13856244 (P.T.A.B. Dec. 13, 2016)

Ex Parte Wang et al

Patent Trial and Appeal BoardDec 13, 2016

13856244 (P.T.A.B. Dec. 13, 2016)

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. 13/856,244 04/03/2013 Ping Wang TTC-87003/08wrg 4931 63796 7590 12/15/2016 DINSMORE & SHOHL LLP P.O. BOX 7021 TROY, MI 48007-7021 EXAMINER BOWERS, ERIN M ART UNIT PAPER NUMBER 1653 NOTIFICATION DATE DELIVERY MODE 12/15/2016 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): docket@patlaw.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte PING WANG, SONGTAO WU, HONGFEI JIA, MASAHIKO ISHII, and MINJUAN ZHANG Appeal 2014-009545 Application 13/856,244 Technology Center 1600 Before JEFFREY N. FREDMAN, TIMOTHY G. MAJORS, and KRISTI L. R. SAWERT, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL This is an appeal1 under 35 U.S.C. § 134 involving claims to a process for stabilizing a bioactive composition against inactivation by an organic solvent. The Examiner rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. 1 Appellants identify the Real Parties in Interest as Toyota Motor Engineering & Manufacturing North America, Inc., The University of Minnesota, and the Toyota Motor Corporation (see App. Br. 1). Appeal 2014-009545 Application 13/856,244 Statement of the Case Background “Bioactive macromolecules such as proteins, nucleic acids, and functional enzymes may be utilized in various aspects of biomedical and industrial applications” (Spec. 13). “Although proteins such as digestive proteins or enzymes may be capable of decomposing and reacting with various organic molecules, they are generally not thermally stable at elevated temperatures. Additionally, such proteins or digestive enzymes are generally not stable in a non-aqueous organic solvent” (Spec. 14). The Claims Claims 1—5 and 7—9 are on appeal. Independent claim 1 is representative and reads as follows: 1. A process for stabilizing a bioactive composition against inactivation by an organic solvent comprising: forming hydrogel matrix pores around protein molecules; reducing a water content within the hydrogel matrix pores forming a hydrogel-protein composite, said step of reducing comprising heating the hydrogel matrix to a temperature of from 20 to 80 degrees Celsius for a time period of 24 hours followed by air drying at room temperature for one week; and stabilizing activity of said protein molecules against inactivation by an organic solvent by said step of forming and said step of reducing. The Issue The Examiner rejected claims 1—5 and 7—9 under 35 U.S.C. § 103(a) as obvious over Wang2 and Lee3 (Final Act. 3—8). 2 Wang et al., US 2008/0293117 Al, published Nov. 27, 2008 (“Wang”). 2 Appeal 2014-009545 Application 13/856,244 The Examiner finds “Wang teaches the encapsulation of chymotrypsin and glucose oxidase in acrylamide hydrogels”; that the “hydrogel entrapped enzymes were exposed to a thermal pretreatment in an oven”; and the “thermal pretreatment conditions for the hydrogel-entrapped glucose oxidase were 20-80 °C for 24 hours” (Final Act 3 4). The Examiner acknowledges that “Wang does not teach that the hydrogel matrix was air dried at room temperature for one week” (Final Act. 6). The Examiner finds “Lee teaches the immobilization of lysozyme in Pluronic hydrogels .... The polymerized gel disks were dried in air for one day and then dried in an oven for one day” (id. ). The Examiner finds it obvious “to air dry the hydrogels in addition to drying them in the oven because Lee teaches that air drying in addition to oven drying is a known method of drying hydrogels” (id.). The Examiner finds it obvious “to determine all operable and optimal drying times for the hydrogel-protein composites because the drying time is an art-recognized result-effective variable known to affect the residual water content, which would have been optimized in the art to provide maximum protein stability” (Final Act. 7). The issue with respect to this rejection is: Does the evidence of record support the Examiner’s conclusion that Wang and Lee render obvious 3 Lee et al., Photo-crosslinkable, thermo-sensitive and biodegradable Pluronic hydrogels for sustained release ofprotein, 15 J. Biomater. Sci. Polymer Edn 1571-1583 (2004) (“Lee”). 3 Appeal 2014-009545 Application 13/856,244 a process of stabilizing a hydrogel encapsulated enzyme by “air drying at room temperature for one week” after oven drying as required by claim 1? Findings of Fact 1. Wang teaches “a need in the art for a thermally stable bioactive composition and process for producing the bioactive composition that may be stable for various environmental stresses including elevated temperature and acidity” (Wang 17). 2. Wang teaches, in Example 1, forming hydrogel matrix pores around protein molecules by “[entrapment of Glucose Oxidase (GOx) into Polyacrylamide Hydrogel” (Wang H 46-47; see Final Act. 3 4). 3. Wang teaches “[ijncubation in an oven under specific temperatures—For hydrogel-entrapped glucose oxidase, an effective pretreatment temperature is illustratively in the range from 20 degree Celsius to 80 degree Celsius” (Wang 1 63). 4. Wang teaches the “estimated half-life of the thermal pretreated glucose oxidase molecules is greater than 500 days compared to minutes for the freely unbound native counterparts” (Wang 1 65). 5. Wang teaches “the stability of the biological macromolecules may be improved through the porosity control of the resultant hydrogel through the manipulation of the water content of the hydrogel such as removing the free water located within the hydrogel” (Wang 137). 6. Wang teaches a thermal pretreatment may include a heat-assisted procedure to remove water from the hydrogel. Various factors including the degree of temperature, the period of time for heat treatment, the starting water content of the hydrogel, as well as the molecular 4 Appeal 2014-009545 Application 13/856,244 weight of the targeted bioactive macromolecules will have a result on the stability of a hydrogel matrix. (Wang 139). 7. Wang teaches “[f]or example, a hydrogel specimen having a glucose oxidase may be pretreated at temperatures of from 20 to 110 degrees Celsius for time periods of from 24 hours to 7 days in length” (Wang 141) 8. Wang teaches that “heat treatment to form a hydrogel protein structure providing increased stability for the protein macromolecule .... Various external stresses including acidic, basic, inorganic salts or organic solvents and heat may cause the denaturization of the proteins” (Wang 136). 9. Wang teaches, in Example 9: “Stability of Thermal Pretreated Hydrogel-Entrapped Glucose Oxidase (GOx) Under a Combined Harsh Condition” where “[stability was investigated under a combined harsh condition including a combination of high temperature and polar solvent” and “the combined harsh condition of dry heat of 75 degrees Celsius and the presence of ethanol elicits no significant effect on the thermal preheated GOx over an examined period of 1200 hours compared to the native GOx counterpart that gets denatured and inactivated instantaneously within a matter of minutes” (Wang H 67—69). 10. Lee teaches “[m]any kinds of natural and synthetic polymeric hydrogels have been widely used for sustained delivery of bioactive macromolecules” (Lee 1571). 11. Lee teaches “lysozyme was dissolved in the Pluronic macromer solution . . . [ajfter UV induced polymerization, gel-disks with a diameter of 5 Appeal 2014-009545 Application 13/856,244 1 cm were excised . . . [t]he above gel-disks were dried in air for 1 day, and then in a vacuum oven for 1 day” (Lee 1574). 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 Inti 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.” Mat417. Analysis We adopt the Examiner’s findings of fact and reasoning regarding the scope and content of the prior art (Final Act. 3—8; FF 1—11). We address Appellants’ arguments below. Appellants contend that “[i]t is clear that neither reference teaches room temperature air drying for one week as is required by all presently pending claims” (App. Br. 2). Appellants also contend “there is no suggestion in Wang et al., Fee et al., or any other cited reference or evidence of record to modify the Wang et al. drying step to add additional drying time for any purpose, including for providing solvent stability” (App. Br. 3). Appellants contend “drying was not recognized as a variable that would lead to organic solvent stability” and that a “one week air drying step was not recognized as an adjustable variable that would or could impart solvent stability to a hydrogel entrapped enzyme” (App. Br. 5). We do not find these arguments persuasive not just because the rejection is for obviousness but because Wang teaches “a hydrogel specimen having a glucose oxidase may be pretreated at temperatures of from 20 to 6 Appeal 2014-009545 Application 13/856,244 110 degrees Celsius for time periods of from 24 hours to 7 days in length” (FF 7) to improve stability (FF 5). Thus, Wang’s pretreatment range expressly encompasses drying at room temperatures of about 20 to 25 °C and time periods of a week (seven days) (FF 7). We also agree with the Examiner that “the instantly claimed drying time would be within the realm of routine experimentation” (Final Act. 7). Indeed, Wang expressly recognizes that the stability of hydrogel entrapped enzymes may be optimized by removing water from the hydrogel (FF 5), that thermal pretreatment removes water (FF 6) and improves stability relative to organic solvents (FF 9), and that factors involved in the optimization of water removal by heat treatment include “the degree of temperature” and “the period of time for heat treatment” (FF 6). “[WJhere the general conditions of a claim are disclosed in the prior art, it is not inventive to discover the optimum or workable ranges by routine experimentation.” In re Alter, 220 F.2d 454, 456 (CCPA 1955). This rule is appropriate in cases such as this one where the optimized variables of temperature and time for removal of water from enzyme containing hydrogels were identified by the art as “result-effective variable[s].” In re Applied Materials, Inc., 692 F.3d 1289, 1295 (Fed. Cir. 2012) (citing In re Antonie, 559 F.2d 618, 620 (CCPA 1977)). In addition, Wang recognizes that stability is not solely related to elevated temperature but may also be related to chemical conditions such as acidity (FF 1), and Wang specifically identifies stressors including organic solvents that may be addressed by increased stability (FF 8). Example 9 of Wang demonstrates improved stability of heat pretreated hydrogel 7 Appeal 2014-009545 Application 13/856,244 encapsulated enzymes when exposed to an organic solvent relative to untreated enzymes (FF 9). Appellants contend that “one of skill in the art would be dissuaded from adding an air drying step from the teaching of Wang et al. as paragraph [0063] clearly teaches that all water is removed by 24 hours” (App. Br. 3). We do not find this argument persuasive because there is no statement in paragraph 63 of Wang that all water is removed by 24 hours (see Wang 1 63; cf Ans. 13). Moreover, a teaching away requires a reference to actually criticize, discredit, or otherwise discourage the claimed solution. See In re Fulton, 391 F.3d 1195, 1201 (Fed. Cir. 2004) (“The prior art’s mere disclosure of more than one alternative does not constitute a teaching away from any of these alternatives because such disclosure does not criticize, discredit, or otherwise discourage the solution claimed”). Here, Wang teaches towards the invention by suggesting treatment may extend to “7 days in length” (FF 7). Appellants contend that “[njowhere does Lee et al. suggest lengthening the air drying step to one week, that a one week air drying step will improve enzyme stability at all, or that organic solvent stability can be achieved” (App. Br. 4). Appellants contend that “one looking to trap an enzyme in a hydrogel matrix to stabilize its solvent exposed activity would not look to Lee et al. for any teaching” (App. Br. 4) We do not find this argument persuasive because Lee is relied upon by the Examiner to demonstrate a drying process for hydrogel encapsulated enzymes that utilizes both oven drying and air drying (FF 11), not for specifically teaching the period of time for air drying. Moreover, it is Wang 8 Appeal 2014-009545 Application 13/856,244 that teaches drying increases half-life of hydrogel encapsulated enzymes (FF 4—5). “Non-obviousness cannot be established by attacking references individually where the rejection is based upon the teachings of a combination of references.” In re Merck & Co., 800 F.2d 1091, 1097 (Fed. Cir. 1986). A reference “must be read, not in isolation, but for what it fairly teaches in combination with the prior art as a whole.” Id. Appellants contend that “[n]o variable is taught as affecting the stabilization of an enzyme against inactivation by an organic solvent as is the crux of all pending claims” (App. Br. 6). We are not persuaded. We recognize that the Examiner’s reason for optimizing stability of pretreating hydrogel encapsulated enzymes “at temperatures of from 20 to 110 degrees Celsius for time periods of from 24 hours to 7 days in length” (FF 7) may not be identical to Appellants’ reasons for performing the same steps, though Wang specifically identifies stressors including organic solvents that may be addressed by heat treatment for increased stability (FF 8—9). However, that the prior art has a different reason or motivation is of no moment as long as there is a sufficient reason to perform the same water removing process on the same hydrogel encapsulated enzyme material for the same period of time. See In re Kemps, 97 F.3d 1427, 1430 (Fed. Cir. 1996) (“[T]he motivation in the prior art to combine the references does not have to be identical to that of the applicant to establish obviousness.”). Appellants contend the “addition of such a drying time is not taught or suggested by any cited reference, and the claimed lengthy drying time is not a variable expected to provide solvent stability to a hydrogel entrapped 9 Appeal 2014-009545 Application 13/856,244 enzyme. It is submitted that Examiner’s conclusion is nothing more than improper hindsight bias” (App. Br. 6). We are not persuaded. While we are fully aware that hindsight bias may plague determinations of obviousness, Graham v. John Deere Co., 383 U.S. 1, 36 (1966), we are also mindful that the Supreme Court has clearly stated that the “combination of familiar elements according to known methods is likely to be obvious when it does no more than yield predictable results.” KSR, 550 U.S. at 416. In the instant case, removing water from hydrogels with encapsulated enzymes by both air drying and oven drying as taught by Lee (FF 11) by selecting times and temperatures expressly within the ranges taught by Wang (FF 5—7) against stressors including organic solvents (FF 8—9), supports the Examiner’s position because a “prima facie case of obviousness typically exists when the ranges . . . overlap the ranges disclosed in the prior art.” In re Peterson, 315 F.3d 1325, 1329 (Fed. Cir. 2003). Appellants provide no evidence of any secondary consideration or unexpected results to weigh with the prima facie case of obviousness. Conclusions of Law The evidence of record supports the Examiner’s conclusion that the Wang and Lee references render obvious a process of stabilizing a hydrogel encapsulated enzyme by “air drying at room temperature for one week” after oven drying as required by claim 1. 10 Appeal 2014-009545 Application 13/856,244 SUMMARY In summary, we affirm the rejection of claim 1 under 35 U.S.C. § 103(a) as obvious over Wang and Lee. Claims 2—5 and 7—9 fall with claim 1. 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 11