11380842 (P.T.A.B. Oct. 11, 2012)

Ex Parte Ghanem et al

Patent Trial and Appeal BoardOct 11, 2012

11380842 (P.T.A.B. Oct. 11, 2012)

UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ Ex parte RAJA N. GHANEM, ROBERT W. STADLER, and XUSHENG ZHANG ____________ Appeal 2010-010148 Application 11/380,842 Technology Center 3700 ____________ Before LINDA E. HORNER, PATRICK R. SCANLON, and BRADFORD E. KILE, Administrative Patent Judges. HORNER, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Raja N. Ghanem et al. (Appellants) seek our review under 35 U.S.C. § 134 of the Examiner’s decision rejecting claims 1-4 and 6-22. We have jurisdiction under 35 U.S.C. § 6(b). We REVERSE. Appeal 2010-010148 Application 11/380,842 2 THE INVENTION Appellants’ claimed invention relates to “a method and apparatus for detecting arrhythmias in a subcutaneous medical device.” Spec., para. [0003]. Claims 1, 21, and 22 are independent. Claim 1, reproduced below, is representative of the subject matter on appeal. 1. A method of detecting a cardiac event by a medical device, comprising: sensing cardiac signals from a plurality of electrodes, the plurality of electrodes forming a first sensing vector and a second sensing vector; separately identifying the first sensing vector and the second sensing vector as being corrupted by noise in response to determining a signal energy content metric of corresponding sensed cardiac signals not being within predetermined limits; separately identifying the first sensing vector and the second sensing vector as being corrupted by noise in response to determining a noise to signal ratio of corresponding sensed cardiac signals not being less than a signal to noise threshold; separately identifying the first sensing vector and the second sensing vector as being corrupted by noise in response to determining corresponding sensed cardiac signals being associated with muscle noise; separately identifying the first sensing vector and the second sensing vector as being corrupted by noise in response to determining a mean frequency of corresponding sensed cardiac signals not being less than a mean frequency threshold; otherwise, separately identifying the first sensing vector and the second sensing vector as not being corrupted by noise; and delivering therapy via the device in response to the identifying. Appeal 2010-010148 Application 11/380,842 3 THE EVIDENCE The Examiner relies upon the following evidence: Hartley US 5,957,857 Sep. 28, 1999 Kohler US 2002/0058878 A1 May 16, 2002 Stratbucker US 6,532,379 B2 Mar. 11, 2003 Ostroff US 2004/0254613 A1 Dec. 16, 2004 THE REJECTIONS Appellants seek review of the following rejections:1 1. Claims 1-4, 6-8, 10, 11, and 13-22 are rejected under 35 U.S.C. § 103(a) as being unpatentable over Kohler and Ostroff. 2. Claim 9 is rejected under 35 U.S.C. § 103(a) as being unpatentable over Kohler, Ostroff, and Hartley. 3. Claim 12 is rejected under 35 U.S.C. § 103(a) as being unpatentable over Kohler, Ostroff, and Stratbucker. ISSUE The Examiner determined that Kohler discloses a method of detecting a cardiac event that includes determining whether a mean frequency corresponding to the sensed cardiac signals is less than a mean frequency threshold. Ans. 5 (citing Kohler, paras. [0014], [0016]). See also Ans. 17- 18 (citing Kohler, para. [0030]). Appellants argue that “[a] mean frequency is a precise term and definition, i.e., the average frequency of the signal, and Kohler et al ‘878 1 The Examiner withdrew the following provisional rejections based on non- statutory, obviousness-type double patenting: claims 1-15 over claims 1-18 of Application 11/380,815; claims 16-18 over claims 1-5 of Application 11/380,815; and claims 1-4 and 6-22 over claims 1-26 of Application 11/380,823. Ans. 3, 16; Final Office Action 2-3. Appeal 2010-010148 Application 11/380,842 4 does not show, disclose or suggest ever determining such a value.” App. Br. 17. The issue presented by this appeal is: Does Kohler disclose a method of detecting a cardiac event that includes determining whether a mean frequency corresponding to the sensed cardiac signals is not less than a mean frequency threshold? ANALYSIS Independent claim 1 calls for a method of detecting a cardiac event by a medical device comprising “separately identifying the first sensing vector and the second sensing vector as being corrupted by noise in response to determining a mean frequency of corresponding sensed cardiac signals not being less than a mean frequency threshold.” Independent claim 21 is directed to a computer readable medium having computer executable instructions for performing a method comprising the same step as set forth above in claim 1. Claim 22 is directed to a medical device comprising means for performing the substantially same step as set forth above in claim 1. The Specification describes that “[t]he mean frequency of the signal during the 3 second segment for each channel ECG1 and ECG2 is generated, for example, by calculating the ratio of the mean absolute amplitude of the first derivative of the 3 second segment to the mean absolute amplitude of the 3 second segment, multiplied by a constant scaling factor.” Spec., para. [0095]. The Specification explains that “[i]f the mean frequency is determined to be greater than or equal to the predetermined mean frequency threshold, . . ., the three second segment for that channel is identified as being likely corrupted with noise.” Id. As such, the description of the Appeal 2010-010148 Application 11/380,842 5 calculation of mean frequency provided in the Specification is consistent with Appellants’ proffered definition of mean frequency as “the average frequency of the signal.” App. Br. 17. Appellants argue that Kohler’s disclosure of comparing a number of zero-crossings with a threshold is not the same as determining a mean frequency of a signal. App. Br. 18. We agree with Appellants. Kohler’s method uses the morphology of the QRS complex, which is characterized by a relative high-amplitude oscillation that markedly guides the signal curve away from the zero line of the electrocardiogram, as compared to other signal segments, to identify the QRS complex based on a zero crossing count. Kohler, para. [0015]. Kohler describes that “[t]he differentiation between a QRS complex and the other signal segments can thus be detected with a frequency measurement that can be described representatively, based on the discussed signal characteristics, by the number of zero crossings per defined evaluated segment.” Kohler, para. [0016]. Kohler states that “[t]he zero crossing count produces a number that is nearly proportional to the given dominant frequency of the signal.” Id. As disclosed in Kohler, the use of the zero crossing count merely serves as a surrogate for the dominant frequency of the signal, and thus Kohler’s system does not determine a mean frequency of sensed cardiac signals and compare this frequency to a mean frequency threshold. As such, the Examiner erred in the finding as to the scope and content of Kohler on which the determination of obviousness of claims 1, 21, and 22 was based. Accordingly, we do not sustain the rejection of independent claims 1, 21, and 22, or dependent claims 2-4, 6-8, 10, 11, and 13-20, under 35 U.S.C. § 103(a) as being unpatentable over Kohler and Ostroff. Appeal 2010-010148 Application 11/380,842 6 The rejection of claim 9 based on Kohler, Ostroff, and Hartley and the rejection of claim 12 based on Kohler, Ostroff, and Stratbucker both suffer from the same erroneous finding as to the scope and content of Kohler as set forth supra. The Examiner did not rely on Hartley or Stratbucker to disclose determining the mean frequency of sensed cardiac signals and comparing that mean frequency to a threshold. Ans. 14-15. As such, we do not sustain the rejections of dependent claims 9 and 12 for the same reasons set forth supra in our analysis of independent claim 1. CONCLUSION Kohler does not disclose a method of detecting a cardiac event that includes determining whether a mean frequency corresponding to the sensed cardiac signals is not less than a mean frequency threshold. DECISION We REVERSE the decision of the Examiner to reject claims 1-4 and 6-22. REVERSED Klh