11428669 (P.T.A.B. Oct. 23, 2012)

Ex Parte Goodrich et al

Patent Trial and Appeal BoardOct 23, 2012

11428669 (P.T.A.B. Oct. 23, 2012)

UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE PATENT TRIAL AND APPEAL BOARD __________ Ex parte RAYMOND P. GOODRICH and CYNTHIA A. SCOTT __________ Appeal 2011-011270 Application 11/428,669 Technology Center 1600 __________ Before LORA M. GREEN, MELANIE L. McCOLLUM, and STEPHEN WALSH, Administrative Patent Judges. McCOLLUM, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims to a method for reducing pathogens. The Examiner has rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm. STATEMENT OF THE CASE Claims 20, 22, 23, 25-27, 29, 31, and 32 are on appeal (App. Br. 9).1 The claims have not been argued separately and therefore stand or fall 1 Claims 28 and 30 are also pending but have been indicated to be allowable if rewritten in independent form (Final Rejection 8). Appeal 2011-011270 Application 11/428,669 2 together. 37 C.F.R. § 41.37(c)(1)(vii). Claim 20 is representative and reads as follows: 20. A method for reducing pathogens in a biological sample; said method comprising the steps of: providing a container for irradiating said biological sample; wherein said container comprises poly(vinyl chloride) and at least one citrate plasticizer wherein said citrate plasticizer is selected from the group consisting of: triethyl citrate; acetyltriethyl citrate; n-butyryltri-n-hexyl citrate; and acetyltri-n-butyl citrate; and wherein said container transmits electromagnetic radiation having a selected distribution of wavelengths and wherein the transmission of electromagnetic radiation having said selected distribution of wavelengths by said container is substantially constant during exposure to electromagnetic radiation; measuring the percentages of transmission of said container as a function of wavelength over said selected distribution of wavelengths; generating electromagnetic radiation using a source of electro- magnetic radiation; monitoring the power of said electromagnetic radiation generated by said light source; calculating a radiant power delivered to said biological sample using said measured percentages of transmission of said container; determining an exposure time of said biological sample required to provide a desired extent of pathogen reduction; and exposing said container to electromagnetic radiation for said exposure time, wherein electromagnetic radiation having said selected distribution of wavelengths is transmitted by said container and is at least partially absorbed by said biological sample, thereby reducing said pathogens in the biological sample. Appeal 2011-011270 Application 11/428,669 3 Claims 20, 22, 23, 25-27, 29, 31, and 32 stand rejected under 35 U.S.C. § 103(a) as obvious over Goodrich,2 as evidenced by Cobe,3 in view of Mahal4 and Medical Grade5 (Ans. 5). The Examiner relies on Goodrich for teaching “a method for inactivation of microorganisms in fluids containing blood or blood products . . . by using electromagnetic radiation such as UV irradiation at about 300 to 700 nm . . . in the presence of endogenous photosensitizers such as 7, 8- dimethyl-10-ribityl isoalloxazine” (id.). The Examiner finds that Goodrich “also teach[es] the containers for the method of inactivation of micro- organisms in fluids can be a bag such as collection bags (e.g. Spectra apheresis systems of Cobe Laboratories, Inc.) for batch-wise treatment of the fluid” (id.). The Examiner relies on Cobe as evidence that “the collection bag disclosed by Goodrich, Jr. et al. is inherently made of citrate plasticized PVC” (id. at 16). The Examiner relies on Mahal for teaching “a medical container for blood and blood component storage made of polyvinyl chloride (PVC) and a citrate plasticizer” (id. at 6). The Examiner finds that “Mahal also teaches that the preferred plasticizers include n-butyryl tri-n-hexyl citrate or acetyl tri-n-butyl citrate” (id.). The Examiner concludes that it would have been obvious to use “the PVC blood container comprising a citrate plasticizer for the container used in the method of Goodrich . . . because the citrate ester 2 Goodrich, Jr. et al., US 6,277,337 B1, Aug. 21, 2001. 3 COBE Spectra Apheresis System Operator’s Manual 1-1 to 1-63 (1997). 4 Mahal, EP 0,138,147 A2, Apr. 24, 1985. 5 Medical “Grade Citroflex®” Plasticizers 1-20 (1993). Appeal 2011-011270 Application 11/428,669 4 plasticized PVC container of Mahal is suitable for the storage of blood and blood components” (id.). The Examiner finds that, “[a]lthough Mahal does not teach triethyl citrate or acetyltriethyl citrate for the citrate plasticizer used in the PVC container, it is well known in the art that these species are citrate plasticizers called Citroflex®,” as disclosed in Medical Grade (id.). The Examiner concludes that it would have been obvious “to use the[se] well known citrate-ester plasticizers for the medical container of Mahal” (id.). “With regard to the steps of measuring the percentages of transmission of the container as a function of wavelength over said selected distribution of wavelengths, monitoring the power of radiation, calculating a radiant power and determining exposure time,” the Examiner finds “that these steps are directed to optimization steps of result-effective parameters associated with the photosensitization therapy of Goodrich” and that Goodrich teaches that “analyzing effects of inactivation based on various parameters (treatment conditions) such as energy level of exposure, photoradiation intensity, duration and photosensitizer concentration will optimize microbial inactivation and minimize damage to desired proteins and/or cellular components in the fluid” (id. at 6-7). In particular, the Examiner finds that “Example 4 disclosed by Goodrich, Jr. et al. is directed to measuring the percentages of transmission through a plastic cuvette” (id. at 7). The Examiner concludes that it would have been obvious “to carry out the optimization steps for the desired outcome by using the method of Goodrich” (id.). Appeal 2011-011270 Application 11/428,669 5 With regard to the “limitation directed to the container transmits electromagnetic radiation having a selected distribution of wavelengths, and that the transmission of electromagnetic radiation is substantially constant during exposure to electromagnetic radiation,” the Examiner concludes that, “since Goodrich, Jr. in view of Mahal teach the same container of citricized PVC bag as claimed, the citricized PVC bag of Goodrich in view of Mahal would have the same properties as the claimed container” (id. at 10). FINDINGS OF FACT 1. Goodrich discloses a method “for inactivation of microorganisms in fluids,” such as blood or blood products, including “adding an effective, non-toxic amount of an endogenous photosensitizer to a fluid and exposing the fluid to photoradiation sufficient to activate the endogenous photosensitizer whereby microorganisms are inactivated” (Goodrich, Abstract). 2. Goodrich also discloses: The fluid containing the photosensitizer is exposed to photoradiation of the appropriate wavelength to activate the photosensitizer. . . . The wavelength used will depend on the photosensitizer selected, as is known to the art or readily determinable without undue experimentation following the teachings hereof. Preferably the light source is a fluorescent or luminescent source providing light of about 300 nm to about 700 nm, and more preferably about 340 nm to about 650 nm of radiation. (Id. at col. 8, ll. 50-63.) 3. In addition, Goodrich discloses that the “fluid containing the photosensitizer may be flowed into a photopermeable container for irradiation” (id. at col. 9, ll. 17-18). Appeal 2011-011270 Application 11/428,669 6 4. Goodrich also discloses: “A cuvette has been used to exemplify one embodiment of the invention involving a flow-through system. Collection bags, such as those used with the Trima™ Spectra™ and apheresis systems of Cobe Laboratories, Inc., have been used to exemplify another embodiment involving batch-wise treatment of the fluid.” (Id. at col. 9, ll. 23-28.) 5. In addition, Goodrich discloses that the “term ‘photopermeable’ means the material of the container is adequately transparent to photoradiation of the proper wavelength for activating the photosensitizer” (id. at col. 9, ll. 29-31). 6. Goodrich also discloses that the “photopermeable container is preferably a blood bag made of transparent or semitransparent plastic” (id. at col. 9, ll. 55-56). 7. In addition, Goodrich discloses: “In an[] embodiment the fluid is placed in a photopermeable container such as a blood bag . . . and agitated while exposing to photoradiation. . . . Collection bags used in the Spectra™ system or Trima™ apheresis system of Cobe Laboratories, Inc. are especially suitable.” (Id. at col. 12, ll. 12-18.) 8. Goodrich also discloses: “Appropriate temperatures for the reaction of the photosensitizer with its substrate are determined, as well as the ranges of temperature, photoradiation intensity and duration, and photosensitizer concentration which will optimize microbial inactivation and minimize damage to desired proteins and/or cellular components in the fluid.” (Id. at col. 14, ll. 59-64.) Appeal 2011-011270 Application 11/428,669 7 9. In Example 4, Goodrich discloses: “The existing Spectra Cuvette is composed of polycarbonate. The light transmission properties of this cuvette were measured at 373 and 447 nm by placing the cuvette in the light path of a UV spectrophotometer. . . . For the region above 350 nm, the light transmission properties are adequate for this application.” (Id. at col. 20, ll. 39-60.) 10. Cobe is a manual “intended for the person who will be operating the COBE Spectra™ Apheresis System” (Cobe 1-1). 11. Cobe discloses collect bags “made from citricized PVC” (id. at 1-18). 12. Mahal discloses: “Citrate-ester plasticized polyvinyl chloride containers for the storage of blood and blood components. Preferred plasticizers include tri-esters of citric acid (or acylated citric acid) and 4-10 carbon alcohols such as acetyl tri-butyl citrate, n-butryl tri-n-hexyl citrate and acetyl tri-n-octyl or decyl citrate.” (Mahal, Abstract.) ANALYSIS In view of the forgoing findings of fact, we conclude that the Examiner has set forth a prima facie case that claim 20 would have been obvious. In particular, we agree with the Examiner that it would have been obvious to use “the PVC blood container comprising a citrate plasticizer for the container used in the method of Goodrich” (Ans. 6). “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’l Co. v. Teleflex Inc., 550 U.S. 398, 416 (2007). Appeal 2011-011270 Application 11/428,669 8 Appellants argue, however, that, from the teachings in Goodrich, “one skilled in the art would think that the illumination container must be made of polycarbonate, not citrate-plasticized PVC” (App. Br. 12). We are not persuaded. While Goodrich exemplifies a polycarbonate cuvette (Finding of Fact (FF) 9), Goodrich generally discloses a photopermeable container (FF 3), and, in fact, discloses the use of blood collection bags, such as those used with Cobe Spectra™ apheresis systems (FF 4 & 7), which use citricized PVC collection bags (FF 10-11). Appellants also argue: “Neither Mahal nor Goodrich . . . give[s] an indication that citrate-plasticized PVC containers would have the desired optical characteristics for irradiation of blood and blood components. Hence, there was no reasonable expectation of success in using the claimed method.” (App. Br. 16.) We are not persuaded. As discussed above, Goodrich generally discloses the use of a photopermeable container, which “means the material of the container is adequately transparent to photoradiation of the proper wavelength for activating the photosensitizer” (FF 3 & 5). To activate the photosensitizer, Goodrich discloses the use of a light source providing “light of about 300 nm to about 700 nm” (FF 2). In particular, Goodrich discloses that the “photopermeable container is preferably a blood bag made of transparent or semitransparent plastic” (FF 6). Mahal, as well as Cobe, discloses blood bags made from citrate- plasticized PVC (FF 10-12). We conclude that one of ordinary skill in the art would understand that citrate-plasticized PVC is photopermeable (see Spec. 27 (“The citrate plasticized poly(vinyl chloride) bag also significantly Appeal 2011-011270 Application 11/428,669 9 transmits (i.e. has percentage transmission greater than about 30%) light having wavelengths ranging from 285 nanometers to 365 nanometers.”)). As a result, we agree with the Examiner that there would have been a reasonable expectation for success. In addition, Appellants argue: There is . . . no teaching in Goodrich of the steps of: “measuring the percentages of transmission of said container as a function of wavelength over said selected distribution of wavelengths” “monitoring the power of said electromagnetic radiation generated by said light source” “calculating a radiant power delivered to said biological sample using said measured percentages of transmission of said container” and “determining an exposure time of said biological sample required to provide a desired extent of pathogen reduction.” (App. Br. 11.) We are not persuaded. Goodrich discloses measuring the amount of transmission of the container as a function of wavelength (FF 9). “While this measurement is based on the plastic (polycarbonate) cuvette,” we agree with the Examiner that it would have been obvious “to use the same assay system to determine light transmission [through citrate-plasticized PVC] in terms of percentage” (Ans. 7). In addition, we agree with the Examiner that, in order to optimize Goodrich’s method, it would have been obvious to monitor the power of the electromagnetic radiation generated by the light source, calculate a radiant power delivered to the biological sample using the measured percentages of transmission of the container, and determine an exposure time of the biological sample required to provide a desired extent of pathogen reduction (id. at 6-7; see FF 8). Appeal 2011-011270 Application 11/428,669 10 Appellants also argue that the claimed method “represents a significant and unexpected improvement over methods of irradiating blood contained in other types of containers” (App. Br. 15). However, Appellants have not presented sufficient evidence that the claimed method provides an unexpectedly superior result, as compared to the closest prior art, to overcome the prima facie case of obviousness. CONCLUSION The evidence supports the Examiner’s conclusion that representative claim 20 would have been obvious. We therefore affirm the obviousness rejection. TIME PERIOD FOR RESPONSE No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a). AFFIRMED lp