2020000021 (P.T.A.B. May. 4, 2020)

ALLERGAN, INC.

Patent Trials and Appeals BoardMay 4, 2020

2020000021 (P.T.A.B. May. 4, 2020)

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. 14/139,519 12/23/2013 Terrence J. Hunt 17859-CON2 (BOT) 7909 51957 7590 05/04/2020 ALLERGAN, INC. 2525 DUPONT DRIVE, T2-7H IRVINE, CA 92612-1599 EXAMINER LYONS, MARY M ART UNIT PAPER NUMBER 1645 NOTIFICATION DATE DELIVERY MODE 05/04/2020 ELECTRONIC 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. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address(es): blake.morgan@allergan.com pair_allergan@firsttofile.com patents_ip@allergan.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE PATENT TRIAL AND APPEAL BOARD __________ Ex parte TERRENCE J. HUNT __________ Appeal 2020-000021 Application1 14/139,519 Technology Center 1600 __________ Before ERIC B. GRIMES, RACHEL H. TOWNSEND, and CYNTHIA M. HARDMAN, Administrative Patent Judges. TOWNSEND, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims to a lyophilized or vacuum dried pharmaceutical composition, which claims have been rejected as obvious and for obviousness-type double patenting. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. STATEMENT OF THE CASE “For storage stability and convenience of handling, a pharmaceutical composition can be formulated as a lyophilized (i.e. freeze dried) or vacuum 1 We use the word “Appellant” to refer to “applicant” as defined in 37 C.F.R. § 1.42. Appellant identifies the real party in interest as Allergan, Inc. (Appeal Br. 3.) Appeal 2020-000021 Application 14/139,519 2 dried powder which can be reconstituted with a suitable fluid.” (Spec. 2.) Such compositions can include active ingredients that are proteins. (Id.) Stabilizing such active ingredients to minimize loss of biological activity in such a composition is important. (Id.) “Various excipients, such as albumin and gelatin have been used with differing degrees of success to try and stabilize a protein active ingredient present in a pharmaceutical composition.” (Id.) “[D]espite their known stabilizing effects, significant drawbacks exist to the use of protein excipients, such as albumin or gelatin, in a pharmaceutical composition.” (Id. at 4.) “Various proteins such as albumin and gelatin have been used to stabilize a botulinum toxin present in a pharmaceutical composition.” (Id. at 2.) The claimed invention relates to botulinum toxin pharmaceutical compositions stabilized with a non-protein excipient. (Id. at 21.) Claims 15, 24–26, and 30 are on appeal. Claim 15 is representative and reads as follows: 15. A lyophilized or vacuum dried pharmaceutical composition comprising: (a) a botulinum toxin, wherein the botulinum toxin is not stabilized by a protein excipient, (b) a poloxamer; and (c) a disaccharide selected from sucrose or trehalose. (Appeal Br. 41.) Appeal 2020-000021 Application 14/139,519 3 The prior art relied upon by the Examiner is: Name Reference Date Friedman et al. US 5,472,706 Dec. 5, 1995 Hunt US 2002/0064536 A1 May 30, 2002 Donovan US 2004/0086532 A1 May 6, 2004 K. Johnson, Preparation of peptide and protein powders for inhalation, 26 Adv. Drug Delivery Reviews, 3–15 (1997) J. Carpenter et al., Rationale Design of stable protein formulations-theory and practice: Rational Design Of Stable Lyophilized Protein Formulations: Theory And Practice, 109–133 (Carpenter and Manning eds. 2002). The following grounds of rejection by the Examiner are before us on review: Claims 15, 24–26, and 30 under 35 U.S.C. § 103(a) as unpatentable over Donovan, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 4–6 of U.S. Patent No. 8,642,047, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–2 of U.S. Patent No. 8,168,206, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–12 of U.S. Patent No. 8,137,677, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claim 1 of U.S. Patent No. 9,981,022, Johnson, Friedman, and Carpenter. Appeal 2020-000021 Application 14/139,519 4 Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claim 11 of U.S. Patent No. 9,044,477, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–3 of U.S. Patent No. 9,265,722, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–28 of U.S. Patent No. 7,419,676, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–9 of U.S. Patent No. 6,203,794, Johnson, Friedman, and Carpenter. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–16 of U.S. Patent No. 9,629,904, Johnson, Friedman, Carpenter, and Hunt. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–6 of U.S. Patent No. 8,580,250, Johnson, Friedman, Carpenter, and Hunt. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–5 of U.S. Patent No. 9,107,815, Johnson, Friedman, Carpenter, and Hunt. Claims 15, 24–26, and 30 on the ground of non-statutory obviousness- type double patenting as being unpatentable over claims 1–6 of U.S. Patent No. 8,323,666, Johnson, Friedman, Carpenter, and Hunt. Claims 15, 24–26, and 30 provisionally on the ground of non-statutory obviousness-type double patenting as being unpatentable over claims 20–41 Appeal 2020-000021 Application 14/139,519 5 and 43–46 of copending Application No. 13/427,582, Johnson, Friedman, and Carpenter.2 DISCUSSION Obviousness The Examiner finds that Donovan teaches a lyophilized pharmaceutical composition that includes a botulinum toxin complex “(e.g., see [0034-35, 0073, 0131-0135, 0144-0149)” where that “neurotoxin can be mixed with emulsifiers and stabilizing agents, including sucrose, (e.g. [0119, 0131, 0176–0177]. . .).” (Final Action 3–4.) The Examiner also finds that Donovan teaches “the compositions may be formulated for inhalation administration.” (Id. at 4 (citing Donovan ¶ 2).) The Examiner finds that Donovan does not disclose the use of poloxamer 188 as an emulsifier or trehalose as a stabilizing agent, but “does not require the composition be stabilized by a protein excipient.” (Id. at 4.) The Examiner notes, though, that Donovan does teach a suitable stabilizing agent is needed for use of the toxin at dilute nanogram per milliliter concentrations, as well as when the toxin is not used pharmaceutically until months or years after the composition with the toxin is formulated. (Ans. 36 (citing Donovan ¶ 36).) The Examiner finds three references concerning lyophilization of proteins teach or suggest the use of poloxamer 188 and trehalose or sucrose 2 Appellant does not argue the merits of this rejection, nor has a terminal disclaimer been filed to obviate the rejection. Therefore, we summarily affirm this rejection. Hyatt v. Dudas, 551 F.3d 1307, 1314 (Fed. Cir. 2008) (“When the appellant fails to contest a ground of rejection to the Board, . . . the Board may treat any argument with respect to that ground of rejection as waived.”). Appeal 2020-000021 Application 14/139,519 6 in the lyophilized composition of Donovan that includes botulinum toxin. (Id. at 4–6). In particular, the Examiner finds that Johnson teaches lyophilization is one of the most common and successful methods for stabilizing proteins and that poloxamer 188 and sucrose are glass forming excipients commonly used in that process with proteins. (Id. at 4) The Examiner also finds that Friedman teaches, in lyophilizing compositions that include neuromuscular blocking agents, essential components of the composition include emulsifiers and cryoprotectant stabilizers, and the emulsifier enhances the composition. (Id. at 4–5.) Poloxamer 188 is one such emulsifier set forth in Friedman. (Id. at 5.) The Examiner further finds that Friedman teaches that there are advantages to lyophilized submicron emulsions, including better stability for long term storage. (Id.) The Examiner finds that Carpenter teaches that there are “minimum criteria for successful lyophilization of a protein-containing pharmaceutical formulation [which] includes protection of the protein during freezing and drying; and a high glass transition temperature.” (Final Action 5.) The Examiner notes that Carpenter teaches formulators include sugars as cryoprotectant stabilizers, and that “the best choice for stabilizing proteins are sucrose and trehalose (e.g. page 117. . . ).” (Id.) Indeed, those sugars are noted to be preferred “for inhibiting lyophilization-induced protein unfolding and provide a glassy matrix with acceptably high glass transition temperatures (e.g. see page 113)” as well as for minimizing aggregation. (Id.) The Examiner concludes that, in light of the foregoing, it would have been obvious to modify the lyophilized “compositions comprising botulinum toxin, stabilizing excipients including sucrose, and emulsifiers, as taught by Appeal 2020-000021 Application 14/139,519 7 Donovan, by using stabilizing cryoprotectants, including sucrose and/or trehalose along with emulsifiers, including poloxamer 188” with a reasonable expectation of success as “each element performs the same function as it does individually.” (Id. at 5–6.) The Examiner explains that the reason to include poloxamer 188 along with sucrose and/or trehalose would have been to achieve a “stable, appropriately-sized, therapeutic composition, fit for human use.” (Id. at 6.) We agree with the Examiner’s conclusion of obviousness. In particular, we agree with the Examiner that Donovan does not require the stabilizing agent be a protein (Ans. 35), as will be addressed below. The Examiner contends that Donovan specifically teaches sucrose is a stabilizing agent for use in a composition of botulinum toxin that is to be lyophilized. The Examiner points to the following passage in Donovan to arrive at that conclusion: To stabilize a neurotoxin, both in a format which renders the neurotoxin useful for mixing with a suitable polymer which can form the oral formulation matrix (i.e. a powdered neurotoxin which has been freeze dried or lyophilized) as well as while the neurotoxin is present or incorporated into the matrix of the selected polymer, various pharmaceutical excipients can be used. Suitable excipients can include starch, cellulose, talc, glucose, lactose, sucrose, gelatin, malt, rice, flour, chalk, silica gel, magnesium stearate, sodium stearate, glycerol monostearate, sodium chloride, albumin and dried skim milk. The neurotoxin in a neurotoxin oral formulation can be mixed with excipients, bulking agents and stabilizing agents, and buffers to stabilize the neurotoxin during lyophilization or freeze drying. Appeal 2020-000021 Application 14/139,519 8 (Donovan ¶ 131; Final Action 43.) We agree with the Examiner that Donovan can be so interpreted. We conclude this portion of Donovan teaches that the lyophilized or freeze dried botulinum toxin used to make the oral formulation that includes a polymer matrix, can be stabilized by the addition of an excipient either (a) by addition of the stabilizing agents in formation of the lyophilized product or (b) after that lyophilized product is formed, or both. The stabilization is such that the toxin is stable for mixing with the polymer, and when incorporated into the matrix of the selected polymer. We do not read this paragraph to limit the list of suitable excipients to arrive at a stabilized neurotoxin to use only with a component that has already been lyophilized that is to then be mixed with polymer matrix, particularly because Donovan indicates that many different types of compounds can be used “to stabilize the neurotoxin during lyophilization or freeze drying,” namely “excipients, bulking agents and stabilizing agents, and buffers.” (Donovan ¶ 131.) We agree with Appellant (Appeal Br. 12) that Donovan teaches the necessity of diluting the toxin for use in a pharmaceutical composition, and that such dilution is known to “result [] in rapid detoxification of the toxin unless a suitable stabilizing agent is present.” (Donovan ¶ 36.) But we disagree with Appellant that because Donovan (a) describes albumin and gelatin as examples of such suitable stabilizing agents that can be used (Appeal Br. 12 (citing Donovan ¶ 36)), (b) refers to obtaining botulinum toxin type A using the Schantz process and “incorporates by reference” the 3 Although the Examiner also cites paragraphs 119 and 176–177, those paragraphs do not refer to specific stabilizing compounds. Appeal 2020-000021 Application 14/139,519 9 article4 describing that process (Appeal Br. 11–12), and (c) provides examples of using commercially available botulinum toxin, which is stabilized with a protein (id. at 14), that Donovan requires that the toxin to be used in its formulation is necessarily stabilized with a protein excipient. First, we agree with the Examiner that Schantz cited by Appellant (Appeal Br. 12; Ans. 37) discloses that human serum albumin use in lyophilized botulinum toxin “presents potential problems.” See Schantz 81. In particular, Schantz teaches that “[a]lthough the commercial botulinum type A product is prepared in the presence of human serum albumin, the use of human serum albumin presents potential problems in that certain stable viral agents carried through from donors could contaminate the toxin.” (Id.) Furthermore, Schantz teaches that loss of toxicity when storing a lyophilized botulinum toxin stabilized with human albumin is significant at pH 7.3 (i.e., neutral pH) and “research” to develop a medium and conditions to overcome losses on drying was being studied. (Id. at 83.) Furthermore, we agree with the Examiner (Ans. 36), that in describing known “stabilizing agents such as albumin and gelatin” (Donovan ¶ 36), Donovan was not limiting stabilization of botulinum toxin to only those agents, as evident by the use of the term “such as.” In fact, Donovan teaches that “[i]t has been discovered that a stabilized neurotoxin can comprise biologically active, non-aggregated neurotoxin complexed with at least one type of multivalent metal cation which has a val[e]ncy of +2 or more.” (Id. ¶ 132.) Donovan notes that “[a] preferred metal cation used to stabilize a 4 E. Schantz and E. Johnson, Properties and Use of Botulinum Toxin and Other Microbial Neurotoxins in Medicine, 56 Microbiological Reviews 80– 99 (1992). Appeal 2020-000021 Application 14/139,519 10 botulinum toxin is Zn++ because the botulinum toxin[s] are known to be zinc endopeptidases.” (Id. ¶ 135.)5 Donovan describes how the “[t]he suitability of a metal cation for stabilizing neurotoxin can be determined” with a number of “stability indicating techniques” including “potency tests on neurotoxin lyophilized particles containing metal cations to determine the potency of the neurotoxin after lyophilization and for duration of release from microparticles.” (Id. ¶ 136.) Donovan further explains: In stabilized neurotoxin, the tendency of neurotoxin to aggregate within a microparticle during hydration in vivo and/or to lose biological activity or potency due to hydration or due to the process of forming a sustained release composition, or due to the chemical characteristics of a sustained release composition, is reduced (Id.)6 The conditions for preparing such a stable toxin are described, including appropriate pH and suitable aqueous solvent and then lyophilizing to form particulates of stabilized neurotoxin. (Id. ¶¶ 144–149.)7 Consequently, we conclude that Donovan’s references to using a stabilized neurotoxin do not require that the neurotoxin be stabilized with a protein 5 We note that the Examiner relies on these cited paragraphs in the rejection. (See Final Action 3–4.) 6 Donovan also notes that “[i]t is known that a significant water content of lyophilized tetanus toxoid can cause solid phase aggregation and inactivation of the toxoid once encapsulated within microspheres.” (Id. ¶ 168.) Donovan explains that the manufacturing process for BOTOX® results in a freeze dried botulinum toxin type A complex which has a moisture content of less than about 3%, at which moisture level nominal solid phase aggregation can be expected. (Id.) 7 We note that the Examiner also relies on these cited paragraphs in the rejection. (See Final Action 4.) Appeal 2020-000021 Application 14/139,519 11 excipient, but do require the stabilization of a lyophilized neurotoxin such that loss of biological activity during hydration is reduced, as well as a reduction in the tendency of the neurotoxin to aggregate within a microparticle during hydration or due to the process of forming, or chemical characteristics of, a sustained release composition. Moreover, we agree with the Examiner that Johnson, Friedman, and Carpenter collectively teach or suggest the use of poloxamer 188 along with sucrose and/or trehalose, without the use of albumin, for obtaining a stable lyophilized botulinum toxin composition, which Donovan teaches can be used to make the controlled release oral formulation of botulinum toxin (Donovan ¶¶ 119, 142, 165). None of these references teach that a protein excipient is necessary to obtain a stabilized lyophilized macromolecule. And as discussed above, we conclude that Donovan does not require albumin or another protein stabilizer. Thus, we disagree with Appellant’s argument the “[t]he cited references are not combinable, as at least one of the cited references teaches away from the claimed composition.” (Appeal Br. 17–18.) Although Johnson is “a review of ‘formulations for delivering therapeutic aerosols to the lungs’” (Appeal Br. 15), and Donovan is primarily concerned with making a biodegradable botulinum toxin oral formulation (Donovan ¶ 169)8, Johnson is analogous art in that it recognizes 8 We disagree with the Examiner that Donovan teaches inhalation of its composition. The citation relied on by the Examiner for such a teaching (Donovan ¶ 2) mentions inhalation administration as one route of administration of pharmaceutical compositions generally, but proceeds thereafter to describe advantages of oral administration. Appeal 2020-000021 Application 14/139,519 12 the susceptibility of proteins to chemical and physical degradation in a formulation or during the manufacturing process, or even during storage, and provides information on common techniques used to stabilize these “macromolecules,” particularly when they “must be stabilized in the solid state.” (Johnson 7.) Johnson explains that “[o]ne of the most common” and a “successful technique” for stabilizing proteins in the solid state is lyophilization, which incorporates the protein into amorphous glasses, and lists ten excipients commonly used in stabilizing proteins in the solid state. (Id. (including Table 3).) Two of the commonly used compounds are surfactants, one being poloxamer 188, the other being polysorbate 80 (also known as TWEEN 80). (Id.) And two of them are carbohydrates, one being sucrose and the other lactose. (Id.) The list also includes two polyols, two amino acids, one chelating agent, and one protein. (Id.) Carpenter teaches that for rational design of stable lyophilized protein formulations there are “five criteria [that] define the minimal conditions necessary for a successful lyophilized protein formulation,” and provides “prototypic rational formulations . . . in Table 2.” (Carpenter 111, 117.) The first criterion of importance is inhibiting protein unfolding, which can lead to non-native aggregates, and the second is to ensure the glass transition temperature (Tg) exceeds the planned storage temperature, which is “essential for optimal protein stability.” (Id. at 111–13 and Table 1.) Carpenter discloses that “[a]ggregation can be minimized by including stabilizing excipients (e.g., sucrose or trehalose) in the formulation to inhibit lyophilization-induced unfolding” and further that “[f]ortunately, sucrose and trehalose, which are the preferred excipients for inhibiting lyophilization-induced protein unfolding. . . , also provide a glassy matrix Appeal 2020-000021 Application 14/139,519 13 with acceptably high Tg values.” (Id. at 112–13.) Carpenter further notes that “[f]rom a regulatory standpoint . . . the formulation scientist should choose from among excipients that are already used in approved parenteral products. For protein stabilizers, the best choices are the disaccharides, sucrose and trehalose,” especially where the protein is a “therapeutic protein.” (Id. at 117, 120.) Carpenter also notes that in the case where a “structurally perturbed protein molecule[]” might have arisen during lyophilization, “fostering refolding during rehydration (e.g., with surfactants) can reduce aggregation.” (Id. at 112.) Thus, inclusion of a nonionic surfactant to reduce protein aggregation, where aggregation is known to be an issue, is considered in addition to the use of trehalose or sucrose in rational lyophilized protein formulations. (Id. at 118 (Table 2).) From a regulatory standpoint, Carpenter indicates that “[f]or surfactants, usually the Tweens (20, 40 or 80) are preferred.” (Id. at 117.) The Examiner relies on Friedman for teaching “advantages of lyophilized submicron emulsions.” (Final Action 5.) We do not agree, because Friedman includes an oily component to make an oil-in-water emulsion, and because Friedman’s composition “are formulated for parenteral administration.” (See e.g., Friedman 2:31–42, 10:53–54.) We do not find the Examiner has established a prima facie case for the obviousness of such a lyophilized emulsion for the botulinum toxin used in Donovan that is combined with a polymer to make an oral formulation. Nevertheless, we rely on Friedman for its suggestion that poloxamer 188, like TWEEN and TYLOXAPOL, is compatible with neuromuscular blocking agents. (Id. at 5:12–29, 6:2–9.) Appeal 2020-000021 Application 14/139,519 14 In light of the foregoing, we agree with the Examiner that it would have been obvious to one having ordinary skill in the art to have selected sucrose and poloxamer 188 as excipients to aid in the stabilization of the botulinum toxin that is lyophilized and used in the Donovan oral formulation, without the need for a protein stabilizer. Donovan suggests that stabilization using a protein is not necessary as discussed above.9 Johnson provides a list of ten excipients for use in stabilizing proteins during lyophilization, and Carpenter provides two strong reasons to include a carbohydrate and a surfactant which are two categories of compounds in the Johnson list. “Reading a list [such as is provided in Johnson] and selecting a known compound to meet known requirements is no more ingenious than selecting the last piece to put into the last opening in a jig- saw puzzle. It is not invention.” Sinclair & Carroll Co. v. Interchemical Corp., 325 U.S. 327, 335 (1945); see also Merck & Co. Inc. v. Biocraft Laboratories, Inc., 874 F.2d 804, 807 (Fed. Cir. 1989). Indeed, in light of Carpenter’s teachings regarding the rational design of stable lyophilized protein formulations and the importance of preventing protein unfolding and non-native aggregation, and its teaching that nonionic surfactant and sucrose and trehalose are useful in that regard, we conclude that one of ordinary skill 9 Moreover, Schantz notes that there are potential contamination problems by stable viral agents carried through from donors associated with the use of human serum albumin as a stabilizing agent. (Schantz 81.) Although Schantz mentions stabilization of the neurotoxin with a protein being “required” (id.; Appeal Br. 12), that disclosure is limited to stabilization in liquid medium for long term storage, not with respect to a lyophilized botulinum neurotoxin. Schantz discloses that it was researching mediums and conditions to overcome toxicity losses on drying of toxin, such as by lyophilization. (Schantz at 83.) Appeal 2020-000021 Application 14/139,519 15 in the art “would have selected and combined th[e] prior art elements [in Table 3 of Johnson] in the normal course of research and development to yield the claimed invention” that includes sucrose and poloxamer 188 as excipients to stabilize the botulinum toxin taught for use in the oral composition of Donovan. Unigene Labs., Inc. v. Apotex, Inc., 655 F.3d 1352, 1360 (Fed. Cir. 2011). While it is true that Carpenter indicates that usually Tweens are preferred for the surfactant (Appeal Br. 16), Johnson provides another commonly used surfactant, one that Friedman teaches is also compatible with neurotoxins. Regarding the selection of poloxamer 188 over TWEEN from Johnson’s list, “[t]he prior art’s mere disclosure of more than one alternative does not constitute a teaching away from . . . alternatives because such disclosure does not criticize, discredit, or otherwise discourage the solution claimed.” In re Fulton, 391 F.3d 1195, 1201 (Fed. Cir. 2004). We conclude that the claimed excipients are no more than a combination of familiar elements yielding no more than predictable stabilization results. Such a combination is unpatentable for obviousness. KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 416 (2007). For the foregoing reasons, we do not agree with the Appellant that the Examiner has not established a rational underpinning to support the conclusion of obviousness (Appeal Br. 18–19). We thus affirm the Examiner’s rejection of claim 15 as being obvious over Donovan, Johnson, Friedman, and Carpenter. Claims 24–26 and 30 have not been argued separately and therefore fall with claim 15. 37 C.F.R. § 41.37(c)(1)(iv). Appeal 2020-000021 Application 14/139,519 16 II Non-Statutory Obviousness-type Double Patenting 1. Rejections relying on Johnson, Friedman, and Carpenter The Examiner contends that the claims on appeal are “not patentably distinct” from the claims identified in the ’047, ’206, ’677, ’022, ’477, ’722, ’676, and ’794 patents “because they are both drawn to substantially similar compositions comprising the same active ingredient, i.e., botulinum toxin, stabilized with commonly used non-protein ingredients.” (Final Action 16, 21, 24, 28, 32, 36, 38, 41.) In particular, the Examiner states with respect to each of the noted patents, that the toxin recited in those claims is a botulinum toxin (’047, ’677, ’022, ’477, ’722, ’676) (id. at 16, 25, 28, 32, 36, 38) or a genus of toxins that is defined to encompass botulinum toxins (’206, ’794) (id. at 21, 41), and that either (1) the toxin is required to not be stabilized by a protein excipient (’047, ’206, ’677 ) (id. at 16, 21, 25), or (2) the Examiner’s position relies on the fact that the claims of the patent do not positively recite the inclusion of a protein excipient (’022, ’477, ’722, ’676, ’794) (id. at 28–29, 32, 36, 38, 41). Regarding additional components in the compositions of the foregoing patents, the Examiner finds: a) Poloxamer and a dissacharide are included (’047) (id. at 16–17), b) A dissacharide and a non-protein polymer excipient are included (’206) (id. at 21), c) Lactose and polyvinylpyrrolidone are included (’677) (id. at 25), d) Trehalose and a thermo-reversible thermoplastic poloxamer are included (’022) (id. at 28–29), Appeal 2020-000021 Application 14/139,519 17 e) Cross-linked, polymeric, hyaluronic acid carrier is included (’477) (id. at 32), f) the toxin is encapsulated in a polymer matrix carrier (’722) (id. at 36), and g) the toxin is necessarily in a composition (’676) (id. at 38). In view of the foregoing, the Examiner concludes that with respect to the differences between the appealed claims and the patent claims that: 1) For the ’047 patent “the difference between the instant claims and the patent claims is lyophilization” but “lyophilizing a protein containing composition is prima facie obvious in view of the teachings of Johnson et al., Friedman et al., and Carpenter et al. for the same reasons as set forth [in the obviousness rejection discussed above].” (Final Action 17.) 2) For the ’206, ’677, ’477, ’676, and ’794 patents “the difference between the instant claims and the patent claims is lyophilization with the use of poloxamer 188 and trehalose” but “that lyophilizing a composition, including the use of commonly employed, non-protein, stabilizing excipients, emulsifiers, and/or cryoprotectants is prima facie obvious in view of the teachings of Johnson et al., Friedman et al., and Carpenter et al., for the same reasons set forth above.” (Id. at 21–22, 25, 32–33, 38–39, 41–42.) 3) For the ’022 patent “the difference between the instant claims and the patent claims is lyophilization with the use of poloxamer 188” but “that lyophilizing a composition, including the use of commonly employed, non- protein, stabilizing excipients, emulsifiers, and/or cryoprotectants is prima facie obvious in view of the teachings of Johnson et al., Friedman et al., and Carpenter et al., for the same reasons set forth above.” (Id. at 29.) Appeal 2020-000021 Application 14/139,519 18 4) For the ’722 patent “the difference between the instant claims and the patent claims is lyophilization with the use of poloxamer 188, sucrose and/or trehalose” but “that lyophilizing a composition, including the use of commonly employed, non-protein, stabilizing excipients, emulsifiers, and/or cryoprotectants is prima facie obvious in view of the teachings of Johnson et al., Friedman et al., and Carpenter et al., for the same reasons set forth above.” (Id. at 36.) Thus, in light of the foregoing, the Examiner concludes that “the claims are not patentably distinct as being obvious variants of the compositions in the patent claims.” (Id. at 17–18, 22, 26, 29, 33, 37, 39, 42.) We agree with the Examiner’s position as to the ’047, ’206, ’677, and the ’022 patents, but not as to the ’477, ’722, ’676, and ’794 patents. Appellant first argues that the rejections are improper because the Office has issued two different restrictions based on distinctness of certain compositions. (Appeal Br. 21–22.) Appellant states that the restriction dated August 18, 2014 concluded that “the pharmaceutical compositions comprising a botulinum toxin and the following excipients are distinct: polyvinylpyrrolidone (PVP), sugars/sugar alcohols, polyethylene glycol (PEG), amino acids (e.g. methionine).” (Id. at 21.) Appellant states that the restriction dated April 6, 2009 concluded that “a pharmaceutical composition comprising a botulinum toxin (combination) is distinct from a pharmaceutical composition comprising a botulinum toxin, wherein the botulinum toxin is not stabilized by a protein excipient (subcombination).” (Id. at 21–22.) Appellant argues that “it is improper for the Office to apply one standard to determine whether the claims are distinct for restriction Appeal 2020-000021 Application 14/139,519 19 practice and another contradictory standard for purposes of obviousness-type double patenting.” (Id. at 22.) We do not find this argument persuasive as to any of the patents for the reasons set forth by the Examiner in the Answer (Ans. 45–46), which Appellants do not respond to. a. The ’047, ’206, ’677, and the ’022 patents Appellant argues with respect to these patents, that none refer to a lyophilized composition. (Appeal Br. 23, 30, 36–37, 38.) This argument is not persuasive. The Examiner recognized the absence of this limitation and explained that such would have been an obvious variant of a botulinum toxin composition including the excipients recited by these patent claims in light of the cited prior art. (See, e.g., Final Action 21–22, Ans. 51.) Appellant further argues that the Examiner has failed to provide a rational underpinning for the selection of poloxamer 188. (Appeal Br. 22) Regarding the ’677 patent, Appellant states the Examiner “has not explained why a skilled artisan would have randomly chosen a poloxamer instead of the claimed non-protein polymer excipient.” (Id. at 24.) Regarding the ’022 patent, Appellant states that the Examiner has failed to provide a reason why a skilled artisan would have randomly selected poloxamer 188 from Johnson among a long list of commonly used stabilizing agents, or poloxamer 188 from Friedman’s long list of surfactants, when both Friedman and Carpenter both teach that TWEEN surfactants are most preferred. (Id. at 31.) Appellant argues similarly regarding the ’206 patent. (Id. at 37.) We do not find this argument persuasive for the reasons discussed above regarding the obviousness rejection and the obviousness of using known excipients for their recognized purpose in stabilizing proteins for lyophilization. Appeal 2020-000021 Application 14/139,519 20 Regarding the ’047 patent, Appellant asserts that one of ordinary skill in the art would not have reasonably expected success in obtaining a toxin having the recovery potency of the patent claims. (Id. at 38.) We do not find this argument persuasive because the asserted potency is not an aspect of the patented invention. Whether or not obtaining that potency would have been obvious, has no bearing on whether the claims on appeal, which do not require a particular potency, would have been obvious from the patented claim which recites a composition that includes a botulinum toxin that is not stabilized by a protein excipient, but does include a poloxamer and also includes sucrose or trehalose. Regarding potency, we note that a later- claimed genus is always obvious over an earlier claimed species. In re Slayter, 276 F.2d 408, 411 (CCPA 1960) (“A generic claim cannot be allowed to an applicant if the prior art discloses a species falling within the claimed genus.”) The only difference is that the appealed claims require lyophilization (and with respect to dependent claim 30, a particular poloxamer). We have already addressed the obviousness of those differences above. That the patented combination might yield a better potency does not mean that an inferior potency would not have been obvious. In re Fulton, 391 F.3d 1195, 1200 (Fed. Cir. 2004) (a conclusion of obviousness does not require “something in the prior art as a whole to suggest that the combination is the most desirable combination available”). Regarding the ’677 patent, we note that an “[e]xpress suggestion to substitute one equivalent for another need not be present to render such substitution obvious.” In re Fout, 675 F.2d 297, 301 (CCPA 1982). But, we do note as to the substitution of trehalose or sucrose for lactose, Carpenter Appeal 2020-000021 Application 14/139,519 21 teaches that “[r]educing sugars, such as maltose or lactose, should not be used” in lyophilization because these compounds “during storage in the dried solid . . . can degrade proteins via the Maillard reaction between carbonyls of the sugar and free amino groups on the protein.” (Carpenter 121.) Consequently, for the reasons set forth in the Examiner’s Final Action as well as the Answer addressing Appellant’s arguments, which Appellant does not respond to, we affirm the Examiner’s obviousness-type double patenting rejection with respect to the ’047, ’206, ’677, and the ’022 patents. b. The ’477, ’722, ’676, and ’794 patents The references relied upon by the Examiner indicate excipients are used to stabilize lyophilized proteins, which are subject to various degradation effects on lyophilization either through chemical and/or physical degradation and thus are accompanied by excipients to prevent degradation. We note that in contrast to the patents just discussed, none of the claims of the ’477, ’722, ’676, or ’794 patents recite lyophilized toxin or the inclusion of excipients. The ’477 patent recites botulinum toxin with a cross-linked, polymeric hyaluronic carrier. The ’722 patent recites the botulinum toxin “encapsulated in a carrier.” The ’676 and ’794 patents recite toxin polypeptide structural characteristics and are silent as to any excipients. Consequently, we find that the Examiner has not established a reason that one of ordinary skill in the art would have modified the toxins recited in the patented claims to include excipients used for stabilizing a lyophilized protein. Appeal 2020-000021 Application 14/139,519 22 Thus, we do not affirm the Examiner’s obviousness-type double patenting rejection grounded on the claims of the ’477, ’722, ’676, and ’794 patents. 2. Rejections relying on Johnson, Friedman, Carpenter, and Hunt The Examiner contends that the claims on appeal are “not patentably distinct” from the claims identified in the ’904, ’250, ’815, and ’666 patents “because they are both drawn to substantially similar compositions comprising the same active ingredient, i.e., botulinum toxin, modified to remove an undesirable protein element and stabilized with commonly used non-protein ingredients.” (Final Action 44, 48, 52, 56.) The Examiner relies on Hunt as recognizing prior to 2004, that “the presence of albumin was a serious problem and thus provided one of ordinary skill in the art motivation to remove albumin from pharmaceutical compositions comprising botulinum toxins (e.g. inter alia [0068]).” (See e.g., Final Action 44.) We do not agree with the Examiner’s rejections. The Examiner’s position is that it would have been obvious to do precisely the opposite of what the patented claims require. That is, the claims of each of the ’904, ’250, ’815, and ’666 patents require botulinum toxin and albumin, whereas the instant claims require that “the botulinum toxin is not stabilized by a protein excipient” such as albumin. We find that the patented compositions are the quintessential teaching away, as urged by Appellant. (See e.g., Appeal Br. 27.) They lead one of ordinary skill in the art in a divergent path, a polar opposite path, from the claims on appeal. It is improper to combine references where the references teach away from their combination. In re Grasselli, 713 F.2d 731, 743 (Fed. Cir. 1983) (The Appeal 2020-000021 Application 14/139,519 23 claimed catalyst which contained both iron and an alkali metal was not suggested by the combination of a reference which taught the interchangeability of antimony and alkali metal with the same beneficial result, combined with a reference expressly excluding antimony from, and adding iron to, a catalyst.). Thus, we do not find the claims on appeal to be obvious variants of the patented inventions set forth in the ’904, ’250, ’815, ’666 patents. DECISION SUMMARY In summary: Claims Rejected 35 U.S.C. § Reference(s)/Basis Affirmed Reversed 15, 24–26, 30 103 Donovan, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 8,642,047, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 8,168,206, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 8,137,677, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 15, 24–26, 30 Appeal 2020-000021 Application 14/139,519 24 9,981,022, Johnson, Friedman, Carpenter 15, 24–26, 30 Obviousness-type Double Patenting: 9,044,477, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 9,265,722, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 7,419,676, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 6,203,794, Johnson, Friedman, Carpenter 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 9,629,904, Johnson, Friedman, Carpenter, Hunt 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 8,580,250, Johnson, 15, 24–26, 30 Appeal 2020-000021 Application 14/139,519 25 Friedman, Carpenter, Hunt 15, 24–26, 30 Obviousness-type Double Patenting: 9,107,815, Johnson, Friedman, Carpenter, Hunt 15, 24–26, 30 15, 24–26, 30 Obviousness-type Double Patenting: 8,323,666, Johnson, Friedman, Carpenter, Hunt 15, 24–26, 30 15, 24–26, 30 Provisional Obviousness-type Double Patenting: Application No. 13/427,582, Johnson, Friedman, and Carpenter 15, 24–26, 30 Overall Outcome 15, 24–26, 30 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). See 37 C.F.R. § 1.136(a)(1)(iv). AFFIRMED