12923891 (P.T.A.B. Jun. 21, 2016)

Ex Parte Miyazaki

Patent Trial and Appeal BoardJun 21, 2016

12923891 (P.T.A.B. Jun. 21, 2016)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 12/923,891 10/13/2010 23117 7590 06/23/2016 NIXON & V ANDERHYE, PC 901 NORTH GLEBE ROAD, 11 TH FLOOR ARLINGTON, VA 22203 FIRST NAMED INVENTOR Mitsue Miyazaki 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. LSN-4813-100 5278 EXAMINER KISH, JAMES M ART UNIT PAPER NUMBER 3737 NOTIFICATION DATE DELIVERY MODE 06/23/2016 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address( es): PTOMAIL@nixonvan.com pair_nixon@firsttofile.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte MITSUE MIYAZAKI Appeal2014-007288 Application 12/923,891 Technology Center 3700 Before DONALD E. ADAMS, JEFFREY N. FREDMAN, and JACQUELINE T. HARLOW, Administrative Patent Judges. PER CURIAM. DECISION ON APPEAL This is an appeal 1 under 35 U.S.C. Â§ 134 involving claims to a computer-implemented method and apparatus for generating an MR image. The Examiner rejected the claims on the grounds of anticipation and obviousness. We have jurisdiction under 35 U.S.C. Â§ 6(b). We affirm. 1 Appellant identifies the Real Party in Interest as Kabushiki Kaisha Toshiba and Toshiba Medical Systems Corporation (see App. Br. 3). Appeal2014-007288 Application 12/923,891 Statement of the Case Background Appellant's invention "relates generally to magnetic resonance imaging (MRI) processes" that "involve enhancements to Tl images of tissue for computer-aided diagnostics (CAD) of imaged patient tissue" (Spec. 1 :2-5). The Claims Claims 1-20 are on appeal. Independent claim 1 is representative and reads as follows (emphasis added): 1. A computer-implemented method for generating an MR image especially useful for computer-guided diagnostics, said method comprising the use of at least one programmed computer to: acquire an MR-image of Tl or Tl-weighted values for a patient volume containing at least one predetermined tissue type having a respectively corresponding predetermined range of expected Tl values; generate a color-coded Tl-image from said MR-image by (a) assigning a first color or spectrum of colors to those pixels having a value falling within said predetermined range of expected values and (b) assigning a second color or spectrum of colors to those pixels having a value falling outside said predetermined range of expected values; and display said color-coded Tl-image for use m computer-aided diagnosis of said patient tissue. 2 Appeal2014-007288 Application 12/923,891 The Issues A. The Examiner rejected claims 1and11under35 U.S.C. Â§ 102(b) as being anticipated by Lowen2 (Final Act. 3--4 ). B. The Examiner rejected claims 2 and 12 under 35 U.S.C. Â§ 103(a) as obvious over Lowen and Stork3 (Final Act. 5). C. The Examiner rejected claims 3, 4, 6, 13, 14, and 16 under 35 U.S.C. Â§ 103(a) as obvious over Lowen and Brasch4 (Final Act. 5---6). D. The Examiner rejected claims 5, 7-10, 15, and 17-20 under 35 U.S.C. Â§ 103(a) as obvious over Lowen, Brasch, and Daw5 (Final Act. 6-8). A. 35 U.S.C. Â§ 102(b) over Lowen The Examiner finds that Lowen teaches "color magnetic resonance imaging using both a magnetic resonance property and a function of the magnetic resonance property ... includ[ing] color imaging of estimates of [the chosen MR property] to distinguish between regions of a sample containing homogenous tissue and regions containing mixtures of tissue by spatial variation in the hue, brightness, or saturation of the colors (see Abstract)." The disclosure of Lowen discusses the use of T 2 as the magnetic resonance property, however, Lowen teaches the property may also be T 1 (see column 2, lines 38-40; ... therefore, the remainder of this rejection will replace T 2 with T 1 when directly quoting Lowen). "The function of the magnetic resonance property can be a function of fit of the [T 1] data to a reference curve. Including this characteristic of the [T 1] data in the color image allows a viewer to distinguish between a voxel with a single type of tissue with a particular [T 1] and a voxel with different tissues that together yield that [T1] (see column 3, lines 1-6)." 2 Lowen, US 6,804,384 B2, issued Oct. 12, 2004. 3 Stork et al., US 6,674,880 Bl, issued Jan. 6, 2004 (hereinafter "Stork"). 4 Brasch et al., US 6,009,342, issued Dec. 28, 1999 (hereinafter "Brasch"). 5 Daw, US 7, 155,043 B2, issued Dec. 26, 2006. 3 Appeal2014-007288 Application 12/923,891 The remainder of column 3 provides specific equations that, when the function of fit of [T 1] data to a reference curve is utilized as the magnetic resonance property as stated by Lowen provide predetermined hue, saturation and brightness assignments for a single type of tissue having a particular [T 1]. "The color image data are in RGB format. This renders the data suitable for convenient display on computer monitors (see column 3, lines 57-58)." (Final Act. 4.) The issue with respect to this rejection is: Does the evidence of record support the Examiner's findings that Lowen anticipates Appellant's claimed invention? Findings of Fact 1. The Specification teaches The following tables are taken from de Bazelaire, et al., "MR Imaging Relaxation Times of Abdominal and Pelvic Tissues Measured in Vivo at 3.0T: Preliminary Results," Radiology 230:3, pages 652-659, March 2004. As those in the art will appreciate, there are other sources of similar data readily available in the literature. For example, see Stanisz, et al, "T 1, T 2 Relaxation and Magnetization Transfer in Tissue at 3T," MRIM 54:507-512 (2005). (Spec. 4:15-20; see also Ans. 4--5.) 2. The Specification teaches "Table 1: Average Tl Relaxation Times at 1.5 Tesla and 3.0 Tesla" (Spec. Table 1, 5:1-20), and As shown by Table 1 above of published Tl-parameter values for various tissues (including ranges of expected variation), it is possible to determine threshold ranges of Tl values so as to distinguish between various organs and/ or tissues. It is now proposed that such ranges of T 1 values be color-coded (e.g., with a given color for a certain range of Tl 4 Appeal2014-007288 Application 12/923,891 values or for a whole spectrum of colors to be assigned to a particular range of Tl values). (Spec. 7: 17-22; see also Ans. 4--5.) 3. Lowen teaches color magnetic resonance imaging using both a magnetic resonance property and a function of the magnetic resonance property. These enhanced color images provide greater informational content to the viewer. Applications include color imaging of estimates of T 2 to distinguish between regions of a sample containing homogeneous tissue and regions containing mixtures of tissue by using spatial variation in the hue, brightness, or saturation of the colors. (Lowen Abstract; see also Final Act. 4.) 4. Lowen teaches MR images are generated from the FID signals. These images are often in black and white. Techniques are also known for producing gray scale images using Ti, T2, and proton density data, see, e.g., Ronald T. Droege et al., "Nuclear Magnetic Resonance: A Gray Scale Model for Head Images," Radiology, 148:763-771 (1983). There are also methods for generating color images. One approach is to convert a monochrome image into one that is in color, see U.S. Pat. No. 4,998,165. Other approaches to producing color images take both Ti and T 2 data as inputs and use specified methods to render color images, ... (Lowen 1 :52---62; see also Ans. 4--5.) 5. Lowen teaches that "[t]he magnetic resonance property can be an estimate ofT2, Ti, or thermal relaxation" (Lowen 2:38--40; see also Final Act. 4.) 5 Appeal2014-007288 Application 12/923,891 6. Lowen teaches The function of the magnetic resonance property can be a function of fit of the T 2 data to a reference curve. Including this characteristic of the T 2 data in the color image allows a viewer to distinguish between a voxel with a single type of tissue with a particular T 2 and a voxel with different tissues that together yield that T 2. This fit, E, can be calculated usmg: [A] function of intensity. Display of intensity information permits one to distinguish readily between voxels containing mostly air and those containing tissue. The intensity, IN, can be calculated using: [B]oth a function of fit of the first data to a reference curve and a function of intensity. The preceeding [sic] equations can be used to calculate them, or a threshold measure can be used to eliminate a pre-determined range of values. This provides the user with the useful information provided by both characteristics of the T 2 data. The estimate of T 2, the fit of the first data to the reference curve, and the intensity are used to calculate hue, saturation, and brightness. Using these three parameters, the color images provide a greater depth of information than available in grayscale images. The hue, H; saturation, S; and brightness, V, are calculated using: The color image data [] in RGB format. This renders the data suitable for convenient display on computer monitors and storage in cross-platform image files (e.g., JPEG, TIFF, PPM files). The individual color values in the color image data []given by: These equations can be adjusted to enhance the user's ability to distinguish between different types of tissues, e.g., white and gray matter in the human brain. The images can 6 Appeal2014-007288 Application 12/923,891 also be used to ascertain the porosity of T 2 data or investigate samples described by the Arrhenius equation. (Lowen 3:1--4:11; see also Final Act. 4, Ans. 2-3.) Principles of Law A prior art reference can only anticipate a claim if it discloses all the claimed limitations "arranged or combined in the same way as in the claim." Wm. Wrigley Jr. Co. v. Cadbury Adams USA LLC, 683 F.3d 1356, 1361 (Fed. Cir. 2012) (internal quotations and citation omitted). Where . . . the claimed and prior art products are identical or substantially identical . . . the PTO can require an applicant to prove that the prior art products do not necessarily or inherently possess the characteristics of his claimed product. . . . Whether the rejection is based on 'inherency' under 35 U.S.C. Â§ 102, on "prima facie obviousness" under 35 U.S.C. Â§ 103,jointly or alternatively,[] the burden of proof is the same, and its fairness is evidenced by the PTO' s inability to manufacture products or to obtain and compare prior art products. In re Best, 562 F.2d 1252, 1255 (CCPA 1977) (citations and footnote omitted). Analysis We adopt the Examiner's findings of fact and reasoning regarding the scope and content of the prior art (Final Act. 3-8; Ans. 2-14; FF 1-11) and agree that claims 1 and 11 are anticipated by Lowen. We address Appellant's arguments below. Appellant contends that "Lowen does disclose coloration of an MR- image as a function, inter alia, of an MRI parameter (e.g., Tl or T2). However, Lowen's colorization is of an entirely different type and result 7 Appeal2014-007288 Application 12/923,891 than that required by the claimed invention" (App. Br. 8). Appellant argues that "Appellant has taken advantage of the fact that there are now known predetermined ranges of expected T 1 values corresponding to predetermined tissue types" (id. at 9). More particularly, Appellant argues that Lowen does not mention a predetermined tissue type having a respectively corresponding predetermined range of expected Tl-values. It will be appreciated that Appellant's claims require colorization based on a predetermined range of expected T 1 values corresponding to at least one predetermined tissue type. This teaching is not found in Lowen. (Id. at 10; see also Reply Br. 2-8.) We are not persuaded. We agree with the Examiner that: Since equations for H, S, and V are predetermined (see column 3, lines 45-50), certain tissue types, which would have specific T 1 values, will create predetermined colorization (it is known to those of skill in the art that hue defines the color and as can be seen, hue is specifically based on the T 1 (or T2) data). This teaches that there is a pre- determined colorization of expected Tl (or T2) values corresponding to specific (predetermined) tissue types. Furthermore, Lowen states (see column 3, line 34--37), "The preceding equations can be used to calculate them (i.e., a function of fit to a reference curve & a function of intensity), or a threshold measure can be used to eliminate a pre- determined range of values." This teaches to remove predetermined ranges of values based on thresholding, thereby teaching that only a predetermined range will remain. Therefore, the hue is calculated by the predetermined equation based directly on the Tl (or T2), such that this is the only variable term in that equation. And also, a second interpretation by which Lowen reads on this subject matter is the explicitly taught removal of a predetermined range of values teaches a predetermined range of values will be removed (i.e., given either one of a white or black color 8 Appeal2014-007288 Application 12/923,891 depending on which of these is representative of the absence of data). (Ans. 2-3.) We note that Appellant's Specification teaches that "[t]he following tables are taken from de Bazelaire, et al., . . . . As those in the art will appreciate, there are other sources of similar data readily available in the literature" (FF 1), and that "[a]s shown by Table 1 above of published Tl- parameter values for various tissues (including ranges of expected variation), it is possible to determine threshold ranges of Tl values so as to distinguish between various organs and/or tissues" (FF 2). Moreover, Lowen teaches that Techniques are also known for producing gray scale images using Ti, T2, and proton density data, see, e.g., Ronald T. Droege et al., . . . . There are also methods for generating color images. One approach is to convert a monochrome image into one that is in color. . . . Other approaches to producing color images take both T 1 and T 2 data as inputs and use specified methods to render color images. (FF 4.) Lowen teaches color magnetic resonance imaging using both a magnetic resonance property and a function of the magnetic resonance property. These enhanced color images provide greater informational content to the viewer. Applications include color imaging of estimates of T 2 to distinguish between regions of a sample containing homogeneous tissue and regions containing mixtures of tissue by using spatial variation in the hue, brightness, or saturation of the colors. (FF 3.) Therefore, because the T 1 values are known for tissue types as admitted by Appellant and taught by Lowen, and Lowen further teaches colorization based on these known data, Lowen necessarily teaches colorization based on predetermined ranges of expected Tl values 9 Appeal2014-007288 Application 12/923,891 corresponding to at least one predetermined tissue type. See Jn re Best, 562 F.2d at 1255. Further, we note that "predetermined" represents intended use of known data, and represents a mental step in determining data that the evidence demonstrates was already known to the ordinary artisan (FF 1-2, 4). "[T]erms [that] merely set forth the intended use for, or a property inherent in, an otherwise old composition ... do not differentiate the claimed composition from those known [in] the prior art." In re Pearson, 494 F.2d 1399, 1403 (CCPA 1974). Appellant contends that Appellant's approach permits use of a Tl range index that can be compared to normal tissue indices stored from many normal tissues. For example, an irregular tissue Tl index can be compared with a known T 1 index of tumors. Known data can be accumulated from collected data that can then be used to compare. (App. Br. 10.) For the reasons discussed above, we are not persuaded. Moreover, we agree with the Examiner that "this argument fails to address any limitation found within claims 1 and 11" (Ans. 3). "[L ]imitations are not to be read into the claims from the specification." In re Van Geuns, 988 F.2d 1181, 1184 (Fed. Cir. 1993). See also In re Self, 671F.2d1344, 1348 (CCPA 1982) ("[A]ppellant's arguments fail from the outset because ... they are not based on limitations appearing in the claims"). Appellant argues that Contrary to Lowen's disclosure, Appellant has described a real-world situation where a single predetermined type of tissue does not have an associated particular single magnetic resonance property value. Instead, a predetermined tissue type has a respectively corresponding predetermined 10 Appeal2014-007288 Application 12/923,891 range of expected Tl values. Appellant's colorization is based upon such predetermined ranges of expected values. (App. Br. 11 ). We do not find this argument persuasive for the reasons discussed above. Accordingly, we agree with the Examiner that although such a real-world situation has been described, this fails to preclude Lowen from reading on the limitations of claims as currently written. A single example of a real-world situation in which the claim reads upon does not preclude a broadest reasonable interpretation for which a prior art reference positively reads on the claimed subject matter. In this case, using Lowen' s methods on a patient who does not have a tumor (in which Tl or T2 values of a specific tissue have a specific value) reads on claims 1 and 11. (Ans. 4.) Appellant contends that "[i]n addition, Lowen does not teach that the eliminated 'predetermined range of values' has any relationship to a predetermined patient tissue type" (App. Br. 12). We are not persuaded for the reasons discussed above. We note that Lowen teaches "[i]ncluding this characteristic of the T 2 data in the color image allows a viewer to distinguish between a voxel with a single type of tissue with a particular T 2 and a voxel with different tissues" and that "[t]hese equations can be adjusted to enhance the user's ability to distinguish between different types of tissues, e.g., white and gray matter in the human brain" (FF 6). We further agree with the Examiner that Lowen does not need to make such a statement. As stated on page 9, lines 3-4 of the Appeal Brief, "Appellant has taken advantage of the fact that there are now known pre- determined ranges of expected T 1 values corresponding to predetermined tissue types." This statement makes it clear that it is a fact that predetermined tissue types have 11 Appeal2014-007288 Application 12/923,891 predetermined ranges of expected T 1 values. The other fact found within this statement is that this first fact may have been determined by the Appellant. However, this does not mean that pre-determined ranges of expected T 1 values did not correspond to predetermined tissue types prior to such discovery. In other words, the Appellant's determination that predetermined tissue types have predetermined ranges of expected Tl values does not mark the first time [in] history that such phenomenon occurred. This is a natural and inherent characteristic of tissues. The only variable in the equation provided by Lowen is the Tl (or T2) value. Therefore, it is inherent that a predetermined range of hues (for example, a spectrum of blues for one tissue type, or a spectrum of reds for another tissue type - as claim 1 states that "a first/second color or a spectrum of colors) corresponds to predetermined types of tissues. Furthermore, the elimination of a predetermined range of values (i.e., Tl or T2 values) would inherently be related to values of a predetermined tissue type, based on the threshold and elimination techniques taught by Lowen. (Ans. 4--5.) See In re Best, 562 F.2d at 1255. We recognize, but are not persuaded by Appellant's contention that Firstly, the Examiner fails to recognize that the Lowen teaching at 3 :34 et seq. deals with eliminating a predetermined range of values from one or more of the intermediate parameters used, later, to determine colorization. Still further, the predetermined eliminated range of intermediate parameter values taught by Lowen has no disclosed relationship to any respectively corresponding patient tissue type . . . . . In particular, the Lowen colorization formulae depend upon at least two input variables so eliminating some predetermined range of values from an input (intermediate) variable is not the same as assigning colorization to pixels based on whether the Tl pixel value falls in or outside of a 12 Appeal2014-007288 Application 12/923,891 predetermined range of expected T 1 values respectively corresponding to a predetermined tissue type. (App. Br. 15.) As the Examiner explains, By Lowen' s teaching of eliminating a predetermined range of values, Lowen's final image would inherently show those pixel locations by either black or white (or some other predetermined color that signifies zero data). Such "zero data color" would be applied to pixels falling within the range that is outside of the threshold value, while the other pixels would have a color granted by the hue equation, thereby having a non-"zero data color." Therefore, this explicitly reads on the claimed subject matter. With regard to "[] ... no disclosed relationship to any respectively corresponding patient tissue type," it is again noted that it is a matter of fact that tissue has a known predetermined range of T 1 (or T2) values associated therewith. (Ans. 6.) See In re Best, 562 F.2d at 1255. Accordingly, we affirm the rejection of claims 1 and 11. B. 35 U.S.C. Â§ 103(a) over Lowen and Stork Appellant states that "Appellant agrees that acquisition of image data by retrieval of stored image data was itself known in the art" (App. Br. 16). Having affirmed the anticipation rejection, we therefore, affirm the obviousness rejection of claims 2 and 12 for the reasons given by the Examiner. C. 3 5 U.S. C. Â§ 103 (a) over Lowen and Brasch The Examiner concludes that it would have been obvious to one of ordinary skill in the art at the time the invention was made to utilize the teachings of Brasch, i.e., obtaining multiple pre-contrast images in order to generate a curve for that illustrates "normal" relaxation times for normal and tumorous tissue, with the system and 13 Appeal2014-007288 Application 12/923,891 methods of Lowen because Lowen teaches comparing relaxation values to a reference curve but fails to teach how to obtain such a curve. (Final Act. 6.) The issue with respect to this rejection is: Does the evidence of record support the Examiner's conclusion that Lowen and Brasch render the claims obvious? Findings of Fact 7. Brasch teaches in MR imaging, from the change in relaxation rates, parameters important to determining the microvascular permeability are determined. Precontrast relaxation rates (R1) (1/T 1) estimates for normal tissue and tumor are obtained by curve fittings based on more than two, preferably 5 unenhanced three dimensional image sets with TR' s varying from 50 msec to 2000 msec. Postcontrast Rl values are calculated based on signal intensity and knowledge of precontrast values. (Brasch 10:63-11:4; see also Final Act. 6.) 8. Brasch teaches that "[p]recontrast SPGR sequences included multiple TR of 50-2000 msec for calculating baseline relaxation rates (R1 = 1/T 1)[.] Dynamic postcontrast images were performed with TR fixed at 50 msec" (Brasch 14:64---67; see also Ans. 8). Principles of Law "The combination of familiar elements according to known methods is likely to be obvious when it does no more than yield predictable results." KSR Int'! Co. v. Teleflex Inc., 550 U.S. 398, 416 (2007). "If a person of ordinary skill can implement a predictable variation, Â§ 103 likely bars its patentability." Id. at 41 7. 14 Appeal2014-007288 Application 12/923,891 Analysis We agree with the Examiner that Lowen and Brasch render the claims obvious. We address Appellant's arguments below. Appellant contends that "in the context of colorization based on predetermined ranges of expected Tl values respectively corresponding to predetermined tissue types, these claims when considered 'as a whole' (as is required under 35 U.S.C. Â§ 103) are novel and not suggested or taught even by the combination of Lowen/Brasch" (App. Br. 17; see also Reply Br. 6-8). We remain unpersuaded regarding the issue of "predetermined" for the reasons discussed above, and agree with the Examiner that claims 3, 4, 13, and 14 are obvious over Lowen and Brasch (see Ans. 7). In regard to claims 6, and 16, Appellant argues that The Examiner apparently misconceives the claimed subject matter of claims 6, 16 as somehow being analogous to derivation of a "reference curve" in Lowen. . . . The recited subject matter is part of the process of acquiring a Tl value for that pixel (e.g., depending upon the exponential curve time decay factor required for a fitting to the acquired data, a Tl value is determined). This is the antithesis of fitting the acquired data to a "reference curve". . . . In other words, claims 6, 16 deal with derivation of the T 1 image values - not to any "reference curve" that might be involved in colorization ala Lowen's teaching. (App. Br. 18-19; see also Reply 10.) We are not persuaded for the reasons discussed above regarding the teachings of Lowen. We further agree with the Examiner that the Examiner incorporated Brasch as a more defined use of "curve fitting" since the use of curve fitting by Lowen is not well defined. The curve fitting used by Brasch specifically teaches contrast and pre-contrast imaging to determine 15 Appeal2014-007288 Application 12/923,891 relaxation times (Tl and T2) to provide estimates for normal tissue and tumorous tissue. Therefore, by incorporating this curve fitting into the teachings of Lowen, it would have been obvious to one of skill in the art that removing a certain range of values would and could relate to removing either one of normal tissue or tumorous tissue values. (Ans. 7-8; FF 7-8). That is, the Examiner reasonably relies upon Brasch to evidence that methods of curve fitting using different intervals was known in the prior art (FF 7-8) and that the ordinary artisan would have been motivated to apply these known methods to optimize the curve fitting disclosed by Lowen (FF 6). D. 35 U.S.C. Â§ 103(a) over Lowen, Brasch, and Daw The Examiner concludes that [i]t would have been obvious to one of ordinary skill in the art at the time the invention was made to incorporate the user interface taught by Daw with the system and methods taught by the combination of Lowen with Brasch, because "without use of [techniques taught by Daw]; the radiologist may spend a great deal of time studying [multiple] slices in an attempt to locate matching tissue in order to be assured of the proper scope and boundary of the tumor under study (see column 15, lines 21-25)." (Final Act. 7 .) The issue with respect to this rejection is: Does the evidence of record support the Examiner's conclusion that Lowen, Brasch, and Daw render the claims obvious? Findings of Fact 9. Daw teaches the display of the image as part of the user interface includes two separate windows on the visual display. Within one 16 Appeal2014-007288 Application 12/923,891 window of the visual display the main image under study is shown. In another portion of the visual display, such as in an upper, central portion of the screen, a window having a plurality of miniature images is simultaneously displayed. In each of these images, a mark is provided in the form of an analysis indicator that indicates whether or not the image analysis resulted in an image that has tissue which matches the reference tissue under examination. (Daw 2:16-25; see also Final Act. 7.) 10. Daw teaches When a user is performing the first tissue classification analysis, which is done in order to generate the results ... , or desires to perform a second classification analysis on a different type of tissue within the region of interest, he or she will indicate the reference tissue on which the classification is to take place and then input a command to the computer to begin the classification analysis. (Daw 16:44--51; see also Ans. 12.) 11. Daw teaches that "[p ]referably, a color is selected which is easily detectable by the user, and optionally appears as an overlay on the image so the features of the image can be seen underneath the color overlay. Therefore, the user is allowed to toggle between a bright solid color" (Daw 2:63---67; see also Ans. 13). Principles of Law [E]vidence of a motivation to combine need not be found in the prior art references themselves, but rather may be found in "the knowledge of one of ordinary skill in the art or, in some cases, from the nature of the problem to be solved." ... When not from the prior art references, the "evidence" of 17 Appeal2014-007288 Application 12/923,891 motive will likely consist of an explanation of the well-known principle or problem-solving strategy to be applied. Dystar Textilfarben GmbH & Co. Deutschland KG v. C.H. Patrick Co., 464 F.3d 1356, 1366 (Fed. Cir. 2006) (emphases in original, quoting In re Dembiczak, 175 F.3d 994, 999 (Fed. Cir. 1999)). Analysis We agree with the Examiner that Lowen, Brasch, and Daw render the claims obvious. We address Appellant's arguments below. We recognize, but are not persuaded by Appellant's contention that claims 5 and 15 "additionally require first and second color-coded Tl- images to be generated respectively (a) without and (b) with administration of a contrast agent - and require both such differently color-coded T 1- images to be displayed for use in computer-guided diagnosis of said patient tissue" (App. Br. 19-20; see also Reply 10-11). As the Examiner explains, Brasch has already been described for acquiring both pre- contrast and post-contrast images . . . . Furthermore, Daw specifically teaches that pre-contrast and post-contrast sequence data may be acquired . . . . Furthermore, Daw teaches that multiple images may be displayed simultaneously to allow an operator to easily compare tissue types amongst multiple images. (Ans. 9; FF 7-11.) In regard to claims 7 and 1 7, we recognize, but are not persuaded by Appellant's contention that "one still does not find mention anywhere here of a certain sub-range of T 1 pixel values not expected in normal tissue of the particular predetermined tissue type - nor color coding to distinguish the sub-range from the predetermined range of expected Tl values recited in 18 Appeal2014-007288 Application 12/923,891 parent claims 1, 11" (App. Br. 20; see also Reply 11). We note that claims 7 and 17 do not recite "sub-range of Tl pixel values." See In re Van Geuns, 988 F.2d at 1184 and In re Self, 671 F.2d at 1348. Accordingly, we are not persuaded for the reasons discussed above and agree with the Examiner that "Daw teaches that multiple images may be displayed simultaneously to allow an operator to easily compare tissue types amongst multiple images . . . . Therefore, it is obvious that one of these two images is a reference image used for the comparison" (Ans. 9; FF 9). We recognize, but are not persuaded by Appellant's contention that "[t]aking all of the above into account, there is still no teaching in Daw of the claims 5, 15 requirement for display of both of two differently colorized Tl-images, etc." (App. Br. 22; see also Reply 10-11). As the Examiner explains, there is no clear limitation that states that the two images are "two differently colorized" images. Rather, one image is \'l1ithout contrast agent \'l1hile the other is \'l1ith contrast agent. It is noted ... that both Brasch and Daw teach acquisition of both of these types of images, Lowen' s hue equation is a predetermined equation and relies solely on the Tl (or T2) value of the tissue region being imaged, and Daw teaches display of multiple images for comparison purposes and diagnostic purposes. (Ans. 9-10; FF 6-9.) We recognize, but are not persuaded by Appellant's contention that "there is also still no teaching in Daw of the claim 7, 17 further requirement of displaying, in addition to the colorized image of parent claim 1, a reference MR-image of said patient tissue" (App. Br. 22; see also Reply 11 ). As the Examiner explains, Daw "teaches display of two images comprising 19 Appeal2014-007288 Application 12/923,891 (a) the main image under study and (b) a plurality of miniature images showing possible images that may or may not have a same tissue type present" (Ans. 10; FF 9). In regard to claims 8 and 18, we recognize, but are not persuaded by Appellant's contention that there does not appear to be any teaching or suggestion that the colorization should distinguish between a sub-range (defining abnormal values not expected in normal tissue of the predetermined tissue type - followed by color coding respectively corresponding pixels with a color or spectrum of colors that is distinguished from the remainder of the imaged tissue). (App. Br. 23; see also Reply 11-13.) We note that the claims do not define "sub-range." As the Examiner explains, the invention of Lowen will distinguish between normal and abnormal tissue types within its methods because the hue is dependent only on the Tl (or T2) value. By viewing an image where the abnormal tissue has a hue different from the surrounding tissue, it is obvious that this different hue is "within a subrange," and it is obvious that such an analysis occurs because this is the method by which radiologists detect tumors and cancers from medical images. (Ans. 11-12; FF 6). See In re Best, 562 F.2d at 1255. See also Dystar Textilfarben GmbH & Co. Deutschland KG v. C.H. Patrick Co., 464 F.3d at 1366. In regard to claims 9 and 19, we recognize, but are not persuaded by Appellant's contention that "the Examiner has not identified any specific Daw text that actually teaches an operator capability to adjust a predetermined range of expected TI -values corresponding to a predetermined tissue type for colorization as required by parent claim 1" 20 Appeal2014-007288 Application 12/923,891 (App. Br. 24; see also Reply 13-14). As the Examiner explains, "Daw teaches further that a user may characterize any number of tissue types based on any desired sub-range of data types and values" (Ans. 12; FF 10). See Dystar Textilfarben GmbH & Co. Deutschland KG v. C.H. Patrick Co., 464 F.3d at 1366. In regard to claims 10 and 20, we recognize, but are not persuaded by Appellant's contention that "these passages do not teach operator control for both a first and a second color spectrum in the relevant context of parent claim 1" (App. Br. 24; see also Reply 14--15). As the Examiner explains, Daw teaches at column 2, lines 51---67 that the colorized overlay may be selectable by a user - "preferably, a color is selected which is easily detectable by the user ... [.]" Furthermore, the passages at column 17, lines 54-58 and 64- 66 also teach that colors have been selected for particular tissue types within the image. (Ans. 13; FF 11.) SUMMARY In summary, we affirm the rejection of claims 1 and 11 under 35 U.S.C. Â§ 102(b) as being anticipated by Lowen. We affirm the rejection of claims 2 and 12 under 35 U.S.C. Â§ 103(a) as obvious over Lowen and Stark. We affirm the rejection of claims 3, 4, 6, 13, 14, and 16 under 35 U.S.C. Â§ 103(a) as obvious over Lowen and Brasch. We affirm the rejection of claims 5, 7-10, 15, and 17-20 under 35 U.S.C. Â§ 103(a) as obvious over Lowen, Brasch, and Daw. 21 Appeal2014-007288 Application 12/923,891 No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. Â§ 1.136(a). AFFIRMED 22