Ex Parte John et alDownload PDFPatent Trial and Appeal BoardDec 17, 201814177340 (P.T.A.B. Dec. 17, 2018) Copy Citation UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 14/177,340 02/11/2014 28524 7590 12/19/2018 SIEMENS CORPORATION INTELLECTUAL PROPERTY DEPARTMENT 3501 Quadrangle Blvd Ste 230 Orlando, FL 32817 FIRST NAMED INVENTOR Matthias John 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. 2013P02992US01 4028 EXAMINER TURCHEN, ROCHELLE DEANNA ART UNIT PAPER NUMBER 3793 NOTIFICATION DATE DELIVERY MODE 12/19/2018 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): ipdadmin.us@siemens.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte MATTHIAS JOHN, MURRIL MICHAEL SZUCS, RAZV AN IONASEC, and ALOIS NOETTLING 1 Appeal2017-010310 Application 14/177 ,340 Technology Center 3700 Before JEFFREY N. FRED MAN, MICHAEL J. FITZPATRICK, and JOHN G. NEW, Administrative Patent Judges. NEW, Administrative Patent Judge. DECISION ON APPEAL 1 Appellants state that the real parties-in-interest are Siemens Aktiengesellschaft and Siemens Medical Solutions USA, Inc. App. Br. 1. Appeal2017-010310 Application 14/177 ,340 SUMMARY Appellants file this appeal under 35 U.S.C. § I34(a) from the Examiner's Final Rejection of claims 1-34 as unpatentable under 35 U.S.C. § 101 as being directed to nonstatutory subject matter. Specifically, claims 1, 5-9, 12, 13, 17, 18, 21, 25-29 and 32 stand rejected as unpatentable under 35 U.S.C. § I03(a) as being obvious over the combination of Boese et al. (US 2007/0021668 Al, January 25, 2007) ("Boese") and Liao et al (US 2011/0222750 Al, September 15, 2011) ("Liao"). Claims 2, 10, 11, 14, 19, 20, 22, 30 and 31 stand rejected as unpatentable under 35 U.S.C. § I03(a) as being obvious over the combination of Boese, Liao, and Grbic et al. (US 2012/0230568 Al, September 13, 2012) ("Grbic"). Claims 3, 4, 15, 16, 23, 24, 33 and 34 stand rejected as unpatentable under 35 U.S.C. § I03(a) as being obvious over the combination of Boese, Liao, and Mountney et al. (US 2012/0296202 Al, November 22, 2012) ("Mountney"). We have jurisdiction under 35 U.S.C. § 6(b). We AFFIRM. NATURE OF THE CLAIMED INVENTION Appellants' invention is directed to a method and system for determining an angulation of a C-arm image acquisition system for a cardiac intervention. Abstr. REPRESENTATIVE CLAIM Claim 1 is representative of the claims on appeal and recites: 2 Appeal2017-010310 Application 14/177 ,340 1. A method for determining an angulation of a C-arm image acquisition system for a cardiac intervention, comprising: rece1vmg a 3D ultrasound image including a cardiac reg10n; registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system; detecting a cardiac structure of interest in the registered 3D ultrasound image; and determining an angulation of the C-arm image acquisition system based on the detected structure of interest in the registered 3 D ultrasound image. App. Br. 26. ISSUES AND ANALYSES We are persuaded by, and expressly adopt, the Examiner's findings, reasoning, and conclusion that Appellants' claims are not directed to nonstatutory subject matter and are prima facie obvious over the combined cited prior art. We address the arguments raised by Appellants below. I. A. Issue REJECTIONUNDER35 U.S.C. § 101 Rejection of independent claims 1, 13, and 21 Appellants argue the Examiner erred because the claims are not drawn to a judicially-created exception, i.e., an abstract idea, to Section 101. App. Br. 3. Analysis 3 Appeal2017-010310 Application 14/177 ,340 The Examiner finds that the claims are directed to analyzing and registering acquired data. Final Act. 2. The Examiner finds that the claims do not include additional elements that are sufficient to amount to significantly more than the judicial exception, because the claims do not include additional elements that are sufficient to amount to significantly more than the judicial exception. Id. The Examiner finds that, viewed as a whole, these additional claim elements link the abstract idea to a particular environment (i.e., medical diagnostic data analysis) and do not provide any meaningful limitations to transform the abstract idea into a patent eligible application of the abstract idea, such that the claims amount to significantly more than the abstract idea itself. Id. at 2-3. The Examiner further finds that the claims do not require a particular machine, but apply the abstract idea on a generic computer or processor to perform well-understood, routine and conventional acts in the art (i.e., data acquisition and analysis). Final Act. 3. The Examiner also finds that the claims do not recite any means or steps reciting improvements to the technological field, or improvements to the functioning of the computer/ultrasound/C-arm acquisition system. Id. Appellants argue that the Examiner erred by characterizing the independent claims at a high level of abstraction untethered to language recited in the claims. App. Br. 4. Appellants point to the Federal Circuit's opinion in Enfzsh, LLC v. Microsoft Corp., 822 F.3d 1327, 1337 (Fed. Cir. 2016), in which the court noted that, when determining whether a claim is directed to an abstract idea, one should compare the claim to claims already found to be directed to an abstract idea in previous court decisions. Id. 4 Appeal2017-010310 Application 14/177 ,340 Appellants contend that the Examiner's finding that: "[t]he idea of analyzing [and] registering data can be considered to be a fundamentally basic part of human intelligence. It allows humans to make decisions through the discernment of parameter conditions" is untethered from the language of the claims. Id. (quoting Final Act. 2-3). Appellants contend that claim 1 recites a specific method for determining the angulation of a C-arm image acquisition system that requires registration of a received ultrasound image with a coordinate system of the C-arm image acquisition system, detection of a structure of interest in the registered ultrasound image, and determination of the angulation of the C-arm image acquisition system based on the detected structure of interest in the registered ultrasound image. App. Br. 5. According to Appellants, the Examiner has not established any previous court decisions in which claims directed to similar subject matter to the present claims, which are directed to determination of an angulation of interest of a C-arm image acquisition system based on detected structure of interest in a 3D ultrasound image that has been registered to a coordinate system of the C-arm image acquisition system, have been ruled to be abstract. Id. Appellants point out that examples of abstract ideas in previous court decisions have included fundamental economic practices, certain methods of organizing human activities, an idea itself, and mathematical formulas. App. Br. 5 (citing Alice Corp. Pty. Ltd. v. CLS Bank Int'!, 134 S.Ct. 2347, 2355- 57 (2014)). According to Appellants, the method recited in claim 1 is a functional and palpable application in the field of computer and medical imaging technology with a concrete and tangible result, not a basic building block of human ingenuity. Id. Appellants argue that, although independent 5 Appeal2017-010310 Application 14/177 ,340 claim 1 may require the use of various underlying mathematical relationships or formulas (e.g., to perform the registration of the ultrasound image with the coordinate system of the C-arm image acquisition system or the detection of the structure of interest), claim 1 does not claim or attempt to tie up the mathematical relationships or formulas, themselves. Id. at 6. Appellants dispute the relevance of the Examiner's reliance upon SmartGene, Inc. v. Advanced Biological Labs., SA, 555 F. App'x 950 (Fed. Cir. 2014) (nonprecedential) and Digitech Image Techs., LLC v. Elecs.for Imaging, Inc., 758 F.3d 1344 (Fed. Cir. 2014). App. Br. 6 (citing Final Office Act. 10). Appellants assert that the claims in SmartGene were directed to a method for guiding the selecting of a therapeutic treatment regimen for a patient with a known disease of medical condition. Id. ( citing SmartGene, 555 F. App'x at 952). Appellants note that, in SmartGene, the Federal Circuit ruled that the claim at issue was directed to the mental steps of comparing new and stored information and using rules to identify medical options. Id. (citing SmartGene, 555 F. App'x at 954). Furthermore, Appellants argue, the court further held that: "Our ruling is limited to the circumstances presented here, in which every step is a familiar part of the conscious process that doctors can and do perform in their heads." Id. (citing SmartGene, 555 F. App'x at 955). To the contrary, Appellants assert, claims 1, 13, and 21 are not directed to comparing new and stored information and using rules to identify medical options, and are therefore not similar to the claims at issue in SmartGene. App. Br. 6-7. Nor, argue Appellants, are they directed to an ineligible abstract process of gathering and combing data, as in Digitech. Id. at 7 (citing Digitech, 758 F.3d at 1351). 6 Appeal2017-010310 Application 14/177 ,340 Appellants further point to the Federal Circuit's holding in Enfzsh that distinguished between claims that recite an improvement in computer- related technologies and those in which general-purpose computer components are added post-hoc to a fundamental economic practice or mathematical equation. App. Br. 7 ( citing Enfzsh, 822 F.3d at 1339). According to Appellants, claim 1 is directed to an improvement in the computer-related technology of determination of an angulation of interest of a C-arm image acquisition system. Id. According to Appellants, the method of claim 1 reduces the amount of radiation and contrast agent exposure required for a patient as compared to convention techniques for determining a C-arm angulation. Id. Furthermore, Appellants argue, the method of claim 1 does not require any extra operating room setting, as in intra operative X-ray imaging. Id. Therefore, Appellants assert, claim 1 provides improvements to the computer related technology of determination of an angulation of interest of a C-arm image acquisition system. Id. Appellants therefore contend that the claims at issue are not directed to an abstract idea, and are therefore directed to a patent-eligible idea. App. Br. 8. However, Appellants argue, assuming arguendo, that the claims incorporate an exception to Section 101, the claims recite significantly more than the abstract idea itself. Id. According to Appellants, the limitations of claim 1 recite improvements to specific technologies and therefore claim significantly more than the abstract idea of "analyzing and registering acquired data." Id. at 9. By way of example, Appellants point to claim 1 's limitation reciting: "registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system." Id. Appellants assert that this limitation recites significantly more than the alleged abstract idea of 7 Appeal2017-010310 Application 14/177 ,340 "registering data" in that it requires that a 3D ultrasound image is registered to a 3D coordinate system of a C-arm image acquisition system. Id. at 4. Furthermore, Appellants argue, the limitations of claim 1 do not seek to tie up the concept of "registering data," but instead recite a specific method step of "registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system" in a method for determining an angulation of the C-arm image acquisition system. App. Br. 9. Appellants point out that claim 1 also recites the limitations of "detecting a cardiac structure of interest in the registered 3D ultrasound image" and "determining an angulation of the C-arm image acquisition system based on the detected structure of interest in the registered 3D ultrasound image." Id. Appellants argue that these limitations thus recite specific method steps that require that a structure of interest be detected in a 3 D ultrasound image that has been registered to a 3D coordinate system of the C-arm image acquisition system, and that the detected structure of interest be used as a basis for determining the angulation of the C-arm image acquisition system. Id. These limitations, argue Appellants, recite significantly more than the abstract concept of "analyzing data." Id. Appellants dispute the Examiner's finding that the limitation of claim 1 reciting "receiving a 3D ultrasound image" is an additional extra-solution activity. App. Br. 9. Appellants assert that claim 1 requires that the received 3D ultrasound image is registered to a coordinate system of the C- arm image acquisition system and requires that the structure of interest, which is used as the basis for determining the angulation of the C-arm image acquisition system, be detected in the 3D ultrasound image. Id. at 9--10. Appellants further assert the method of claim 1 does not merely recite that a 8 Appeal2017-010310 Application 14/177 ,340 computer is used to determine the angulation for a C-arm image acquisition system, but recites a specific method for how the angulation is determined for a C-arm image acquisition system. Id. We are not persuaded by Appellants' arguments. As an initial matter, we point out that whether a claim preempts a judicial exception, such as an abstract idea, is not an actual part of the test that the Supreme Court set forth in either Alice or Mayo Collaborative Servs. v. Prometheus Labs. Inc., 566 U.S. 66, 71 (2012). Rather, such preemption is acknowledged to be an outcome to be avoided by any such analysis, rather than an established step in the analytical framework itself. See Mayo, 566 U.S. at 72-73. Appellants' claims are directed to a method, i.e., a "process," and therefore fall into one of the broad statutory categories of patent-eligible subject matter under 35 U.S.C. § 101. See App. Br. 8-9. We consequently next tum to determining whether this process is patent-eligible or comes under one of the nonstatutory exceptions to Section 101. In performing such a patentability analysis under 35 U.S.C. § 101, we follow the framework set forth by the Supreme Court in Mayo. As a first step, we determine whether the claims at issue are directed to a patent- ineligible concept, i.e., a law of nature, a phenomenon of nature, or an abstract idea. Mayo, 566 U.S. at 70-71. If the claims are so directed, we next consider the elements of each claim both individually and "as an ordered combination" to determine whether additional elements "transform the nature of the claim" into a patent-eligible application. Id. at 78-79; see also Ariosa Diagnostics, Inc. v. Sequenom, Inc., 788 F.3d 1371, 1375 (Fed. Cir. 2015). Specifically, the Supreme Court considered this second step as determining whether the claims recite an element or combination of 9 Appeal2017-010310 Application 14/177 ,340 elements that is "sufficient to ensure that the patent in practice amounts to significantly more than a patent upon the [ineligible concept] itself." Mayo, 566 U.S. at 72-73. Claim 1 comprises four discrete steps: (1) receiving a 3D ultrasound image; (2) registering the 3D ultrasound image to a 3D coordinate system; (3) detecting a cardiac structure of interest in the registered image; and ( 4) determining an angulation of the C-arm system. Appellants' Specification describes the registration of the received 3D ultrasound image to the 3D coordinate system as comprising: At step 104, the ultrasound image is registered to a coordinate system of the C-arm image acquisition device. In particular, the ultrasound image is registered to the "table" coordinate system of the C-arm image acquisition device. The table coordinate system is a mechanical coordinate system that is oriented with respect to the table of the C-arm device and thus remains constant even as the C-arm portion of the C-arm image acquisition device is rotated with respect to the table. Spec. ,r 22. The image received can be input as a series of abstract digital values suitable for processing by a computer: An image acquisition device 920 can be connected to the computer 902 to input images to the computer 902. For example the image acquisition device 920 may be a C-arm image acquisition system capable of acquiring X-ray images and inputting the X-ray images to the computer 902. The image acquisition device 920 can also include an ultrasound probe, such as a TEE or ICE ultrasound probe, capable of acquiring 3D ultrasound images and inputting the ultrasound images to the computer 902. Id. at 40. In the subsequent step of claim 1: 10 Appeal2017-010310 Application 14/177 ,340 [A] structure of interest is detected in the registered ultrasound image. The structure of interest at least a portion of an anatomical structure that can be used to defined an optimal viewing angle for the X-ray acquisition. Although it is possible for a user to manually mark the structure of interest in the ultrasound image, according to an advantageous embodiment the structure of interest can be detected automatically in the 3D ultrasound image. Spec. ,r 33. In an exemplary embodiment of this method: In order to efficiently localize an object using MSL, [ marginal space learning] parameter estimation is performed in a series of marginal spaces with increasing dimensionality. Accordingly, the idea of MSL is not to learn a classifier directly in the full similarity transformation space, but to incrementally learn classifiers in the series of marginal spaces. As the dimensionality increases, the valid space region becomes more restricted by previous marginal space classifiers. In particular, detection of the global object in the 3D image is split into three stages: position estimation, position-orientation estimation, and position-orientation-scale estimation. A separate classifier is trained based on annotated training data for each of these steps. Id. at ,r 34. Finally, in the next step of the claimed method: [T]he C-arm angulation is determined based on the detected structure of interest. The C-arm angulation is dependent on the type of cardiac intervention being performed and can be automatically determined based on the structure of interest. For example, for TA VI, the annulus plane of the aortic valve is determined based on the detected structure of interest and a C- arm angulation that is perpendicular to the aortic annulus plane is selected. Similarly, for mitral valve intervention procedures, a C-arm angulation that is perpendicular to the annulus plane of the mitral valve can be selected. 11 Appeal2017-010310 Application 14/177 ,340 In summary, all of these steps constitute a receiving of, and subsequent manipulation of, routinely gathered data to produce an optimal angular measurement for the C-arm using a series of mathematical processes, all of which constitute no more than abstract processes. Furthermore, and as the Specification discloses, all of these processes can be performed on a generic computer: The above-described methods for determining an angulation of a C-arm image acquisition system may be implemented on one or more computers using well-known computer processors, memory units, storage devices, computer software, and other components.... The computer program instructions may be stored in a storage device 912, or other computer readable medium (e.g., magnetic disk, CD ROM, etc.) and loaded into memory 910 when execution of the computer program instructions is desired. Thus, the steps of the methods of FIGS. 1, 2, 4, and 5 may be defined by the computer program instructions stored in the memory 910 and/ or storage 912 and controlled by the processor 904 executing the computer program instructions. Spec. ,r 40. All of the steps of the claimed process, therefore, represent a series of abstract computational steps of the sort that could be performed mentally (however laboriously) and therefore constitute an abstract idea of the sort that falls within the exceptions to Section 101. We find our reviewing court's opinion in CyberSource Corp. v. Retail Decisions, Inc., 654 F.3d 1366 (Fed. Cir. 2011) to be instructive in this regard. A method claim in CyberSource was directed to: a) obtaining information about other transactions that have utilized an Internet address that is identified with the [ ] credit card transaction; 12 Appeal2017-010310 Application 14/177 ,340 b) constructing a map of credit card numbers based upon the other transactions and; c) utilizing the map of credit card numbers to determine if the credit card transaction is valid. 654 F.3d at 1370. Or, more generically, the claim recited: (1) gathering data; (2) mapping data with respect to a set of references; and (3) analyzing the data received to determine a useful output (valid/invalid). The Federal Circuit therefore reasoned that, with respect to the subject claim: [The claim's] steps can all be performed in the human mind. Such a method that can be performed by human thought alone is merely an abstract idea and is not patent-eligible under § 101. Methods which can be performed entirely in the human mind are unpatentable not because there is anything wrong with claiming mental method steps as part of a process containing non-mental steps, but rather because computational methods which can be performed entirely in the human mind are the types of methods that embody the "basic tools of scientific and technological work" that are free to all men and reserved exclusively to none. CyberSource, 654 F.3d at 1373 (quoting Gottschalkv. Benson, 409 U.S. 63, 67 (1972) (footnote omitted). We conclude that the same reasoning applies with respect to Appellants' claims. The steps of the claims relate to: (1) receiving data; (2) mapping (registering) the data to a series of references (a 3D coordinate system); (3) identifying a useful feature; and (4) calculating an optimal angular measure. We consequently conclude that Appellants' claims are directed to an abstract idea and, therefore, to a judicially-created exception to Section 101. 13 Appeal2017-010310 Application 14/177 ,340 Proceeding to the second step of our analysis, i.e., determining whether the rest of the claim, viewed individually or as an ordered combination, add "significantly more" to the claim than just the exception itself. We conclude that it does not. Appellants point to no additional steps beyond these calculation steps that could not be performed mentally, with the aid of pencil and paper, or without using a generic computer. Nor are we persuaded by Appellants' arguments that Appellants' claims are directed to an improvement in computer-related technology itself, as was the case in Enfish. See App. Br. 7. As we have noted supra, Appellants' claims can be performed on a generic computer, using commercially-available software. See Spec. ,r 40. We consequently affirm the Examiner's rejection of claims 1, 13, and 21 upon this ground. B. Rejection of dependent claims 3, 15, and 23 Analysis Appellants contend that each of these claims elaborate upon the requirement that the 3D ultrasound image is registered to a 3D coordinate system of the C-arm image acquisition system by: (1) "acquiring a 2D x-ray image by the C-arm image acquisition system"; (2) "detecting a position of an ultrasound probe in the 2D x-ray image using a learning based probe detector"; "estimating a pose of the ultrasound probe in the 3D coordinate system of the C-arm image acquisition device based on the detected position of the ultrasound probe in the 2D x-ray image"; and (4) "registering the 3D ultrasound image to the 3D coordinate system of the C-arm image acquisition device based on the estimated pose of the ultrasound probe in the 14 Appeal2017-010310 Application 14/177 ,340 3D coordinate system of the C-arm image acquisition device." App. Br. 11. Appellants contend that the claims thus recite a specific method for how the registration is performed and are not directed to the mere idea of registration. Id. We do not find this contention to be persuasive. Although the claims recite a more specific method for registering the received data to a 3D coordinate system, we do not find that this essentially changes the nature of the abstract process of registering data against a coordinate system that constitutes the exception to 101. We conclude that the refinement of the steps found patent-ineligible in Section A of our analysis supra insufficient in nature to render them patent eligible. Appellants argue further that the claims each recite: "detecting a position of an ultrasound probe in the 2D x-ray image using a learning based probe detector." App. Br. 11. Appellants contend that this limitation of the claims require the use of a "learning based probe detector" to detect the position of the ultrasound probe in the 2D x-ray image. Id. Therefore, Appellants argue, this limitation requires machine learning-based detection of the position of the ultrasound probe, and clearly cannot be performed as a mental process or by a human being with a pen and paper. Id. We disagree. Appellants' Specification discloses: At step 202, the ultrasound probe is detected in the 2D X- ray image. According to an advantageous implementation, a learning based method can be used for probe detection. Leaming based methods are robust to noise and capable of handling large variations in appearance. Unlike matching or similarity measures, learning based methods are trained on a set of manually annotated or synthetically generated training data. In particular, a probe detector is trained using a learning based method offline prior to the cardiac intervention procedure, and 15 Appeal2017-010310 Application 14/177 ,340 the trained probe detector is used to detect an image patch in the 20 X-ray image that contains the ultrasound probe head. Spec. ,r 24. Appellants' Specification thus discloses that a "learning based method" involves a series of steps involving the generation of training data and then using that training data as a basis to train the system to detect a probe. As such, this consists of a series of steps directly emulating a mental process, i.e., learning through repetition and familiarization. Appellants point to no non-abstract addition to this limitation that would constitute "significantly more" than the exception, i.e., the abstract idea, itself. We consequently affirm the Examiner's rejection of claims 3, 15, and 23 upon this ground. C. Rejection of dependent claims 4, 16, and 24 Appellants argue that claims 4, 16, and 24 each recite a series of steps that define how the step of "registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system" recited in the independent claims is performed. App. Br. 12. Specifically, Appellants assert that the claims require that the 3D ultrasound image is registered to a 3D coordinate system of the C-arm image acquisition system by "tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor" and "registering the ultrasound image to the 3D coordinate system of the C-arm image acquisition device based on the tracked position of the ultrasound probe." Id. Appellants therefore argue that the claims recite a specific method for how the registration is performed and are not directed to the mere idea of registration. Id. 16 Appeal2017-010310 Application 14/177 ,340 We do not find Appellants' arguments persuasive. Claim 4, by way of example, recites: The method of claim 1, wherein registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system comprises: tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor; and registering the ultrasound image to the 3D coordinate system of the C-arm image acquisition device based on the tracked position of the ultrasound probe. Although we acknowledge Appellants' point that the limitations of these claims provide more specific detail with respect to the limitation of the independent claims reciting: "registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system," we do not see how the addition of these specific steps alters the method from being abstract because these steps also lack anything significantly more than the exception itself. Appellants argue further that the claims each recite: "tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor." App. Br. 13. According to Appellants, this limitation requires the use of a position sensor to detect the position of the ultrasound probe in the 2D x-ray image. Id. Appellants argue that paragraph [0032] of Appellants' Specification discloses that a "position sensor" refers to a device, such as an electro-magnetic tracking sensor, that tracks the position of the ultrasound probe relative to the C-arm image acquisition device. Id. Therefore, Appellants contend, this limitation 17 Appeal2017-010310 Application 14/177 ,340 cannot be performed as a mental process or by a human being with a pen and paper. We are not persuaded. Paragraph [0032] of Appellants' Specification discloses that: In another exemplary embodiment, the registration of the 3D ultrasound image to the coordinate system of the C-arm image acquisition device can be implemented by equipping the ultrasound probe with a position sensor ( e.g., an electro-magnetic tracking sensor). The position sensor tracks the position of the ultrasound probe relative to the C-arm image acquisition device, and the tracked position of the ultrasound probe can be used to derive the position of the ultrasound image in the coordinate system of the C-arm image acquisition device. Appellants' Specification provides no more detail concerning, or indeed mentioning, a "position sensor," suggesting that such sensors would be known to a person of ordinary skill in the art. Indeed, the Examiner finds that Mountney teaches tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor (i.e., a detector): At step 106, the probe is detected in the fluoroscopic image. The probe detection identifies the location of the probe head used in the fluoroscopic image. The probe head is rigid and can move in 3D space with six degrees of freedom (DOF). The probe' s location in the fluoroscopic image is defined by two parameters, i.e., the x and y position in the image space. Mountney ,r 26. Because such probe sensors are known in the art, we find that the use of such a sensor constitutes routine data gathering activity already engaged in by the scientific community, and therefore does not add significantly more to the abstract idea than the abstract idea itself. See 18 Appeal2017-010310 Application 14/177 ,340 Mayo, 566 U.S. at 79--80. We therefore affirm the Examiner's rejection of the claims upon this ground. D. Rejection of dependent claims 12 and 32 Appellants next argue that claims 12 and 32 each recite the limitation of "orienting the C-arm image acquisition device to the determined angulation." App. Br. 13. Therefore, Appellants argue, these claims require movement of C-arm image acquisition device to a specific determined angulation. Id. Appellants argue that physical movement of a C-arm image acquisition device to a determined angulation is clearly not a mental process, and the claims therefore recite more than the abstract idea of "analyzing and registering acquired data." Id. at 13-14. We do not find this argument persuasive. "[T]o transform an unpatentable [ exception to Section 101] into a patent-eligible application of such a law, one must do more than simply state the law of nature while adding the words 'apply it."' Mayo, 566 U.S. at 72 (citing, e.g., Benson, 409 U.S. at 71-72). In the appeal before us, the abstract idea is the registration of the data onto a 3D coordinate system and the resultant calculation of the optimal angle of the C-arm. Moving the C-arm to match the calculated angle for the arm constitutes no more than applying the abstract idea. In other words, we find that moving the C-arm to correspond to the result of the abstract processing does not rise to the level of an "inventive concept," as required by the second step of the Mayo analysis. See Mayo, 566 U.S. at 82. We agree with the Examiner that this is not "significantly more" than the exception itself, as required by the second step of our patent eligibility 19 Appeal2017-010310 Application 14/177 ,340 analysis under Alice and Mayo. We therefore affirm the Examiner's rejection upon this ground. E. Rejection of dependent claim 33 Appellants argue that claim 33 recites a series of steps that specifically define how the step, recited in claim 3, of "estimating a pose of the ultrasound probe in the 3D coordinate system of the C-arm image acquisition device based on the detected position of the ultrasound probe in the 2D x-ray image" is performed. App. Br. 14. Specifically, claim 33 recites that the step requires: "acquiring a 2D x-ray image by the C-arm image acquisition system" and "refining the estimated initial pose of the ultrasound probe in the 3D coordinate system of the C-arm image acquisition device to reduce a difference value between a DRR image generated based on the estimated initial pose of the ultrasound probe and the 2D x-ray image." Id. at 14--15. Therefore, Appellants argue, claim 33 recites a specific method for how the pose of the ultrasound probe is estimated, and is not directed to the mere idea of analyzing and registering acquired data. Id. at 15. Appellants argue further that the limitations of claim 33 require the use of MSL-based pose detection ( which utilizes a series of trained learning based classifiers) to estimate an initial pose of the ultrasound probe in the 3D coordinate system of the C-arm image acquisition device, and also require generating a digitally reconstructed radiograph (DRR) image. App. Br. 15. According to Appellants, these limitations clearly cannot be performed as a mental process or by a human being with a pen and paper. Id. 20 Appeal2017-010310 Application 14/177 ,340 We are not persuaded by Appellants' arguments. As we have explained supra, adding refinements to an abstract idea that do not add significantly more than that idea will not transform the abstract idea into a non-abstract idea. Furthermore, recitation of the additional steps of an MSL- based learning model, which is itself designed to model human learning processes (i.e., mental steps) does not render the scope of the claim any less abstract. See CyberSource, 654 F.3d at 1373 (quoting Benson, 409 U.S. at 67) ("[C]omputational methods which can be performed entirely in the human mind are the types of methods that embody the 'basic tools of scientific and technological work"'). Finally, the step of generating an image, i.e., a digitally reconstructed radiograph (DRR) image, is, as we have explained an example of obtaining the end result and simply "apply[ing] it," and, as such, does not add significantly more to the claim than the abstract idea itself, as required by the second step of our Mayo analysis. We consequently affirm the Examiner's rejection of claim 33 on this ground. F. Rejection of dependent claim 34 Appellants argue that claim 34 requires that the step of "estimating an initial pose of the of the ultrasound probe in the 3D coordinate system of the C-arm image acquisition device based on the detected position of the ultrasound probe in the 2D x-ray image using marginal space learning-based pose detection," as recited in claim 33, comprises "initializing x and y coordinates of the ultrasound probe using the detected position of the probe in the 2D x-ray image," "estimating a 3D position of the probe ultrasound probe in a first detection stage using a first trained classifier," and "estimating the 3D position and orientation of the ultrasound probe in a 21 Appeal2017-010310 Application 14/177 ,340 second detection stage using a second trained classifier." App. Br. 16. Appellants therefore argue that claim 34 recites a specific method for how the initial pose of the ultrasound probe is estimated, and is not directed to the abstract idea of analyzing and registering acquired data. Id. Appellants argue further that the limitations of claim 34 require the use of a first trained classifier to estimate a 3D position of the ultrasound probe in a first detection stage and a second trained classifier to estimate the 3D position and orientation of the ultrasound probe in a second detection stage. App. Br. 16. According to Appellants, this limitation requires the use of trained machine learning-based classifiers, and cannot be performed as a mental process or by a human being with a pen and paper. Id. We are not persuaded. Appellants' Specification discloses that: Leaming based techniques are used for each detection stage. This approach treats pose estimation as a classification problem. A training dataset of the probe in different poses is generated offline. The training set can include manually annotated and synthetically generated training data. In a possible implementation, separate PBT classifiers are trained for each detection stage (i.e., position and position-orientation) of the pose estimation. At run time, features (e.g., Haar features) are extracted from the fluoroscopic image and used by the sequence of trained classifiers to estimate the pose of the probe. This approach is fast and provides an initial estimate of the probes position and orientation. Spec ,r 28. We find that Appellants' argument that "the use of trained machine learning-based classifiers" is not directed to a non-abstract concept, because such trained machine learning-based classifiers are, by design, intended to emulate human learning processes, which are themselves, 22 Appeal2017-010310 Application 14/177 ,340 abstract concepts. See CyberSource, 654 F.3d at 1373 (quoting Benson, 409 U.S. at 67) ("[C]omputational methods which can be performed entirely in the human mind are the types of methods that embody the 'basic tools of scientific and technological work"'). We therefore affirm the Examiner's rejection of claim 34 on this ground. II. A. Issue REJECTIONUNDER35 U.S.C. § 103(a) Claims 1, 3, and 21 Appellants argue that the Examiner erred because the combined cited prior art references fail to teach or suggest the limitations of the claims reciting: (1) "registering the 3D ultrasound image to a 3D coordinate system of the C-arm image acquisition system"; and (2) "detecting a cardiac structure of interest in the registered 3D ultrasound image." App. Br. 21. Analysis The Examiner finds that Boese teaches a method, apparatus and non- transitory computer readable medium for determining an angulation of a C- arm image acquisition system for a cardiac intervention, comprising: (1) receiving a 3D image including a critical structure; (2) registering the 3D image to a 3D coordinate system of the C-arm image acquisition system; (3) detecting a critical structure of interest in the registered 3D image; and ( 4) determining a required position of the C-arm image acquisition system based on the detected critical structure of interest in the registered 3D image. Final Act. 5 (citing Boese ,r,r 17, 22, 25). However, the Examiner finds, Boese does not teach or suggest receiving a 3D ultrasound image including a 23 Appeal2017-010310 Application 14/177 ,340 cardiac region, and determining an angulation of the C-arm image acquisition system and a transcatheter aortic valve implantation (TA VI). Id. The Examiner finds that Liao, in the same medical field of endeavor, teaches: (1) receiving a 3D ultrasound image including a cardiac region; (2) determining an angulation of the C-arm image acquisition system; (3) wherein the cardiac intervention is a transcatheter aortic valve implantation (TA VI) procedure. Final Act. 5 (citing Liao ,r,r 34, 3, 8). The Examiner finds that Liao further teaches detecting a cardiac structure of interest in the registered 3D ultrasound image comprising: (1) detecting an aortic annulus plane in the registered 3D ultrasound image. Id. ( citing Liao ,r 3). The Examiner concludes that it would have been obvious to one of ordinary skill in the art to modify the 3D image acquisition of a critical structure and positioning a C-arm image acquisition system with ultrasound images of the cardiac region and determining an angulation of the C-arm image acquisition system, because it would provide imaging of a region of interest in order to optimize intraoperative image acquisition. Final Act. 6. Appellants argue that, in the method of Boese, the registration of the 2D fluoroscopy system with the 3 D data set is performed after the optimum direction of projection is determined and, to any extent to which the critical structure is detected in the 3 D data set, the detection of the critical structure occurs before the registration of the 2D fluoroscopy system with the 3D data set. App. Br. 19. According to Appellants, Boese does not teach detection of a structure of interest in the registered 3D image. Appellants dispute the Examiner's finding that paragraph [0025] of Boese teaches "detecting a critical structure of interest in the registered 3D image." App. Br. 19 (quoting Final Act. 5). However, Appellants argue, 24 Appeal2017-010310 Application 14/177 ,340 paragraph [0025] of Boese teaches that the defined intervention data, which is determined prior to the registration, is transmitted to a navigation system, and then data determined within the context of the projection planning previously undertaken is transmitted to the fluoroscopy system. Id. ( citing Boese ,r,r 17-21; Fig. 1 ). Appellants further contend that paragraph [0025] teaches that, when the position of the C-arm is determined using the previously determined optimal direction of projection, the critical structure and the needle can be seen in the fluoroscopy image. Id. However, Appellants assert, the fluoroscopy image is the 2D image acquired using the fluoroscopy system, and not a 3D image that has been registered with the fluoroscopy system. Id. According to Appellants, there is no description in paragraph [0025] or elsewhere in Boese that teaches or suggests detecting the critical structure in a 3D image once the 3D image has been registered to the 2D fluoroscopy system. Id. Appellants also dispute the Examiner's finding that: "Boese[] disclose[ s] registration of a 3D image set and a critical structure of interest is determined after image registration." App. Br. 19 (quoting Final Act. 11). However, Appellants assert, the cited portions of Boese teach that the critical structure is located in the 3D image prior to the registration step, and there is no description in Boese of detecting the critical structure in a 3D image once the 3 D image has been registered to the 2D fluoroscopy system. Id. Appellants also argue that, as described in paragraph [0017] of Boese, the 3D data can be 3D angiography, computer tomography, or magnetic resonance tomography. App. Br. 20. Appellants assert that there is no description in Boese of receiving a 3D ultrasound image, registering the 3D 25 Appeal2017-010310 Application 14/177 ,340 ultrasound image to a 3D coordinate system of a C-arm image acquisition device, or detecting a cardiac structure of interest in a 3D ultrasound image. Id. With respect to Liao, Appellants argue that the reference teaches that "[ e ]xemplary embodiments of the inventions as described herein generally include systems and methods for detecting acoustic shadows and evaluating image quality in 3D ultrasound images." App. Br. 20. According to Appellants, this teaching of Liao is inconsistent with the description in all of the other paragraphs of Liao and does not appear to be related to the rest of Liao's teachings. Id. By way of example, Appellants point to paragraph [0002] of Liao, which teaches that: "This disclosure is directed to methods for guiding aortic valve replacements using real-time digital imaging." Id. Appellants also point to paragraph [0008] of Liao, which states that: "Exemplary embodiments of the invention as described herein generally include methods and systems for performing 3 D C-arm CT imaging during transcatheter aortic valve implantations." Id. Appellants assert that there is no description anywhere in Liao of any methods or systems for "detecting acoustic shadows and evaluating image quality in 3 D ultrasound images," as stated in paragraph [0034]. Id. Furthermore, argue Appellants, even though paragraph [0034] of Liao teaches: "detecting acoustic shadows and evaluating image quality in 3D ultrasound images," but there is no description in Liao of any such ultrasound images including a cardiac region or of detecting a cardiac structure in any ultrasound image. App. Br. 20-21. Appellants note that paragraph [0035] of Liao also states that the term "image" may refer to a medical image of a subject collected by computer tomography, magnetic 26 Appeal2017-010310 Application 14/177 ,340 resonance imaging, ultrasound, or any other medical imaging system. Id. at 21. However, Appellants argue, all of the embodiments described in Liao in which cardiac structures are detected utilize 3D C-arm CT imaging, and there is no description in Liao of any cardiac structure being detected in an ultrasound image. Id. Consequently, Appellants assert, there is no reason that a person of ordinary skill in the art would replace the 3D C-arm CT images of Liao with 3D ultrasound images, because such a modification would change the fundamental purpose of the methods described in Liao. Id. We do not find Appellants' arguments persuasive. Boese teaches: A critical structure 11, in the exemplary embodiment depicted, an organ of a patient, is located in the vicinity of a needle channel 12 indicated by an arrow. The structure 11 and the needle channel 12 are objects in a three-dimensional space. The task within the context of pre-interventional planning consists of finding an optimum direction of projection for the fluoroscopy. This direction or the associated plane which lies perpendicular to the direction of projection, is defined by the best visualization of the critical structure 11 in relation to the needle channel 12 and allows an especially secure monitoring of the needle movement during the intervention. Boese ,r 20. Boese then teaches that: "The user can move away from these projection directions which are determined from the recorded 3D data and visualized on a screen, and selects an optimum visualization." Id. at ,r 21. In the next step: [A] registration 5 of the 2D fluoroscopy system with 3D data set is performed in order to match the coordinate systems to each other. 27 Appeal2017-010310 Application 14/177 ,340 Where 3 D data from other sources such as magnetic resonance tomography or computer tomography is used, automatic or interactive image registration methods can be used. It is also possible, to initially register an external data set with 3D/3D registration with the 3D rotation angiography data set, in order to implicitly establish the registration with the fluoroscopy system in this way. Id. ,r,r 22-24. Finally, Boese teaches that: In the next step shown in FIG. 1 the defined intervention data 6 is transmitted to a navigation system. In this exemplary embodiment the navigation system is a stereotactic frame. Subsequently the data determined within the context of the projection planning 7 previously undertaken is transmitted to the fluoroscopy system. This enables the required position of the C- arm to be determined. Id. at ,r 25. We therefore agree with the Examiner that Boese teaches the claimed steps of: (1) receiving a 3D image including a critical structure; (2) registering the 3D image to a 3D coordinate system of the C-arm image acquisition system; (3) detecting a critical structure of interest in the registered 3D image; and (4) determining a required position of the C-arm image acquisition system based on the detected critical structure of interest in the registered 3D image. However, we agree with Appellants that Boese teaches performing step (4) before step (3), i.e., the critical structure is detected prior to registration of the received 3D image with the 3D coordinate system. However, we do not find that this is sufficient to overcome the Examiner's prima facie conclusion of obviousness. Our reviewing court has held that: Unless the steps of a method actually recite an order, the steps are not ordinarily construed to require one. See Loral Fairchild Corp. v. Sony Corp., 181 F.3d 1313, 1322, 50 USPQ2d 1865, 28 Appeal2017-010310 Application 14/177 ,340 1870 (Fed. Cir. 1999) (stating that "not every process claim is limited to the performance of its steps in the order written"). However, such a result can ensue when the method steps implicitly require that they be performed in the order written. Interactive Gift Express, Inc. v. Compuserve Inc., 256 F.3d 1323, 1342--43 (Fed. Cir. 2001). Claim 1 recites, in relevant part: "A method for determining an angulation of a C-arm image acquisition system for a cardiac intervention, comprising .... " (Emphasis added). The claim does not expressly require that the steps of registering the 3D image to a 3D coordinate system of the C-arm image acquisition system and detecting a critical structure of interest in the registered 3D image be performed in the specific order listed, i.e., there is no language reciting, "then" or "next" after each subsequent step. Furthermore, Appellants do not argue that preceding the detection step with the registration step is necessary to the functioning of their claimed invention, or that the claimed invention will be inoperative if the steps are reversed. Furthermore, the use of the transitional term "comprising" in the language of the claim creates a presumption that the claim does not exclude additional, unrecited elements. See Crystal Semiconductor Corp. v. TriTech Microelectronics Int'!, Inc., 246 F.3d 1336, 1348 (Fed. Cir. 2001). In other words, additional steps could be included in the method claimed by Appellants, not excluding again detecting the critical structure of interest again after registering the 3D image with the 3D coordinate system. Moreover, and importantly, Appellants provide neither argument nor evidence as to why the order of steps in the claims are necessary to the function of the claimed invention. In Burhans, there were four process steps, where each of the steps was disclosed in the prior art, differing only order of 29 Appeal2017-010310 Application 14/177 ,340 the steps. In re Burhans, 154 F.2d 690, 692 (CCPA 1946). The court was unpersuaded of patentability, finding that "[t]here is no merit in the point here in the absence of any proof in the record that the order of performing the steps produces any new and unexpected results." Id. In other words, Appellants adduce no evidence that, if step ( 4) is performed prior to step (3), the claimed method would not have been obvious and would not function to predict an optimal angle for the C-arm. With respect to the teachings of Liao, Liao expressly teaches that: As used herein, the term "image" refers to multidimensional data composed of discrete image elements (e.g., pixels for 2-D images and voxels for 3-D images). The image may be, for example, a medical image of a subject collected by computer tomography, magnetic resonance imaging, ultrasound, or any other medical imaging system known to one of skill in the art. Liao ,r 35. Appellants argue that there is no description in Liao of any such ultrasound images including a cardiac region or of detecting a cardiac structure in any ultrasound image and that the embodiments taught by Liao in which cardiac structures are detected utilize 3D C-arm CT imaging rather than ultrasound. App. Br. 20-21. We do not find this argument persuasive. Although Liao teaches CT imaging of cardiac structures in its exemplary embodiments, "all disclosures of the prior art, including unpreferred embodiments, must be considered." Merck & Co., Inc. v. Biocraft Labs., Inc., 874 F.2d 804, 807 (Fed. Cir. 1989). We agree that a person of ordinary skill in the art would understand from the disclosures of Liao, and particularly from paragraph [0035] supra, that its imaging methods could include 3D ultrasound images, as also taught by Boese, of cardiac structures. We therefore affirm the Examiner's rejection of claims 1, 3, and 21. 30 Appeal2017-010310 Application 14/177 ,340 Furthermore, Appellants rely upon these same arguments with respect to the Examiner's rejection of dependent claims 2, 3, 5, 6, 8-15, 17-20, 22, 23, 25, 26, and 28-34. App. Br. 22. For the same reasons we have given for rejecting the independent claims from which these claims depend, we affirm the Examiner's rejection of these claims. B. Claims 4, 16, and 24 Issue Appellants argue the Examiner erred in finding the combined cited prior art teaches or suggests the limitation of these claims reciting: "tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor." App. Br. 22. Analysis Appellants argue that paragraph [0032] of their Specification discloses that: a "position sensor" is a device, such as an electro-magnetic tracking sensor, that tracks the position of the ultrasound probe relative to the C-arm image acquisition device. App. Br. 22-23. Appellants assert that the Examiner mistakenly relies upon Mountney as teaching this limitation. App. Br. 23. According to Appellants, paragraph [0030] of Mountney teaches that the pose of a probe in 3D is estimated, and the detected probe position in the 2D fluoroscopic image can be used as a starting point for probe pose estimation using a marginal space learning (MSL) framework. Id. Appellants further contend that paragraphs [0026]- [0029] of Mountney describe that the probe position in the 2D fluoroscopic image is detected using a learned based method. Id. However, Appellants 31 Appeal2017-010310 Application 14/177 ,340 argue, paragraph [0032] of the Specification, which discloses that a "position sensor" refers to a device that tracks the position of the ultrasound probe relative to the C-ann image acquisition device, is distinguishable from the use of a learning-based method for detecting the probe position. Id. The Examiner responds that, contrary to Appellants' assertion, the Specification does not expressly provide a limited definition of the position sensor, but rather provides a non-limiting example of the position sensor as an electro-magnetic tracking sensor. Ans. 25. The Examiner finds that Mountney is directed to registration of ultrasound to x-ray fluoroscopic images. Id. (citing Mountney Abstr.). The Examiner finds Mountney further discloses tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device, in that the pose of the probe relative to the fluoroscopic image is defined by defining the probe's position in 3D in the coordinate system of the x-ray fluoroscopic image. Id. The Examiner finds that, because Appellants have not expressly defined the position sensor in the claims, the position sensor can be reasonably interpreted to be the computer of Mountney which tracks the x, y, and z data points for the position of the ultrasound probe. Ans. 25-26. The Examiner also finds that Mountney teaches a trained probe detector to detect the probe location. Id. at 26 (citing Mountney ,r 29). We agree with the Examiner. Dependent claim 4 recites, in relevant part: "tracking a position of an ultrasound probe in the 3D coordinate system of the C-arm image acquisition device using a position sensor; and registering the ultrasound image to the 3D coordinate system of the C-arm 32 Appeal2017-010310 Application 14/177 ,340 image acquisition device based on the tracked position of the ultrasound probe." We determines the scope of claims in patent applications by giving claims their broadest reasonable construction in light of the Specification as it would be interpreted by one of ordinary skill in the art. Phillips v. A WH Corp., 415 F.3d 1303, 1316 (Fed. Cir. 2005). We agree with the Examiner that Appellants' Specification gives no express limiting definition to the claim term "position sensor," but merely provides an exemplary embodiment. Paragraph [0032] of Appellants' Specification discloses: In another exemplary embodiment, the registration of the 3D ultrasound image to the coordinate system of the C-arm image acquisition device can be implemented by equipping the ultrasound probe with a position sensor ( e.g., an electro-magnetic tracking sensor). The position sensor tracks the position of the ultrasound probe relative to the C-arm image acquisition device, and the tracked position of the ultrasound probe can be used to derive the position of the ultrasound image in the coordinate system of the C-arm image acquisition device. We consequently define the claim term "position sensor" as meaning: "a device or mechanism that tracks the position of a probe relative to the C-arm image acquisition device." Mountney teaches: [A]t step 104, a TEE image is received. The TEE image is an ultrasound image that is acquired using a probe with an ultrasound transducer at the tip that is passed into a patient's esophagus. The TEE image may be received directly from the probe in real-time during the cardiac intervention procedure. In an advantageous implementation, the TEE image may be acquired at the same time as the fluoroscopic image received in step 102. 33 Appeal2017-010310 Application 14/177 ,340 At step 106, the probe is detected in the fluoroscopic image. The probe detection identifies the location of the probe head used in the fluoroscopic image. The probe head is rigid and can move in 3D space with six degrees of freedom (DOF). The probe' s location in the fluoroscopic image is defined by two parameters, i.e., the x and y position in the image space. The probe has the potential to move in six DOF and therefore the detection should be robust to changes in scale, translation, and rotation. According to an advantageous implementation, a learning based method can be used for probe detection .... In particular, a probe detector is trained using a learning based method offline prior to receiving the fluoroscopic image, and the trained probe detector is used to detect an image patch in the fluoroscopic image that contains the ultrasound probe head. Mountney ,r,r 25-27. Mountney thus teaches using a computer learning- based mechanism for locating, in three-dimensional space, the location of the ultrasound probe relative to the acquisition device, as determined by the relative location of the probe to the acquired image. We consequently affirm the Examiner's rejection of the claims. C. Claims 7 and 27 Issue Appellants argue that the Examiner erred in finding that the combined cited art teaches the limitation of the claims reciting: "detecting the aortic annulus plane as a plane that is perpendicular to the aortic root centerline at the aortic annulus." App. Br. 24. Analysis 34 Appeal2017-010310 Application 14/177 ,340 Appellants note that the Examiner relies on the paragraph [0022] of Liao as teaching this limitation. App. Br. 24 (Final Act. 6). Appellants assert that paragraph [0022] of Liao teaches deriving a perpendicularity circle parallel to a plane spanned by the three lowest points of the aortic root cusps and a ruler orthogonal to that plane. Id. Furthermore, Appellants assert, paragraph [0055] of Liao provides further description of how the perpendicularity circle is derived: a circle is derived that is parallel to the plane spanned by the three lowest points of the cusps, and the circle is then displaced a predetermined distance below the plane of the three points along a direction normal to that plane. Id. at 24--25. Therefore, argue Appellants, the perpendicularity circle described in paragraphs [0022] and [0055] is not located at the aortic annulus, as required by the claims. Id. at 25. Furthermore, Appellants contend, the perpendicularity circle is derived to be parallel to a plane defined by the three lowest points on the aortic root cusps. App. Br. 25. Appellants assert that, although paragraph [0038] of Liao mentions a centerline of the aortic root, there is no description of the perpendicularity circle being detected as a plane that is perpendicular to the aortic root centerline at the aortic annulus. Id. The Examiner responds that the aortic annulus is a fibrous ring that constitutes the transition point between the left ventricle of the heart and the aortic root. Ans. 26. The Examiner finds that the aortic root consists of the aortic valve which has three cusps surrounded by the aortic annulus and the openings for the coronary arteries. Id. The Examiner finds that Liao teaches detecting the root shape and landmarks, in particular the lowest points of each aortic root cusp, which are known to be surrounded by the aortic annulus, in the 3D volume and then 35 Appeal2017-010310 Application 14/177 ,340 detecting the centerline. Ans. 27 (citing Liao ,r 38). The Examiner finds that Liao then teaches deriving a perpendicularity circle parallel to a plane spanned by three lowest points of the aortic root, and notes that a plane of the aortic root would be perpendicular to a plane spanned by all three of the lowest points, i.e., the aortic root cusps. Id. ( citing Liao ,r 22). The Examiner finds that, if the plane of the aortic root cusps is perpendicular to the aortic root, the plane of the aortic annulus is also perpendicular to the aortic root. Id. The Examiner also notes that the claim requires only detecting an aortic plane which is perpendicular to the aortic annulus. We agree with the Examiner. Liao teaches: According to a further aspect of the invention, the method includes deriving a perpendicularity circle parallel to a plane spanned by three lowest points of the aortic root cusps and a ruler orthogonal to that plane, where the perpendicularity circle is displayed in the 3D volume rendering, and the ruler is displayed in one of the intersection planes. Liao ,r 22. We agree with the Examiner's reasoning that the three lowest points of the aortic root cusps as sufficient to define the aortic annulus plane. We further agree with the Examiner that Liao' s teaching of a ruler orthogonal to that plane includes the "aortic root centerline at the aortic annulus," as recited in the claim, because the centerline of the aortic root is necessarily orthogonal to the plane containing the aortic annulus. We therefore find that Liao teaches the disputed reference, and we affirm the Examiner's rejection of the claims. 36 Appeal2017-010310 Application 14/177 ,340 DECISION The Examiner's rejection of claims 1-34 under 35 U.S.C. § 101 is affirmed. The Examiner's rejections of claims 1-34 under 35 U.S.C. § 103(a) is affirmed. No time period for taking any subsequent action in connection with this appeal may be extended under 3 7 C.F .R. § 1.13 6( a )(1 )(iv). AFFIRMED 37 Copy with citationCopy as parenthetical citation
