Ex Parte BUELOW et alDownload PDFPatent Trial and Appeal BoardJan 25, 201914334176 (P.T.A.B. Jan. 25, 2019) Copy Citation UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE FIRST NAMED INVENTOR 14/334,176 07/17/2014 THOMAS BUELOW 24737 7590 01/29/2019 PHILIPS INTELLECTUAL PROPERTY & STANDARDS 465 Columbus A venue Suite 340 Valhalla, NY 10595 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. 2005P00340US 4812 EXAMINER HOFFA, ANGELA MARIE ART UNIT PAPER NUMBER 3793 NOTIFICATION DATE DELIVERY MODE 01/29/2019 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): patti. demichele@Philips.com marianne.fox@philips.com katelyn.mulroy@philips.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte THOMAS BUELOW, RAFAEL WIEMKER, CRISTIAN LORENZ, STEFFEN RENISCH, and THOMAS BLAFFERT 1 Appeal2018-002744 Application 14/334, 17 6 Technology Center 3700 Before DANIEL S. SONG, JAMES P. CAL VE, and AR THUR M. PESLAK, Administrative Patent Judges. SONG, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE The Appellant appeals under 35 U.S.C. § 134(a) from the Examiner's Final Office Action ("Final Act.") rejecting claims 1, 6-10, and 15-19 in the present application. (App. Br. 10-12, Claims App.). We have jurisdiction under 35 U.S.C. §§ 6(b) and 134(a). We REVERSE. 1 The Appellant is the Applicant, Koninklijke Philips N.V., which is identified as the real party in interest (Appeal Brief ("App. Br.") 2). Appeal2018-002744 Application 14/334, 17 6 The claimed invention is directed to "[ a ]n imaging method for identifying abnormal tissue in the lung." (Abstract). Representative independent claim 1 reads as follows (App. Br. 10, Claims App., emphasis added): 1. A method, comprising recording slice images of a lung through X-ray radiation to produce slice images of the lung, each slice image corresponds to a different position of the lung, where at least one slice image of the slice images includes lung cavity, blood vessels and an abnormal tissue, wherein the lung cavity, the blood vessels and the abnormal tissue are represented through gray-scale values; segmenting the blood vessels in the slice images of the lung, wherein the gray-scale values of the blood vessels are differentiated from the gray-scale values of the abnormal tissue through eigenvalues of a Hessian matrix; removing the segmented blood vessels from the slice images of the lung; and displaying at least one of the slice images of the lung with the removed segmented blood vessels on an output device. Independent claim 10 is directed to a computer tomograph that performs the method as substantially claimed in claim 1, and independent claim 19 is directed to a computer readable storage medium having instructions for causing a processor to perform the method as substantially claimed in claim 1. (App. Br. 10, Claims App. 11-12). 2 Appeal2018-002744 Application 14/334, 17 6 REJECTION The Examiner rejects claims 1, 6-10, and 15-192 under 35 U.S.C. § 103 as obvious over Lin et al. (US 2004/0151356 Al, pub. Aug. 5, 2004 ("Lin")) in view of Reeves et al. (US 2004/0252870 Al, pub. Dec. 16, 2004 ("Reeves")). (Final Act. 5). ANALYSIS In rejecting the claims, the Examiner finds that Lin discloses the invention as substantially recited in claim 1, including wherein "the blood vessels and the abnormal tissues are represented through gray-scale values" and "identifying the blood vessels in the slice images of the lung ... wherein the gray-scale values of the blood vessels are differentiated from the gray- scale values of the abnormal tissue through eigenvalues of a Hessian matrix." (Final Act. 5---6). In that regard, the Examiner finds the identification of blood vessels to be satisfied by Lin's disclosure of "enhancement filters; fig. 1 Ob shows enhancement of abnormal tissue/nodules created in S23, fig. 2; fig. 10c shows enhancement of blood vessels created in S25, fig. 2; par. 0133-0142 teach eigenvalues of a Hessian matrix." (Id.). The Examiner also finds that it is unclear if Li teaches "segmenting" the blood vessels. Image segmentation is generally known in the art as partitioning image pixels and classifying the pixels into defined segments. Li demonstrates pixel assignment/segmentation of candidate nodules (S28, fig. 2) but does not expressly teach segmentation of entire blood vessels. Instead, only the blood vessel features 2 Claim 21 has been canceled. (App. Br. 10-12, Claims App.). 3 Appeal2018-002744 Application 14/334, 17 6 that overlap with the initial nodule candidates (S24, fig. 2) are clearly segmented (S26, fig. 2). (Final Act. 5-6; see also Answer ("Ans.") 3--4). To remedy this deficiency, the Examiner finds that Reeves discloses "segmentation of blood vessels from the C[ omputed] T[ omography] image data (fig. 8, par. 0055, 0089)," and removing "segmented structures adjacent to structures of interest (i.e. nodules)" to "enhance the display of the structures of interest (i.e. nodules) (par. 0105)." (Final Act. 6). The Examiner concludes that it would have been obvious to one of ordinary skill in the art to have provided "the line-enhanced image of Li as a blood vessel segmentation image in order to enhance the display of structures of interest (i.e. nodules) as taught by Reeves." (Final Act. 6). The Appellant argues that the rejection is inadequate because "Li discloses segmenting nodules and not blood vessels." (App. Br. 5, citing Li ,r 142; see also App. Br. 6 ("Li cannot remove something that is not detected"); Reply Br. 3). The Appellant also argues that "Li does not disclose segmenting blood vessels and then removing the segmented blood vessels from the image." (App. Br. 6, citing Li ,r 142). However, these arguments are not persuasive in view of the Appellant's Specification, which utilizes the term "segmentation" to refer to the broader process of identifying particular structure from an image, for removal, for example. (Spec. 1, 11. 27-29 ("known segmentation methods, in which slice images of structures of the object to be examined are subtracted from one another and individual structures are thereby removed from the resulting image"); 5, 1. 33---6, 1. 1 ("After recording the tomograms, interfering structures of the body are segmented, for instance, the heart or 4 Appeal2018-002744 Application 14/334, 17 6 the thoracic cage, that is, these are removed from the image"); 6, 1. 4--5 ("After segmentation of the structures of the body, the lung cavity 5 and the blood vessels 6 are left, as illustrated")). The Examiner explains that "Li creates a blood vessel image (i.e. line image) as shown in Fig. 1 OC. This can be considered a type of blood vessel 'segmentation' image because pixel values are assigned only to structures representing lines (i.e. blood vessels)." (Ans. 6). This image is "compared to the nodule candidate image" and "removed from the final nodule candidate image." (Ans. 6). In order for the invention of Li to identify and display the nodules, the remaining structures of the lung, including the blood vessels, must be identified for removal. Accordingly, we agree with the Examiner that "boundaries of blood vessels are implicitly determined in a segmentation image to demonstrate blood vessel/not blood vessel interface." (Ans. 8). The Appellant rebuts that "Li does not disclose, suggest or imply segmenting blood vessels where the gray-scale values of the blood vessels are differentiated from gray-scale values of abnormal tissue." (Reply Br. 2). According to the Appellant, there is no indication that "line enhanced image" or "image filtering" as disclosed in Li would be understood by those of ordinary skill in the art as segmentation based on grey-scale values (Reply Br. 2). We find the Appellant's contention to be persuasive and determine that the rejection as presently set forth is inadequate. While Li discloses segmentation in the sense of identifying non-nodule structure in the lungs, it utilizes filtering to enhance images to do so such that better identification of nodules can be attained. While the claims recite a specific manner of attaining segmentation, Li discloses applying dot, line, and 5 Appeal2018-002744 Application 14/334, 17 6 plane filters to enhance the image and to distinguish nodules from other structures within the lung. (Li ,r,r 44--47, 50-54, 140, 142). We do not understand, nor has the Examiner adequately explained, how a filter-enhanced image disclosed in Li is an image "wherein the gray-scale values of the blood vessels are differentiated from the gray-scale values of the abnormal tissue" as required by the claims. The claims further require the displaying of "at least one slice image of the lung with the removed segmented blood vessels on an output device." (See e.g., App. Br. 10, Claims App. (claim 1)). It is unclear from the Examiner's rejection where Li discloses such a display. The Examiner explains that "Li suggests display of image of nodules (i.e. an image with blood vessels removed) because it is the intended use of his invention. As shown in Fig. 2, step S28 results in a nodule image wherein the blood vessels have been removed." (Ans. 7). However, the image displayed are 3- D images of just the nodules as generated using the disclosed enhancement filters, and are not two-dimensional slice images of the lung with segmented blood vessels removed as claimed. The Appellant also argues that "Reeves does not cure the deficiencies of Li." (App. Br. 5). We generally agree. While the Examiner explains that Reeves "teaches that a blood vessel segmentation image, analogous to the line image of Li, is subtracted from a lung image" such that "only nodule candidates remain" (Ans. 6-7), such general disclosure, as applied by the Examiner, does not adequately address the above-noted deficiencies of Li pertaining to gray-scale, and display of at least one of the slice images of the lung with the blood vessels removed. In that regard, the Appellant is correct 6 Appeal2018-002744 Application 14/334, 17 6 that Reeves eliminates "structures which are not nodules, which suggests that lung cavity and nodules are not included together in any image contrary to the claim limitations." (Reply Br. 4). According to the Examiner: [ A ]s evidenced by Li, Reeves, and the lack of detail in Appellant's disclosure, one of ordinary skill would recognize that image segmentation is highly routine in the art and provides highly predictable results. The steps of the claimed method do not appear to provide any technical advantage or benefit over that which is taught by Li and Reeves and generally known by one of ordinary skill in the image processing art. (Ans. 7). However, the Appellant is correct that a proper rejection is "not based on advantage or benefit" (Reply Br. 3), but instead, must be based on the claim language and the prior art as understood by those of ordinary skill. Finally, the Examiner also responds that "[ o ]ne of ordinary skill in the art would also find it routine to selectively highlight the desired tissues for display (e.g. lung cavity, nodules, blood vessels)." (Ans. 8). While this reasoning may be true, it is still inadequate to address the deficiencies of Li, and the Examiner's rejection as noted above. To be clear, the record indicates the use of gray-scale values to differentiate the lung from other structures in the body appears to be well-known in the art. For example, step S22 labeled "Lung Segmentation" in Figure 2 of Li discloses such a technique. (See also Li ,r,r 140, 142). Nonetheless, the rejection, as presently articulated, does not adequately address the actual claim language pertaining to the recited segmentation and displaying. 7 Appeal2018-002744 Application 14/334, 17 6 As noted by the Appellant "[ c ]laims 10 and 19 include similar limitations" to those of claim 1. (App. Br. 6). Therefore, in view of the above considerations, we reverse the Examiner's rejections of claims 1, 10, and 19. The remaining claims depend from one of these independent claims, and as such, we also reverse the rejection of these claims as well. CONCLUSION The Examiner's rejection is REVERSED. REVERSED 8 Copy with citationCopy as parenthetical citation
