10981098 (P.T.A.B. Feb. 25, 2013)

Ex Parte Couvillon et al

Patent Trial and Appeal BoardFeb 25, 2013

10981098 (P.T.A.B. Feb. 25, 2013)

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. 10/981,098 11/04/2004 Lucien Alfred Couvillon JR. 02-204US02 (4010/34C1) 7138 106953 7590 02/25/2013 Mayer & Williams 251 North Avenue West Suite 201 Westfield, NJ 07090 EXAMINER GRAY, PHILLIP A ART UNIT PAPER NUMBER 3767 MAIL DATE DELIVERY MODE 02/25/2013 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 LUCIEN ALFRED COUVILLON JR., PETE M. NICHOLAS, and MICHAEL S. BANIK __________ Appeal 2011-002820 Application 10/981,098 Technology Center 3700 __________ Before TONI R. SCHEINER, JEFFREY N. FREDMAN, and STEPHEN WALSH, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims to a drug delivery pump. The Examiner rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. Appeal 2011-002820 Application 10/981,098 2 Statement of the Case Background “The present invention is directed to novel implantable infusion pumps in which electroactive polymer actuators are used to express medication from a medication reservoir within the pump” (Spec. 3 ¶ 0008). The Claims Claims 1-19, 26, and 27 are on appeal. Independent claim 1 is representative and reads as follows: 1. A drug delivery pump apparatus comprising: (a) a contractible and expandable enclosure having an interior volume defining a medication reservoir; (b) an electroactive polymer actuator comprising a conducting polymer, said electroactive polymer actuator reducing said interior volume of said contractible and expandable enclosure upon contraction of said electroactive polymer actuator based upon received control signals; (c) a medication outlet port providing fluid communication between said interior volume of said contractible and expandable enclosure and an exterior of said delivery pump apparatus; and (d) a control unit electrically coupled to said actuator and sending said control signals to said actuator. The issues A. The Examiner rejected claims 1-14, 17-19, 26, and 27 under 35 U.S.C. § 103(a) as obvious over Kriesel1 and Adolf2 (Ans. 4-6). B. The Examiner rejected claims 15 and 16 under 35 U.S.C. § 103(a) as obvious over Kriesel, Adolf, and Flaherty3 (Ans. 6-7). 1 Kriesel et al., US 6,416,495 B1, issued Jul. 9, 2002. 2 Adolf et al., US 5,250,167, issued Oct. 5, 1993. 3 Flaherty et al., US 6,723,072 B2, issued Apr. 20, 2004. Appeal 2011-002820 Application 10/981,098 3 A. U.S.C. § 103(a) over Kriesel and Adolf The Examiner finds that “Kriesel discloses the claimed invention except for the polymeric actuator which contraction causes a contraction/reduction of a reservoir (bellows)” (Ans. 4). The Examiner finds that “Adolf teaches that it is known to use a polymeric actuator which contraction causes a contraction/reduction of a reservoir (bellows)” (Ans. 4). The Examiner finds it obvious to modify the system as taught by Kriesel with use a polymeric actuator which contraction causes a contraction/reduction of a reservoir (bellows)as taught by Adolf, since such a modification would provide the system with use a polymeric actuator which contraction causes a contraction/reduction of a reservoir (bellows)for providing suitable alternate designs of equivalent polymeric actuators and to provide a gel actuated device demonstrating compactness, simplicity, and low material costs, while providing a synthetic muscle (Ans. 5). The issue with respect to this rejection is: Does the evidence of record support the Examiner’s conclusion that Kriesel and Adolf render claim 1 obvious? Findings of Fact 1. Kriesel teaches “an implantable fluid delivery apparatus that can be used for the precise infusion of various pharmaceutical fluids into the patient at controlled rates over extended periods of time” (Kriesel, col. 2, ll. 35-38). 2. Kriesel teaches that “fluid reservoir 44, which contains the medicinal fluid ‘F’ to be delivered to the patient, is defined by an Appeal 2011-002820 Application 10/981,098 4 expandable component, here provided as a first expandable bellows 46” (Kriesel, col. 5, ll. 39-42). 3. Kriesel teaches that “bellows 46 is movable between the expanded configuration . . . and the collapsed configuration” (Kriesel, col. 5, ll. 42-44). 4. Figure 4 of Kriesel is reproduced below: FIG. 4 is a cross-sectional view of the medicament delivery device. 5. Kriesel teaches that “signals can be delivered to the CPU/electric controller 112 of the implanted device to accomplish, among other things, the energization of heater foil 72. Upon energizing the heater foil 72, the expandable gel 70 will expand . . . causing fluid to be Appeal 2011-002820 Application 10/981,098 5 controllably expelled from the device via the infusion means” (Kriesel, col. 13, ll. 38-42). 6. Kriesel teaches that “[e]xpansion of the first stored energy means causes bellows 50 to expand . . . and concomitantly causes capture housing 48 to slide upwardly . . . This upward movement of capture housing 48 causes bellows 46 to collapse . . . As bellows 46 collapses, the fluid contained therein is forced outwardly of the fluid reservoir through an outlet port 56” (Kriesel, col. 6, ll. 3-10). 7. Kriesel teaches stimulating a “first stored energy source, which here comprises an expandable mass 70” so that when “power is supplied to heater foil 72 via leads 72a, the heater foil will be heated so as to controllably heat expandable mass 70 to a predetermined, substantially constant elevated temperature to enable appropriate expansion thereof” (Kriesel, col. 6, ll. 19-30). 8. Kriesel teaches regarding “the novel expandable mass 70, this mass is here provided in the form of a polymeric gel . . . Polymeric gels best suited for use in constructing the heat expandable mass of the present invention are gels which undergo a change in polymer conformation and in so doing exhibit a large volume change at a given phase-transition condition” (Kriesel, col. 6, ll. 33-52). 9. Kriesel teaches that “when such gels experience certain environmental changes, the entire gel, or a component thereof will undergo a reversible volumetric change which typically involves a shift between two equilibrium states as, for example, expanded and collapsed” (Kriesel, col. 7, ll. 39-43). Appeal 2011-002820 Application 10/981,098 6 10. Kriesel teaches that “[g]els particularly well suited for use as the stored energy sources of the present invention include various types of so called ferrogels that respond reversibly to a magnetic field” (Kriesel, col. 9, ll. 49-51). 11. Kriesel teaches that a “ferrogel can respond to a magnetic stimuli by either elongating (growing in length) or contracting (shortening in length). . . . the placement of the applied magnetic field relative to the ferrogel determines whether a contraction or elongation is observed” (Kriesel, col. 10, ll. 22-27). 12. Adolf teaches “employment of polyelectrolyte polymeric gels in electrolytic solutions contained in flexible containers and selectively subjecting them to electrical potentials to induce desired expansion or contraction so as to act as an actuator” (Adolf, col. 7, ll. 49-52). 13. Adolf teaches that “[u]pon application of an electrical potential from power source 116, polymer gel sheets 114 in the vicinity of inner wall 102 [sic 104] swell resulting in a sphincter type action opening of annular gel actuator 100” (Adolf, col. 5, ll. 30-34). 14. Adolf teaches that “[u]pon removal of electrical potential, the cation-rich polymeric gel sheets contract to their original configuration resulting in the closing of the annular polymeric gel actuator 100. Proper actuation of a series of such annular actuators can result in a peristaltic pump action” (Adolf, col. 5, ll. 34-39). 15. Figures 4 and 4a of Adolf are reproduced below: Appeal 2011-002820 Application 10/981,098 7 “FIG. 4 is a view in perspective of another embodiment of the invention wherein the encapsulated polymeric gel actuator is capable of a sphinctering action. FIG. 4a is a plan view of the gel actuator of FIG. 4” (Adolf, col. 3, ll. 26-30). 16. Adolf teaches “an alternative annular actuator structure . . . Upon application of electric potential to electrodes 108 and 110, gel elements 116 and 118 contract against inner wall 104, closing the annulus. Upon removal of electrical potential, gel elements then expand allowing the annulus to open” (Adolf, col. 5, ll. 40-50). 17. Adolf teaches “gel actuated devices demonstrating compactness, simplicity, modest weight, small power requirements, and low material costs” (Adolf, col. 2, ll. 41-44). Principles of Law “The combination of familiar elements according to known methods is likely to be obvious when it does no more than yield predictable results.” KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 416 (2007). “If a person of ordinary skill can implement a predictable variation, § 103 likely bars its patentability.” Id. at 417. Appeal 2011-002820 Application 10/981,098 8 Analysis Kriesel teaches a drug delivery pump apparatus (FF 1) comprising: a) a “fluid reservoir 44, which contains the medicinal fluid ‘F’ to be delivered to the patient, is defined by an expandable component, here provided as a first expandable bellows 46” (Kriesel, col. 5, ll. 39-42; FF 2). Kriesel teaches that “bellows 46 is movable between the expanded configuration . . . and the collapsed configuration” (Kriesel, col. 5, ll. 42-44; FF 3). b) Kriesel teaches regarding “the novel expandable mass 70, this mass is here provided in the form of a polymeric gel” (Kriesel, col. 6, ll. 33-34; FF 8). c) Kriesel teaches that as “bellows 46 collapses, the fluid contained therein is forced outwardly of the fluid reservoir through an outlet port 56” (Kriesel, col. 6, ll. 8-10; FF 6). d) Kriesel teaches that “signals can be delivered to the CPU/electric controller 112 of the implanted device to accomplish, among other things, the energization of heater foil 72. Upon energizing the heater foil 72, the expandable gel 70 will expand . . . causing fluid to be controllably expelled from the device via the infusion means” (Kriesel, col. 13, ll. 38-42; FF 5). While Kriesel teaches the use of a polymeric gel to reduce the interior volume of a contractible and expandable enclosure based on control signals (FF 2, 3, 5, 6), Kriesel does not teach contraction of an electroactive polymer as the actuator polymer. Adolf teaches the use of the expansion and contraction of electroactive polymers as actuators (FF 12). Adolf teaches that “[p]roper Appeal 2011-002820 Application 10/981,098 9 actuation of a series of such annular actuators can result in a peristaltic pump action” (Adolf, col. 5, ll. 34-39; FF 14). Adolf teaches an embodiment where “[u]pon application of electric potential to electrodes 108 and 110, gel elements 116 and 118 contract against inner wall 104, closing the annulus” (Adolf, col. 5, ll. 40-50; FF 16). Applying the KSR standard of obviousness to the findings of fact, we conclude that the person of ordinary skill would have reasonably substituted Adolf’s electroactive polymer (FF 12) as a known equivalent of the heat expandable or ferrogel polymers of Kriesel (FF 7, 10, 11). Kriesel recognizes the use of multiple gel types (FF9) and Adolf provides a reason to select the electroactive polymers teaching that “gel actuated devices demonstrating compactness, simplicity, modest weight, small power requirements, and low material costs” (Adolf, col. 2, ll. 41-44; FF 17). Such a combination is merely a “predictable use of prior art elements according to their established functions.” KSR, 550 U.S. at 417. Appellants contend that “it is quite clear that Adolf does not show a polymer actuator that reduces the interior volume of a reservoir or enclosure upon its contraction, as required by claim 1 of the present invention” (App. Br. 5). We are not persuaded. Adolf teaches that the electroactive polymer can contract to reduce an enclosure. Specifically, Adolf teaches an embodiment where “[u]pon application of electric potential to electrodes 108 and 110, gel elements 116 and 118 contract against inner wall 104, closing the annulus” (Adolf, col. 5, ll. 40-50; FF 16). In this embodiment, the contraction of the gel elements closes the annulus. If the same gel elements Appeal 2011-002820 Application 10/981,098 10 were placed in the device of Kriesel, then the ordinary artisan would have recognized that contraction of the gel elements would have functioned to reduce the interior volume of an enclosure, and served as the actuator in the pump/bellows of Kreisel (FF 6, 16). Conclusion of Law The evidence of record supports the Examiner’s conclusion that Kriesel and Adolf render claim 1 obvious. B. 35 U.S.C. § 103(a) over Kriesel, Adolf, and Flaherty The Examiner finds that “Flaherty teaches that it is known to use a wireless power transmission interface and battery” (Ans. 6). The Examiner finds it obvious to “modify the fluid delivery device as taught by Kriesel with a wireless power transmission interface and battery as taught by Flaherty, since such a modification would provide the fluid delivery device with a wireless power transmission interface and battery for providing a smaller, light-weight, easy-to-use device for delivering liquid medicines to a patient remotely” (Ans. 6-7). The Examiner provides sound fact-based reasoning for combining Flaherty with Kriesel and Adolf. We adopt the fact finding and analysis of the Examiner as our own. Appellants do not separately argue this rejection. Therefore, consistent with the rejection which we affirmed above, we affirm this rejection for the reasons stated by the Examiner. Appeal 2011-002820 Application 10/981,098 11 SUMMARY In summary, we affirm the rejection of claim 1 under 35 U.S.C. § 103(a) as obvious over Kriesel and Adolf. Pursuant to 37 C.F.R. § 41.37(c)(1), we also affirm the rejection of claims 2-14, 17-19, 26, and 27 as these claims were not argued separately. We affirm the rejection of claims 15 and 16 under 35 U.S.C. § 103(a) as obvious over Kriesel, Adolf, and Flaherty. 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 lp