11873878 (B.P.A.I. Sep. 17, 2010)

Ex Parte Lebing et al

Board of Patent Appeals and InterferencesSep 17, 2010

11873878 (B.P.A.I. Sep. 17, 2010)

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. 11/873,878 10/17/2007 Wytold R. Lebing 13281-00002-US1 1437 23416 7590 09/17/2010 CONNOLLY BOVE LODGE & HUTZ, LLP P O BOX 2207 WILMINGTON, DE 19899 EXAMINER MOSHER, MARY ART UNIT PAPER NUMBER 1648 MAIL DATE DELIVERY MODE 09/17/2010 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 STATE S PATENT AND TRADEMARK OFFICE __________ BEFORE THE BOARD OF PATENT APPEALS AND INTERFERENCES __________ Ex parte WYTOLD R. LEBING, DOUGLAS C. LEE, KLAUS-PETER RADTKE, SCOTT A. COOK, HANNS-INGOLF PAUL, and PATRICIA ALRED __________ Appeal 2010-008454 Application 11/873,878 Technology Center 1600 __________ Before ERIC GRIMES, FRANCISCO C. PRATS, and JEFFREY N. FREDMAN, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL1 This is an appeal under 35 U.S.C. § 134 involving claims to a method of preparing a purified, virally inactivated antibody preparation.2 The 1 The two-month time period for filing an appeal or commencing a civil action, as recited in 37 C.F.R. § 1.304, or for filing a request for rehearing, as recited in 37 C.F.R. § 41.52, begins to run from the “MAIL DATE” (paper delivery mode) or the “NOTIFICATION DATE” (electronic delivery mode) shown on the PTOL-90A cover letter attached to this decision. 2 Oral Hearing held on September 14, 2010. Appeal 2010-008454 Application 11/873,878 2 Examiner rejected the claims as anticipated. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. Statement of the Case The Claims This is a reissue application of US 6,955,917, issued October 18, 2005. Claims 8 and 11, filed in the reissue application, are on appeal. Claims 8 and 11 read as follows: 8. A method of preparing a purified, virally inactivated antibody preparation from a starting solution comprising antibodies and other substances at an initial pH, the method comprising the steps of: (a) adding a source of caprylate ions to the starting solution and adjusting the pH to form a precipitate and a supernatant solution comprising antibodies, and (b) incubating the supernatant solution under conditions of time, pH, temperature, and caprylate ion concentration to inactivate substantially all enveloped viruses to produce a purified, virally inactivated antibody preparation. 11. A method of preparing a purified, virally inactivated immunoglobulin preparation from a starting material comprising immunoglobulin and other substances, the method comprising the steps of (a) adjusting the starting material to conditions of pH, temperature, and caprylate concentration such that a first precipitate and a first supernatant comprising immunoglobulin are formed, (b) separating the first supernatant from the first precipitate, Appeal 2010-008454 Application 11/873,878 3 (c) incubating the first supernatant under conditions of time, pH, temperature, and caprylate concentration to inactivate substantially all enveloped viruses, and such that a second precipitate and a second supernatant comprising immunoglobulin are formed, and (d) separating the second supernatant from the second precipitate to produce a purified, virally inactivated immunoglobulin preparation. The issue The Examiner rejected claims 8 and 11 under 35 U.S.C. § 102(b) as anticipated by Steinbuch3 as evidenced by Seng4 (Ans. 3-4). The Examiner finds that Steinbuch “teaches a method of preparing antibodies from a starting solution comprising other substances, which comprises adjustment of the pH to 4.5 - 5.2 (optimally 4.8) and dropwise addition of caprylic acid (6.8 g/100 ml) at room temperature for 30 minutes to form a precipitate and a supernatant solution comprising antibodies” (id. at 3). The Examiner finds that Seng evidences that “at pH 6.5 or less, virus inactivation by caprylic acid is achieved almost instantaneously” (id.). The Examiner concludes that “Steinbuch inherently anticipates the claimed method, even though the reference does not expressly teach virus inactivation” (id.). Appellants contend that “Steinbuch teaches addition of caprylic acid. . . . [U]se of caprylic acid, and particularly use at high levels as disclosed in 3 M. Steinbuch and R. Audran, The Isolation of IgG from Mammalian Sera with the Aid of Caprylic Acid, 134 ARCHIVES BIOCHEMISTRY BIOPHYSICS 279-284 (1969). 4 Seng et al., US 4,939,176, issued Jul. 3, 1990. Appeal 2010-008454 Application 11/873,878 4 Steinbuch, is not the same as ‘adding a source of caprylate ions’ as recited in step (a) of claim 8” (App. Br. 11). Appellants contend that the “anticipation rejection of claim 8 also fails because the inherency of viral inactivation has not been established” (id. at 12). Appellants quote Seng’s teaching that “[s]urprisingly, at lower pHs (6.5 or less) if caprylic acid is present at 0.07 to 0.001%, virus inactivation is achieved almost instantaneously” (id., citing Seng 3). Appellants calculate that “Figure 2 discloses using 6.8 g caprylic acid in 100 ml of 5% human plasma and 200 ml acetate buffer. Assuming the solution has a density of 1 mg/ml, caprylic acid is present at 2.267 % by weight, which is far above where Seng teaches instantaneous viral inactivation occurs” (id.). The issues with respect to this rejection are: (i) Does the evidence of record support the Examiner’s conclusion that the IgG isolation method of Steinbuch inherently adds caprylate ions? (ii) Does the evidence of record support the Examiner’s conclusion that the IgG isolation method of Steinbuch inherently functions to “inactivate substantially all enveloped viruses”? Findings of Fact 1. Steinbuch teaches “a procedure for the preparation of pure IgG with good yield” (Steinbuch 279, col. 1). 2. Steinbuch teaches a starting solution where “[h]uman, equine, ovine, and rabbit sera or ACD plasma were used in these experiments” (Steinbuch 279, col. 1). 3. Steinbuch teaches that “the purity and yield of IgG were dependent on the amount of caprylic acid, the pH of the reaction mixture, the Appeal 2010-008454 Application 11/873,878 5 dilution factor and the molarity of the buffer used for dilution” (Steinbuch 280, col. 1). 4. Steinbuch teaches that “[a]djustment of the pH to 4.8 ± 0.05 before adding the caprylic acid has been adopted as a standard procedure” (Steinbuch 280, col. 2). 5. Steinbuch teaches that the “amount of caprylic acid necessary to remove the proteins of 100 ml ACD plasma of about 5% protein concentration (or equally diluted serum) was 6.8 g ± 5%” (Steinbuch 280, col. 2). 6. Figure 2 of Steinbuch is reproduced below: “Fig. 2. Flow sheet showing the isolation of IgG from human plasma” (Steinbuch 281). 7. Figure 2 of Steinbuch shows that caprylic acid was added dropwise into a 300 ml solution with a pH of 4.8 at a temperature of 20°C Appeal 2010-008454 Application 11/873,878 6 and then subjected to stirring for 30 minutes prior to centrifugation (see FF 6). 8. The Examiner finds that “an acid . . . will partially dissociate into its ionized form in aqueous solution. At the pKa, one-half of the dissolved molecules will be in ionized form” (Ans. 4). 9. Seng teaches that the “pKa of caprylic acid is 4.89 . . . The Henderson-Hasselbalch equation: gives the concentration of acid and its ionized form at various pHs” (Seng, col. 4, ll. 1-9). 10. Seng teaches that “one can easily provide a given concentration of caprylic acid by carefully controlling pH and caprylate concentration. For example, if the caprylic acid concentration is kept constant at 0.07% (0.0035 M) and the ionized form (e.g., sodium caprylate) is varied between 0.06% at pH 4.9 and 2.0% at pH=8, the amount of caprylic acid shown as FIG. 1 is produced” (Seng, col. 4, ll. 9-16). 11. Seng teaches “varying the concentration of sodium caprylate between 0.1% at pH 4.8 and 20% at about pH =9.0 to give instantaneous inactivation of lipid-coated viruses. More preferably, the total concentration is kept between 0.1% at pH 4.8 and linearly increasing to 2.0% at 6.5 to give instantaneous virus inactivation” (Seng, col. 4, ll. 21-27). 12. Seng teaches that “caprylate can be kept at 2% between pH 6.5 and 9.5 for a longer period of time (e.g., 2 to 4 hours) to give an appropriate caprylic acid concentration for virus inactivation” (Seng, col. 4, ll. 27-30). Appeal 2010-008454 Application 11/873,878 7 13. The Specification5 teaches that the “process involves suspension of the antibodies at pH 3.8 to 4.5 followed by the addition of caprylic acid (or other source of caprylate) and a pH shift to pH 5.0 to 5.2 . . . . Sodium caprylate is again added to a final concentration of not less than about 15 mM. This solution is incubated under conditions sufficient to substantially reduce the titer of active virus” (Alred, col. 3, ll. 1-9). Principles of Law “Whether the rejection is based on ‘inherency’ under 35 U.S.C. § 102, on ‘prima facie obviousness’ under 35 U.S.C. § 103, jointly or alternatively, the burden of proof is the same, and its fairness is evidenced by the PTO’s inability to manufacture products or to obtain and compare prior art products.” In re Best, 562 F.2d 1252, 1255 (CCPA 1977). Analysis The Specification teaches that caprylic acid is a source of caprylate (FF 13). Steinbuch teaches adding caprylate ions to a starting solution which comprises antibodies, and adjusting the pH to form a precipitate, followed by incubating the solution with caprylate (FF 1-6). Seng provides evidence that a solution of caprylic acid at pH 8 will comprise caprylate ions (FF 8-10) and that caprylic acid will instantaneously inactivate lipid coated particles at pH 4.8 (FF 11-12). We agree with the Examiner that Seng “provides reason to believe that the conditions of time, pH, temperature and caprylate ion concentrations present in Steinbuch were inherently sufficient to inactivate substantially all enveloped viruses in the supernatant solution” (Ans. 4). 5 Citation is to Alred et al., US 6,955,917 B2, issued Oct. 18, 2005. Appeal 2010-008454 Application 11/873,878 8 Appellants contend that “Steinbuch teaches addition of caprylic acid. . . . [U]se of caprylic acid, and particularly use at high levels as disclosed in Steinbuch, is not the same as ‘adding a source of caprylate ions’ as recited in step (a) of claim 8” (App. Br. 11). We are not persuaded. Appellants’ own Specification teaches addition of caprylic acid as a source of caprylate (FF 13). Seng teaches the Henderson-Hasselbalch equation, which shows the equilibrium equation for a compound in acid and ionized forms (FF 9). Seng teaches this equilibrium for caprylic acid and its ionized form (FF 10). Seng teaches that at pH 4.9 the solution comprises 0.0035 M caprylic acid, where 0.06% is in the ionized form (FF 10). Thus, there can be no reasonable dispute that at pH 4.8 as taught in Steinbuch, the caprylic acid will be found in both caprylic acid and ionized forms, as required by the Henderson-Hasselbalch equation (FF 9-11). Appellants contend that “the suspensions involved in Steinbuch et al. are not ideal solutions . . . Thus the arguments based on pK in an ideal aqueous solution do not apply, because the mixture in Steinbuch et al. is far from an idealized aqueous solution” (Reply Br. 3). We are not persuaded. Seng clearly relies upon the Henderson- Hasselbalch equation as representative of the ionization of caprylic acid in solution (FF 9-11). The Examiner reasonably relies upon this evidence to demonstrate inherency in the absence of any rebuttal evidence. Appellants contend that the “anticipation rejection of claim 8 also fails because the inherency of viral inactivation has not been established” (App. Br. 12). Appellants quote Seng’s teaching that “[s]urprisingly, at lower pHs Appeal 2010-008454 Application 11/873,878 9 (6.5 or less) if caprylic acid is present at 0.07 to 0.001%, virus inactivation is achieved almost instantaneously” (id., citing Seng 3). Appellants calculate that Steinbuch’s “Figure 2 discloses using 6.8 g caprylic acid in 100 ml of 5% human plasma and 200 ml acetate buffer. Assuming the solution has a density of 1 mg/ml, caprylic acid is present at 2.267 % by weight, which is far above where Seng teaches instantaneous viral inactivation occurs” (id. at 12). Steinbuch teaches the dropwise addition of caprylic acid to the antibody solution which will inherently and necessarily result in increasing concentrations of both caprylic acid and the ionized form as more drops are added, until the final concentration is reached (FF 6-7). As these concentrations increase from zero to Appellants’ calculated 2.267% (App. Br. 12), during Steinbuch’s process, the concentrations will necessarily fall within Seng’s instantaneous inactivation range of 0.07 to 0.001%. Further, Seng does not teach that higher concentrations of caprylic acid and caprylate ions do not inactivate virus, but rather that the lower concentration range of 0.07 to 0.001% is preferred (see Seng, col. 3, ll. 24- 26). In fact, Seng teaches that “caprylate can be kept at 2% between pH 6.5 and 9.5 for a longer period of time (e.g., 2 to 4 hours) to give an appropriate caprylic acid concentration for virus inactivation” (Seng, col. 4, ll. 27-30; FF 12). This 2% range is close to the 2.267% value calculated for Steinbuch by Appellants (see App. Br. 12). Appellants have provided no direct evidence clearly showing that the amount of caprylic acid added by Steinbuch does not inherently comprise caprylate ions or that the amount, time, pH value and temperature used by Appeal 2010-008454 Application 11/873,878 10 Steinbuch would not inherently result in inactivating the virus as required by claims 8 and 11. “Where, as here, the claimed and prior art products are identical or substantially identical, or are produced by identical or substantially identical processes, the PTO can require an [A]pplicant to prove that the prior art products do not necessarily or inherently possess the characteristics of his claimed product.” In re Best, 562 F.2d 1252, 1255 (CCPA 1977). Conclusions of Law (i) The evidence of record supports the Examiner’s conclusion that the IgG isolation method of Steinbuch inherently adds caprylate ions. (ii) The evidence of record supports the Examiner’s conclusion that the IgG isolation method of Steinbuch inherently functions to “inactivate substantially all enveloped viruses.” SUMMARY In summary, we affirm the rejection of claims 8 and 11 under 35 U.S.C. § 102(b) as anticipated by Steinbuch as evidenced by Seng. No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a)(1)(iv)(2006). AFFIRMED cdc CONNOLLY BOVE LODGE & HUTZ, LLP P O BOX 2207 WILMINGTON, DE 19899