethylene-co-vinyl acetate) or poly(vinyl acetate), having processing temperatures of approximately 100° C., or silicone gum rubber,,having a processing temperature of about 40° C., for example. Other polymers having similar relatively low processing temperatures may also be suitable. Other polymers which may be suitable include non-degradable polymers capable of carrying and delivering therapeutic drugs, and biodegradable, bioabsorbable polymers capable of carrying and delivering therapeutic drugs, such as poly-DL-lactic acid (DL-PLA), and poly-L-lactic acid (L-PLA), polyorthoesters, polyiminocarbonates, aliphatic polycarbonates, and polyphosphazenes. (Id. at col. 4, ll. 37-54 (emphasis added).) 4. Berg discloses a medical device, particularly a stent, coated with an overlayer, wherein the “overlayer, typically in the form of a porous polymer, is in intimate contact with [a] therapeutic agent and allows [the therapeutic agent] to be retained on the medical device” (Berg, col. 12, ll. 31-42). 5. Berg also discloses: In order to provide the coated stent . . . , a solution which includes a solvent, a polymer dissolved in the solvent and a therapeutic substance dispersed in the solvent is first prepared. . . . The solution is applied to the stent and the solvent is Appeal 2011-011404 Application 10/934,844 6 allowed to evaporate, thereby leaving on the stent surface a coating of the polymer and the therapeutic substance. (Id. at col. 12, l. 63, to col. 13, l. 28.) 6. In addition, Berg discloses: The polymer chosen must be a polymer that is biocompatible and minimizes irritation to the vessel wall when the stent is implanted. The polymer may be either a biostable or a bioabsorbable polymer depending on the desired rate of release or the desired degree of polymer stability. . . . Bioabsorbable polymers that could be used include poly(L-lactic acid), polycaprolactone, . . . polyorthoester, . . . poly(D,L-lactic acid), . . . poly(iminocarbonate), . . . [and] polyphosphazenes. . . . Also, biostable polymers with a relatively low chronic tissue response such as . . . silicones . . . could be used and other polymers could also be used if they can be dissolved and cured or polymerized on the stent such as . . . polyisobutylene[;] . . . polyvinyl esters, such as polyvinyl acetate; [and] copolymers of vinyl monomers with each other and olefins, such as . . . ethylene-vinyl acetate copolymers. (Id. at col. 13, l. 42, to col. 14, l. 8 (emphasis added).) 7. Polyisobutylene has a Tg of -73°C (Spec. ¶ [0025] & ¶ [0019]). 8. Noting that polyisobutylene melts at 5°C (Jiang 320), the Examiner finds that “it would have been able to be processed by an extruder at a temperature considered low by Eury et al. (e.g. 100 o C or less)” (Ans. 6). ANALYSIS In view of the foregoing findings of fact, we conclude that the Examiner has set forth a prima facie case that it would have been obvious to use polyisobutylene, as disclosed in Berg, as the polymeric material of Eury and that the resulting product would meet the requirements of claim 1. “The combination of familiar elements according to known methods is likely to be Appeal 2011-011404 Application 10/934,844 7 obvious when it does no more than yield predictable results.” KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 416 (2007). Appellant argues, however, that, unlike the processing temperatures taught in Eury, the “melting temperature of polyisobutylene (5°C) given in Jiang . . . is below room and body temperature and thus quantitatively different from those of Eury et al., at least for medical device applications” (App. Br. 4). Relying of Oppanol, 8 Appellant also argues “that the ability of polyisobutylene to naturally migrate at body temperature can be readily appreciated from the fact that polyisobutylene is commonly used in making chewing gum” (id.). Thus, Appellant argues: It would be utterly counterintuitive for one of skill in the art to take a device like that of Eury et al., where pores are made using a porosigen to create a porous membrane, and then modify that device to create a device like that claimed in which the polymer migrates to occupy at least a portion of the volume that is created by the departure of the biodisintegrable agent, thereby forming a barrier layer for therapeutic agent remaining within the device. In other words, the modification of Eury et al. proposed by the Examiner would result in a device in which the porous membrane desired by Eury et al. would be destroyed by polymer migration and barrier formation. (Id. at 4-5.) We are not persuaded. “An assertion of what seems to follow from common experience is just attorney argument and not the kind of factual evidence that is required to rebut a prima facie case of obviousness.” In re Geisler, 116 F.3d 1465, 1470 (Fed. Cir. 1997). Here, Appellant presents attorney argument indicating that it would be “counterintuitive” to use polyisobutylene in Eury‟s stent coating 8 BASF, OPPANOL® POLYISOBUTYLENES PIB FOR CHEWING GUM (© 2007). Appeal 2011-011404 Application 10/934,844 8 (App. Br. 4). However, we conclude that Appellant has not provided sufficient evidence to support this position. Appellant does refer to Oppanol, which states that “BASF‟s Oppanol® Polyisobutylenes are excellent gum base ingredients because they are . . . [, among other things, c]hewable even at low temperatures.” However, even if we assume that Oppanol is prior art, we do not agree that this evidence is sufficient to demonstrate that it would not have been obvious to use polyisobutylene, as described in Berg, in Eury‟s stent coating. Moreover, the Examiner finds: Berg . . . explicitly teach[es] polyethylene as a polymer that is particularly well suited as a porous coating on their implantable medical device (see column 3 line 62). The most agreed upon value for the glass transition temperature of polyethylene as tabulated by the Polymer Handbook 9 is -125 o C while that for polyisobutylene is -73 o C. (Ans. 9.) Given this, the Examiner concludes that “there is no reason why the artisan of ordinary skill in the art would conclude that a polyisobutylene coating in Eury et al. would yield an inferior or less suitable porous coating upon implantation due to its low glass transition temperature or ability to migrate as appellant asserts” (id. at 10). Appellant has not adequately explained why this position is in error. CONCLUSION The preponderance of evidence on this record supports the Examiner‟s conclusion that representative claim 1 would have been obvious. We therefore affirm the obviousness rejection. 9 POLYMER HANDBOOK 206 (J. Brandrup et al. eds., 4th ed. 1999). Appeal 2011-011404 Application 10/934,844 9 TIME PERIOD FOR RESPONSE No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a). AFFIRMED alw