15005577 (P.T.A.B. Oct. 24, 2018)

Ex Parte Beacom et al

Patent Trial and Appeal BoardOct 24, 2018

15005577 (P.T.A.B. Oct. 24, 2018)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 15/005,577 23408 7590 Gary C Cohn PLLC 325 7th A venue, #203 San Diego, CA 92101 01/25/2016 10/26/2018 FIRST NAMED INVENTOR Daniel R. Beacom 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 ATTORNEY DOCKET NO. CONFIRMATION NO. 070333US03 6101 EXAMINER AFREMOVA, VERA ART UNIT PAPER NUMBER 1653 NOTIFICATION DATE DELIVERY MODE 10/26/2018 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): garycohn@seattlepatent.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte DANIEL R. BEACOM, JEFFREY J. KOLSTAD, DAVID H. REEDER, and BRIAN J. RUSH 1 Appeal2018-002124 Application 15/005,577 Technology Center 1600 Before RICHARD J. SMITH, TA WEN CHANG, and TIMOTHY G. MAJORS, Administrative Patent Judges. SMITH, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. Â§ 134 involving claims to a fermentation process. A hearing was held on September 11, 2018. We have jurisdiction under 35 U.S.C. Â§ 6(b). We affirm the rejections for indefiniteness and nonstatutory double patenting, which were not contested on appeal, and we reverse the rejection for obviousness. 1 According to Appellants, the real party in interest is Cargill, Incorporated. ( Appeal Br. 1.) Appeal2018-002124 Application 15/005,577 STATEMENT OF THE CASE Background "Fermentation processes are used commercially at large scale to produce organic molecules such as ethanol, citric acid and lactic acid. In those processes, a carbohydrate is fed to a microorganism that is capable of metabolizing it to the desired fermentation product." (Spec. 1, 11. 8-11.) "Usually, starch is hydrolyzed to form a mixture containing mainly glucose (i.e., dextrose). However ... most commercially available glucose products tend to contain a small amount of fructose and various oligomeric polysaccharides. Unfortunately, many microorganisms cannot metabolize the oligomers, either, and so these carbohydrate values are wasted." (Id. at 11. 23-28.) "So-called simultaneous saccharification and fermentation (SSF) processes are known, in which an unhydrolyzed starch is fed into a fermentation process together with enzymes that catalyse the breakdown of the starch until monosaccharides. Monosaccharides are produced and are simultaneously fermented to the desired product." (Id. at 11. 31-35.) Claims on Appeal Claims 4--11 are on appeal. (Claims Appendix, Appeal Br. CA-l- CA-2.) Claim 4, the only independent claim on appeal, is illustrative and reads as follows: 4. A process for fermenting a fermentation substrate in the presence of a microorgamsm, comprising (A) forming a starting fermentation broth containing a starch hydrolysate containing 80-98 weight% (based on carbohydrates) of glucose and 1-20 weight% (based on carbohydrates) of glucose oligomers that are not fermentable by 2 Appeal2018-002124 Application 15/005,577 the microorganism, wherein the starting fermentation broth contains at least 30 g/L of glucose; (B) fermenting the starting fermentation broth in the presence of the microorganism to conditions sufficient to ferment the glucose and reduce the glucose concentration in the fermentation broth to less than 30 g/L; (C) then adding to the fermentation broth an effective quantity of a least one enzyme that depolymerizes at least one glucose oligomer in the fermentation broth to form glucose; (D) and then subjecting the fermentation broth to conditions sufficient to simultaneously depolymerize the glucose oligomers and ferment the glucose to form the desired fermentation product. Examiner's Rejections 1. Claims 4--11 stand rejected under pre-AIA 35 U.S.C. Â§ 103(a) as unpatentable over Tsai, 2 Cadmus, 3 and Oda. 4 (Final Act. 5 2-5.) 2. Claims 4--11 stand rejected under 35 U.S.C. Â§ 112(b) or 35 U.S.C. Â§ 112 (pre-AIA), second paragraph, as indefinite, due to insufficient antecedent basis in claim 4 for the limitation "the desired fermentation product." (Id. at 2.) 3. Claims 4--11 stand rejected on the ground of nonstatutory double patenting as unpatentable over claims 1--4 of US 9,328,364. 6 (Id. at 7.) 2 Tsai et al., US 5,464,760, issued Nov. 7, 1995 ("Tsai"). 3 M.C. Cadmus et al., Enzymatic Production of Glucose Syrup from Grains and its use in Fermentations, Cereal Chem. 43(6), 658---69 (1966) ("Cadmus"). 4 Oda, US 5,780,275, issued July 14, 1998. 5 Final Office Action dated Feb. 14, 2017 ("Final Act."). 6 Beacom et al., US 9,328,364 B2, issued May 3, 2016. 3 Appeal2018-002124 Application 15/005,577 4. Claims 4--11 stand provisionally rejected on the ground of nonstatutory double patenting as unpatentable over claims 4--13 of copending Application No. 14/524,032.7 (Id. at 8.) DISCUSSION Rejection No. 1 Issue Whether a preponderance of evidence of record supports the Examiner's rejection under pre-AIA 35 U.S.C. Â§ 103(a). Analysis8 The Examiner finds that Tsai "teaches fermentation processes based on a microbial fermentation and on a simultaneous fermentation and saccharification (SSF) of glucose-containing starch hydrolysates." (Final Act. 3.) In particular, the Examiner points to Example 8 of Tsai as teaching a fermentation process as recited in steps (A) and (B) of claim 4, wherein the starting glucose of 120 g/L is reduced to 0.6 g/L in the presence of a microorganism. (Id., citing Tsai col. 10, 11. 13-16, 18.) The Examiner further points to Example 7 of Tsai as teaching a fermentation process (such as SSF) as recited in steps (C) and (D) of claim 4, wherein the beginning glucose concentration is 24 g/L ("less than 30 g/L" per claim 4), and a microorganism that ferments the glucose and an enzyme that depolymerizes 7 Application No. 14/524,032 issued on July 25, 2017, as US 9,714,438 B2, and the rejection is thus no longer provisional. 8 Although claims 4--11 are subject to a rejection as indefinite (Rejection No. 2), we do not find that the rejection impedes our ability to address the art rejection. See Ex parte Tanksley, 26 USPQ2d 1384, 1387 (BPAI 1991) ( exercising discretion to reach obviousness rejection despite indefiniteness). 4 Appeal2018-002124 Application 15/005,577 the oligosaccharide isomaltose9 are mixed with the glucose. (Final Act. 3--4, citing Tsai col. 1, 11. 39--46, col. 9, 11. 40--41, and Table 3 (col. 9, 11. 48---60).) Based on those findings, the Examiner concludes that [ t ]hus, as a whole the cited [art] teaches the fermentation process comprising a microbial fermentation of glucose-containing starch hydrolysate (steps A and B) and a simultaneous fermentation and saccharification (SSF) of glucose-containing starch hydrolysates (steps C and D), wherein the SSF steps, that are conducted in the presence of both microorganism and enzyme, are initiated when glucose concentration is below 30 g/L as it is encompassed by the instant claims. Therefore, the claimed invention as a whole was clearly prima facie obvious, especially in the absence of evidence to the contrary. (Final Act. 4.) The Examiner also points to Oda as teaching that the optimal concentration of the glucose at the beginning of SSF should be less than 30 g/L. (Final Act. 4--5, citing Oda col. 6, 11. 21-35.) Based on that finding, the Examiner concludes that it would have been obvious to practice SSF comprising less than 30 g/L of fermentable monosaccharide with a reasonable expectation of success because the prior art teaches the benefits of SSF and "that the high monosaccharide concentration in the fermentable materials inhibit microbial growth and enzymatic activity." (Final Act. 5.) Appellants 'Arguments Appellants argue that Tsai does not disclose Appellants' step (B) followed by Appellants' steps (C) and (D). (Appeal Br. 5.) Appellants also argue that, contrary to the Examiner's position, there is no suggestion in Tsai 9 The Examiner relies on the teaching of Cadmus that starch hydrolysate comprises about 10% or less of isomaltose, thereby meeting the claim limitation of 1-20 weight percent glucose oligomers. (Final Act. 3, citing Cadmus Abstract.) 5 Appeal2018-002124 Application 15/005,577 to combine Example 8 of Tsai (that Appellants refer to a "normal" fermentation process) with Tsai's Example 7, an SSF process. (Id.) Appellants argue that "the 'normal' and SSF processes are alternatives to each other, as is clear from the separate treatment of the two processes throughout [Tsai]." (Id.) Appellants further argue that the Examiner's proposed combination of Example 8 and Example 7 of Tsai "would make no technical sense" because "[t]he Example 8 process has already consumed the sugars more completely than Tsai[] achieved with the SSF process." (Id. at 6.) In support of this argument, Appellants point to the data showing that the final concentrations of glucose and TRS 10 in Example 8 are 0.6 g/L (glucose) and 6.9 g/L (TRS), whereas the final concentrations in Example 7 are 5.3 g/L (glucose) and 9.6 g/L (TRS). (Id.) According to Appellants, "based on [Tsai's] own data, the only logical conclusion is that no purpose would be served by performing a subsequent SSF step on the Example 8 product." (Id.) Examiner's Response The Examiner disputes Appellants' contention that Tsai does not suggest combining Example 8 with Example 7. (Ans. 8-10.) In particular, the Examiner responds that Tsai is relied upon "as a whole for all it contains" and the embodiments of Example 8 and Example 7 (normal fermentation and SSF) are regarded as "variants" by Tsai, and are combined in a whole process stream as illustrated in Figure IA of Tsai. (Id. at 9.) The disclosure of Tsai relied upon by the Examiner states as follows (referring the flowchart of Figure IA shown below): "As a variance of the 10 TRS stands for total reducing sugars and includes both glucose and remaining non-fermentable sugars. (Ans. 10.) 6 Appeal2018-002124 Application 15/005,577 process, if a separate saccharification step is desired ( note dotted lines on flowchart) the liquefied starch 114 is sent to a saccharification unit 117 to produce a glucose syrup before it is fed into the fermenter 116." (Tsai col. 6, 11. 36-39, referred to at Ans. 9.) Figure IA of Tsai is set forth below: M!CROlML !NOCUWM 116 ANO ~JUTRIENTS 120 SODIUM Hl'DP.OXtDE 122 POTATO ~~ASTE 11}'.I -------- -------, HOMOGENATE 103 STARCH SEPARATION mm 100 ST ARC'kl SLURRY 110 UQ\JEF ACTION UNIT 112 UOUIFlEO STARCH 114 Fe:RMENTATiON BROTH rn4 ' CEU. SEPARATOR 126 SACCHARlFICATION ~.... UNIT 117 CEl.L MASS i30 CEll Â· FREE !lflO TH 12S PR!MNW RECOVERY UNIT 1S4 CRUDE LACTIC ACID 13S VACUUM EV.Af'ORA TOR 13S CONCENTHATED LACTIC ACID 140 P1.IRIF!CATICIN PROCESS 142 (NEXT SHEET) F!GURE 1A 7 Appeal2018-002124 Application 15/005,577 Figure IA above is a fermentation process flow chart from Tsai. Regarding Appellants' argument that combining Example 8 and Example 7 "would make no technical sense" because the final glucose and TRS in Example 8 is already lower than in SSF Example 7, the Examiner responds that this "is not found particularly true." (Ans. 10.) By the Examiner's calculations, Example 7 has a smaller amount of remaining non- fermentable sugars than in Example 8, which is "clear evidence that SSF (addition of enzymes to a microbial fermentation) is more efficient with regards to conversion of non-fermentable sugars of a starting substrate to a fermentable glucose." (Id.) We find that Appellants have the better position. A prima facie case for obviousness "requires a suggestion of all limitations in a claim," CFMT, Inc. v. Yieldup Int 'l Corp., 349 F.3d 1333, 1342 (Fed. Cir. 2003), and "a reason that would have prompted a person of ordinary skill in the relevant field to combine the elements in the way the claimed new invention does," KSR Int 'l Co. v. Teleflex Inc., 550 U.S. 398, 418 (2007). Here, the Examiner's obviousness rejection is based on a combination of Tsai's Example 8 and Example 7. However, the Examiner has not persuasively shown a suggestion or reason to combine those different examples to arrive at claim 4. We agree with Appellants that Examples 7 and 8 of Tsai are described as alternative processes, and are not persuaded by the Examiner's reliance on Tsai's Figure IA and "variance of the process" disclosure. Appellants specifically argue that "the examiner misreads this passage" from Tsai regarding the "variance of the process." (Reply Br. 2- 3.) According to Appellants, the "process described in the quoted sentence 8 Appeal2018-002124 Application 15/005,577 has only a single fermentation step (which is an SSF step)." (Id.) Regardless of whether the process of Figure IA is characterized as an SSF process, it is clear that the addition of microorganisms ( and thus fermentation) begins after or simultaneously with the enzymatic process of conversion to a fermentable (i.e., simple) sugar, such as glucose. (See Fermenter Step 116 in Figure IA.) In contrast, Appellants' claimed process begins fermentation prior to the addition of enzymes to convert oligomers to fermentable sugars. Furthermore, Appellants' claimed process begins with "at least 30 g/L of glucose" and adds the depolymerization enzyme after the glucose is reduced to "less than 3 0 g/L." The respective comparison of Examples 7 and 8 by Appellants, and the calculation of TRS by the Examiner, further support Appellants' contention that the examples are alternatives. The Specification describes the advantages and disadvantages of the "normal" fermentation process and the SSF process. (See Spec. 1, 1. 23-2, 1. 5.) Thus, the fact that Example 7 has a smaller amount of non-fermentable sugars than Example 8, and Example 8 has a smaller amount of glucose than Example 7, at the end of the respective processes, simply reflects the trade-offs between the two alternative processes. Accordingly, for the reasons of record and as set forth above, we reverse the rejection of claim 4 and dependent claims 5-11 for obviousness. Rejection Nos. 2, 3, and 4 Appellants do not contest the rejection for indefiniteness ( claims 4-- 11, Rejection No. 2) or the rejections for nonstatutory double patenting (Rejection Nos. 3 and 4). Accordingly, those rejections are summarily 9 Appeal2018-002124 Application 15/005,577 affirmed. See 37 C.F.R. Â§ 4I.37(c)(l)(iv); Hyatt v. Dudas, 551 F.3d 1307, 1314 (Fed. Cir. 2008). Conclusions A preponderance of evidence of record fails to support the Examiner's rejection of claims 4--11 for obviousness under pre-AIA 35 U.S.C. Â§ 103(a). A preponderance of evidence of record supports the Examiner's rejection of claims 4--11 under 35 U.S.C. Â§ 112(b) or 35 U.S.C. Â§ 112 (pre- AIA), second paragraph, as indefinite. A preponderance of evidence of record supports the Examiner's rejection of claims 4--11 on the ground of nonstatutory double patenting as unpatentable over claims 1--4 of U.S. Patent No. 9,328,364 B2. A preponderance of evidence of record supports the Examiner's rejection of claims 4--11 on the ground of nonstatutory double patenting as unpatentable over claims 4--13 of U.S. Patent No. 9,714,438 B2. SUMMARY We reverse the rejection of claims 4--11 under pre-AIA 35 U.S.C. Â§ 103(a). We affirm the rejection of claims 4--11 under 35 U.S.C. Â§ 112(b) or 35 U.S.C. Â§ 112 (pre-AIA), second paragraph, as indefinite We affirm the rejections of claims 4--11 on the ground of nonstatutory double patenting as unpatentable over claims 1--4 of U.S. Patent No. 9,328,364 B2 and claims 4--13 of U.S. Patent No. 9,714,438 B2. 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. Â§ 1.136(a). AFFIRMED 10