12580113 (P.T.A.B. Feb. 27, 2017)

Ex Parte Lang et al

Patent Trial and Appeal BoardFeb 27, 2017

12580113 (P.T.A.B. Feb. 27, 2017)

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. 12/580,113 10/15/2009 Christoph Lang 1576-0264 9675 28078 7590 02/28/2017 MAGINOT, MOORE & BECK, LLP One Indiana Square, Suite 2200 INDIANAPOLIS, IN 46204 EXAMINER CRAWFORD, ERIK B ART UNIT PAPER NUMBER 1677 MAIL DATE DELIVERY MODE 02/28/2017 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 CHRISTOPH LANG, SAM KAVUSI, DANIEL ROSER, and AMIRALI HAJ HOSSEIN TALASAZ __________ Appeal 2014-001444 Application 12/580,113 Technology Center 1600 __________ Before JEFFREY N. FREDMAN, DEBORAH KATZ, and JACQUELINE T. HARLOW, Administrative Patent Judges. FREDMAN, Administrative Patent Judge. DECISION ON APPEAL This is an appeal1 under 35 U.S.C. § 134 involving claims to a method of detecting a biomarker. The Examiner rejected the claims as anticipated and as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. Statement of the Case Background “Diagnostic tests that can be performed at the point of care of an individual, such as at the bedside of a patient . . . are becoming increasingly popular. Diagnostic tests include tests directed to identifying biomarkers 1 Appellants identify the Real Party in Interest as Robert Bosch GmbH (see App. Br. 1). Appeal 2014-001444 Application 12/580,113 2 such as Nucleic Acid, protein, and small molecules” (Spec. ¶ 2). A “need exists for low cost assays including multiplexed assays, protein arrays, lateral flow devices, sandwich assays, competitive assays, or bead based arrays which provide accurate results and a method of using such arrays” (Spec. ¶ 12). The Claims Claims 1–11 are on appeal. Claim 1 is representative and reads as follows: 1. A method of detecting a biomarker comprising: identifying a quantity of biomolecule types in a sample; exposing the sample to a plurality of test sites, wherein the number of test sites in the plurality of test sites is equal to or greater than the identified quantity of biomolecule types; establishing, for each of the plurality of test sites, a respective test environment, wherein the test environment for each of the plurality of test sites is different from the test environment for each of the other of the plurality of test sites, and each of the plurality of test sites is configured to capture each of the biomolecule types; obtaining a detection signal associated with each of the plurality of test sites; and determining the concentration of one of the biomolecule types based upon the obtained detection signals. Appeal 2014-001444 Application 12/580,113 3 The Issues A. The Examiner rejected claims 1, 4, 5, and 11 under 35 U.S.C. § 102(b) as anticipated by Dufva2 (Final Act. 2–3). B. The Examiner rejected claim 2 under 35 U.S.C. § 103(a) as obvious over Dufva and Xie3 (Final Act. 4–5). C. The Examiner rejected claim 3 under 35 U.S.C. § 103(a) as obvious over Dufva, Xie, and Dowd4 (Final Act. 5–6). D. The Examiner rejected claims 6–9 under 35 U.S.C. § 103(a) as obvious over Dufva and Banerjee5 (Final Act. 6–8). E. The Examiner rejected claim 10 under 35 U.S.C. § 103(a) as obvious over Dufva, Banerjee, and Matson6 (Final Act. 8–9). A. 35 U.S.C. § 102(b) over Dufva The issue with respect to this rejection is: Does the evidence of record support the Examiner’s conclusion that the Dufva anticipates claim 1? Findings of Fact 1. Dufva teaches “on one and the same solid support it is possible to quantitatively compare e.g. pairs of mutant versus wild type genes representing both very strong and very [weak] spots, just in different spatial 2 Dufva et al., WO 2007/062666 A1, published June 7, 2007 (“Dufva”). 3 Xie et al., US 7,087,373 B2, issued Aug. 8, 2006 (“Xie”). 4 Dowd et al., US 2009/0061535 A1, published Mar. 5, 2009 (“Dowd”). 5 Banerjee et al., US 7,892,854 B2, issued Feb. 22, 2011 (“Banerjee”). 6 Matson et al., US 2003/0198967 A1, published Oct. 23, 2003 (“Matson”). Appeal 2014-001444 Application 12/580,113 4 positions of the array corresponding to different washing conditions” (Dufva 17:4–8). 2. Dufva teaches “an easy and flexible platform for conducting an assay of chemical entities and determining optimum assay parameters” that operates “[b]y varying the assay conditions (parameters) within the one or more chambers the chemical entities on the solid support can be exposed to a range of assay conditions” (Dufva 10:4–25). 3. Figure 24 of Dufva is reproduced below: “Fig. 24 shows possible locations of subarrays of chemical entitites (41) on an asymetric solid support (40). The chambers (21) of the device should be located in such a way that the subarrays can be subjected to different conditions” (Dufva 42:5–8). 4. Figure 25 of Dufva is reproduced below: Appeal 2014-001444 Application 12/580,113 5 Fig. 25 shows the combination of a chemical gradient and thermal gradient where the chemical gradient is created on each slide and the respective solid support (40) is treated with different temperatures . . . we can investigate the chemical gradient at up to twelve different temperatures provided that each temperature block (500) can be controlled individually. The figure shows a device that can investigate eight different chemical conditions at two different temperatures. (Dufva 43:4–17). 5. Dufva teaches “the device is formed in a way and from a material which makes it possible to detect a signal, and the device furthermore includes means for detecting a signal” (Dufva 23:1–3). 6. Dufva teaches that after capture and washing, there is “analysis of the locations and amount of the remaining bound analyte on the solid support” (Dufva 19:23–24). 7. Dufva teaches the “type and amount of analyte present in the sample is then determined by detecting the location and amount of specific binding on the microarray spots” (Dufva 2:8–10). Appeal 2014-001444 Application 12/580,113 6 8. Dufva teaches: It is for example possible to determine the IC50 dose for various interacting chemical entities such as a drug-target interaction. The IC50 represents the efficacy of a drug or inhibitor, where IC50 is the concentration required to produce 50% inhibition. In this case, a dilution series of the drug is created with which the target molecules attached to the solid support are in functional contact. (Dufva 17:21–26). 9. Figure 16 of Dufva is reproduced below: “Figure 16 shows images of fluorescently labelled DNA microarray after stringent washing at different temperatures provided by the device” (Dufva 24:29–30). Principles of Law Anticipation under 35 U.S.C. § 102 requires that “‘each and every element as set forth in the claim is found, either expressly or inherently described, in a single prior art reference.”’ In re Robertson, 169 F.3d 743, 745 (Fed. Cir. 1999). Analysis We adopt the Examiner’s findings of fact and reasoning regarding the scope and content of the prior art (Final Act. 2–3; FF 1–9) and agree that claim 1 is anticipated by Dufva. We address Appellants’ arguments below. Appeal 2014-001444 Application 12/580,113 7 Appellants contend that “[n]one of the passages or figures identified by the Examiner disclose a method for calculating the concentration of a biomolecule type, in a sample having an unknown concentration of the biomolecule which is exposed to multiple test environments, using detection signals obtained from the multiple test sites” (App. Br. 4; cf. App. Br. 5–7, 9–14). Appellants specifically contend “[t]here is no disclosure, however, of any calculations. Generally obtaining a signal from a capture probe is not the same as calculating the concentration of a biomolecule type” (App. Br. 8). We begin our analysis with the claim language because the “name of the game is the claim.” In re Hiniker Co., 150 F.3d 1362, 1369 (Fed. Cir. 1998). Claim 1 includes no limitations requiring either a “calculating” step or a sample with an “unknown concentration.” While we read the claims in light of the Specification, “limitations are not to be read into the claims from the specification.” In re Van Geuns, 988 F.2d 1181, 1184 (Fed. Cir. 1993). The Specification does not define the “determining the concentration” step as requiring calculations and claim 1 does not recite that the concentration must be determined by calculation rather than observation of a dilution series or other approaches. Therefore, we do not find Appellants’ argument persuasive that the claim requires a “calculating” step. See In re Self, 671 F.2d 1344, 1348 (CCPA 1982) (“[A]ppellant’s arguments fail from the outset because . . . they are not based on limitations appearing in the claims.”) We interpret the claim as simply requiring “determining the concentration” by some process that need not include calculation. Appeal 2014-001444 Application 12/580,113 8 The Specification teaches an example using known concentrations of AB diamond antibody (Spec. ¶ 55), and provides no definition that requires the concentration of the target to be unknown (cf. Reply Br. 4 acknowledging “it is theoretically possible to start with a known concentration” for “validation of the Appellants’ disclosed process”). Claim 1 also lacks a limitation that requires the analyte to have an “unknown concentration.” In re Self, 671 F.2d at 1348. Therefore, we interpret claim 1 to encompass analysis of both known and unknown concentrations. Applying these interpretations to Dufva’s disclosure, Dufva teaches to “quantitatively compare” biomarkers (FF 1) by conducting assays on the samples (FF 2) including exposing the samples to multiple test sites with multiple different test environments (FF 2–4), obtaining detection signals (FF 5) to obtain information on the “amount of the remaining bound analyte on the solid support” (FF 6). Dufva further teaches the “determining the concentration” step by testing a dilution series to determine an IC50 concentration (FF 8). Dufva specifically teaches that “IC50 is the concentration required to produce 50% inhibition” (FF 8). Thus, when Dufva performs the assay as disclosed to obtain an IC50 value, Dufva determines a concentration, the IC50 concentration, of the drug based upon the signals, reasonably satisfying the “determining the concentration” limitation of claim 1. See In re Zletz, 893 F.2d 319, 321 (Fed. Cir. 1989) (“[D]uring patent prosecution when claims can be amended, ambiguities should be recognized, scope and breadth of language explored, and clarification imposed.”) Appeal 2014-001444 Application 12/580,113 9 We recognize, but find unpersuasive, Appellants’ contention that a “determination that is based upon a single signal as alleged by the Examiner to be present in the prior art, is not the same as a determination based upon at least two signals as required by claim 1” (Reply Br. 2). Whether the dilution series (FF 8) or visual changes shown in Figure 16 (FF 9), multiple signals are used. In the case of the dilution series, the word “series” as a plural teaches multiple signals. In Figure 16, each hybridization has two signals for wildtype and two for mutant (FF 9, cf. FF 1). This is shown, for example, by the top row in Figure 16 of CD8/9 at the first temperature condition of 22 °C, 24 °C, 26 °C, where there are two wildtype hybridizations and two mutant hybridizations that both give signal, with a reduced signal for the mutants at 28 °C, and where the two mutant signals do not appear in the 30 °C, 32 °C, and 34 °C temperature conditions (FF 9). We also recognize, but find unpersuasive, Appellants contention that “the Examiner has failed to identify any disclosure in Dufva of establishing a concentration using at least two detection signals. For example, in the newly proffered ‘visual examination’, only one color at a time is compared to the color scale” (Reply Br. 5). Dufva teaches comparing pairs of mutant and pairs of wildtype signals quantitatively, thereby expressly teaching the use of two detection signals (FF 1; cf. FF 9). Conclusion of Law The evidence of record support the Examiner’s conclusion that Dufva anticipates claim 1. Appeal 2014-001444 Application 12/580,113 10 B. 35 U.S.C. § 103(a) over Dufva and Xie Appellants contend “Xie discloses using a single binding affinity Kd. A method which uses a single binding affinity in calculating a concentration of an analyte is not the same as a method which uses two different binding efficiencies for the analyte in calculating a concentration of an analyte” (App. Br. 16). The Examiner responds: Dufva et al. (WO 2007/062666 A1) discloses a method for determining the amount of a biomolecule type in a sample which is exposed to multiple test environments, using signals obtained from the multiple test sites. Xie et al. (US 7,087,373 B2) is relied upon for teaching that quantification of the concentration of an analyte may be performed by direct measurement of binding affinity of the analyte and calculating the concentration based on said binding affinity. Thus, one of ordinary skill in the art would recognize that upon determining the binding affinity of an analyte for each respective test environment in the method of Dufva et al. it would be beneficial to determine the concentration of an analyte based on each determined binding affinity in order to provide a redundancy in the concentration calculation that improves confidence in the obtained results. (Ans. 22). We find that the Examiner has the better position. As already noted, Dufva teaches “to quantitatively compare e.g. pairs of mutant versus wild type genes” (FF 1), while Xie teaches “quantification of the concentration of protease inhibitor in free form maybe performed by direct measurement of binding affinity Kd using isothermal titration calorimetry; and calculating the concentration” (Xie 6:66 to 7:2). We agree with the Examiner that, given Dufva’s express teaching to use pairs of data points for quantitative Appeal 2014-001444 Application 12/580,113 11 comparison and Xie’s teaching to calculate the concentration based on quantitation information, the ordinary artisan would have found it obvious to use both data points for “improve[d] confidence in the obtained [concentration] results” (Ans. 22). C.-E. 35 U.S.C. § 103(a) Appellants do not separately argue these obviousness rejections, instead relying upon their arguments to overcome Dufva or Dufva and Xie (see App. Br. 17–18). The Examiner provides sound fact-based reasoning for combining Dufva and Xie with Dowd, Banerjee, and Matson (see Final Act. 5–9). Having affirmed the anticipation rejection of claim 1 over Dufva and the obviousness rejection of claim 2 over Dufva and Xie for the reasons given above, we also find that the further combinations render the rejected claims obvious for the reasons given by the Examiner. SUMMARY In summary, we affirm the rejection of claim 1 under 35 U.S.C. § 102(b) as anticipated by Dufva. Claims 4, 5, and 11 fall with claim 1. We affirm the rejection of claim 2 under 35 U.S.C. § 103(a) as obvious over Dufva and Xie. We affirm the rejection of claim 3 under 35 U.S.C. § 103(a) as obvious over Dufva, Xie, and Dowd. We affirm the rejection of claims 6–9 under 35 U.S.C. § 103(a) as obvious over Dufva and Banerjee. We affirm the rejection of claim 10 under 35 U.S.C. § 103(a) as obvious over Dufva, Banerjee, and Matson. Appeal 2014-001444 Application 12/580,113 12 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