Treatment Of Liver Disease With Ring Finger Protein 213 (RNF213) Inhibitors

DETAILED ACTION Notice of Pre-AIA or AIA Status The present application, filed on or after March 16, 2013, is being examined under the first inventor to file provisions of the AIA . Continued Examination Under 37 CFR 1.114 A request for continued examination under 37 CFR 1.114, including the fee set forth in 37 CFR 1.17(e), was filed in this application after final rejection. Since this application is eligible for continued examination under 37 CFR 1.114, and the fee set forth in 37 CFR 1.17(e) has been timely paid, the finality of the previous Office action has been withdrawn pursuant to 37 CFR 1.114. Applicant's submission filed on 01/23/2026 has been entered. Claim Status Claims 1, 3, 8, 17, 37-39, 41-45, 58, and 97-98 are pending. Claims 1, 8, 17, 37-39, 41-43, 58, 97-98 and the species of NASH and SEQ ID NO: 2 are examined in this Action. Claims 3, 44 and 45 stand withdrawn. Priority All pending claims enjoy the benefit of U.S. provisional application 63/155,327 and 63/159,027, filed on 03/02/2021 and 03/10/2021, respectively. Information Disclosure Statement The information disclosure statement (IDS) submitted on 01/28/2026 was filed before the mailing date of this Office Action. The submission is in compliance with the provisions of 37 CFR 1.97. Accordingly, the information disclosure statement is being considered by the examiner. Claim Rejections - 35 USC § 112 35 U.S.C. 112(a): Written Description The following is a quotation of the first paragraph of 35 U.S.C. 112(a): (a) IN GENERAL.—The specification shall contain a written description of the invention, and of the manner and process of making and using it, in such full, clear, concise, and exact terms as to enable any person skilled in the art to which it pertains, or with which it is most nearly connected, to make and use the same, and shall set forth the best mode contemplated by the inventor or joint inventor of carrying out the invention. The following is a quotation of the first paragraph of pre-AIA 35 U.S.C. 112: The specification shall contain a written description of the invention, and of the manner and process of making and using it, in such full, clear, concise, and exact terms as to enable any person skilled in the art to which it pertains, or with which it is most nearly connected, to make and use the same, and shall set forth the best mode contemplated by the inventor of carrying out his invention. Claims 1, 8, 17, 37-39, 41-43, 58, 97-98 are rejected under 35 U.S.C. 112(a) or 35 U.S.C. 112 (pre-AIA ), first paragraph, as failing to comply with the written description requirement. The claim(s) contains subject matter which was not described in the specification in such a way as to reasonably convey to one skilled in the relevant art that the inventor or a joint inventor, or for applications subject to pre-AIA 35 U.S.C. 112, the inventor(s), at the time the application was filed, had possession of the claimed invention. Although the specification discloses some ~40,000 sequences of claimed RNF213 inhibitor, the specification does not disclose a single claimed “RNF213 inhibitor” that actually inhibits the expression of RNF213 following hybridization to an RNF213 mRNA in a liver cell of a human subject, as discussed further below. Claim 1 recites a method of decreasing expression of RNF213 polypeptide in a liver cell in a human following administration of a RNF213 inhibitor to a human subject, wherein the inhibitor comprises one of claimed nucleic acid inhibitor that hybridizes to an RNF213 and wherein the subject is RNF213 reference. The specification defines RNF213 reference as “when the human does not have a copy of an RNF213 predicted loss-of-function or missense variant” (par. 25). In light of the specification, the claimed invention encompasses a method of administering any of the claimed RNF213 inhibitor that hybridizes to a RNF213 mRNA with a subject lacking a copy of an RNF213 predicted loss-of-function or missense variant. Although not stated, but in light of the specification, which notes methods of treating a subject having various liver diseases comprising administering an RNF213 inhibitor to the subject (e.g., see pg. 2), the claimed subject matter encompasses treating a disease and the claimed RNF213 inhibitor is therapeutic. Independent cl. 37 is directed to a method of decreasing expression of RNF213 polypeptide in a liver cell in a human subject comprising 1) determining whether a human subject has a RNF213 predicted loss-of-function or missense variant nucleic acid molecule by genotyping for RNF213 predicted loss-of-function or missense variant nucleic acid molecule and, if the subject is RNF213 reference, then administering a therapeutic agent that treats liver disease and administer to the subject an RNF213 inhibitor, and, if the subject is heterozygous for an RNF213 pLof or missense variant nucleic acid molecule, the administer a lower than standard dose of therapeutic agent and administer an RNF213 inhibitor, wherein the RNF213 pLof or missense variant nucleic acid molecule comprises a nucleic acid molecule encoding claimed variants and the RNF213 inhibitor is the claimed nucleic acid inhibitors. Here, there is an explicit aim to treat liver disease in a human subject. In analyzing whether the written description requirement is met for genus claims, it is first determined whether a representative number of species have been described by their complete structure. In the instant case, the specification does not disclose a claimed RNF213 inhibitor that hybridizes to and decreases a RNF213 mRNA in a liver cell following administration to a human subject. Although the specification discloses some 40,000 nucleic acid sequences that are complementary to the target mRNA, it fails to describe the complete structure of a representative number of species of the large genus that hybridizes to a RNF213 mRNA and that decreases its expression following administration to a human subject. Next, then, it is determined whether a representative number of species have been sufficiently described by other relevant identifying characteristics (i.e. other than nucleotide sequence), specific features and functional attributes that would distinguish different members of the claimed genus. In the instant case, the only other identifying characteristic is that it is “RNF213 inhibitor.” Such a functional limitation cannot be an identifying characteristic for the claimed diverse genus of molecules since by Applicant’s definition of RNF213 inhibitor or functional equivalent thereof all members of the claimed genus will have that characteristic. The inventions of Claims 1 and 37 (dependent claims 8, 17, 38, 39, 41, 42, 43, 58, 97, 98 require the use of the inventions of Claim 1 and 37 and therefore are likewise rejected under 35 U.S.C. 112, first paragraph, as failing to comply with the written description requirement. Applicant’s attention is directed to the Guidelines for the Examination of Patent Applications Under the 35 U.S.C. 112(a) or Pre-AIA 35 U.S.C. 112, first paragraph, "Written Description" Requirement (MPEP2163). In conclusion, Applicant’s disclosure lack any claimed RNF213 inhibitor that hybridizes to a RNF213 mRNA in the liver cell of a human subject, the claimed broad genus is not deemed sufficient to reasonably convey to one skilled in the art that Applicant was in possession of the claimed broad genus at the time the application was filed. Thus, it is concluded that the written description requirement is not satisfied for the claimed genus. 112a-enablement Rejection of claims 1, 8, 17, 37-39, 41-43, 58 and 97-98 is maintained. The statute is noted above. Claims 1, 8, 17, 37-39, 41-43, 58, 97-98 are rejected under 35 U.S.C. 112(a) or 35 U.S.C. 112 (pre-AIA ), first paragraph, as failing to comply with the enablement requirement. The claim(s) contains subject matter which was not described in the specification in such a way as to enable one skilled in the art to which it pertains, or with which it is most nearly connected, to make and/or use the invention. When considering enablement of the invention, the Wands factors need to be reviewed, which poses whether the experimentation needed to practice the invention is undue or unreasonable. Determining undue experimentation requires analysis of, but not limited to: (A) The breadth of the claims; (B) The nature of the invention; (C) The state of the prior art; (D) The level of one of ordinary skill; (E) The level of predictability in the art; (F) The amount of direction provided by the inventor; (G) The existence of working examples; and (H) The quantity of experimentation needed to make or use the invention based on the content of the disclosure. MPEP 2164.03 provides the following: The amount of guidance or direction needed to enable the invention is inversely related to the amount of knowledge in the state of the art as well as the predictability in the art. In re Fisher, 427 F.2d 833, 839, 166 USPQ 18, 24 (CCPA 1970). The "amount of guidance or direction" refers to that information in the application, as originally filed, that teaches exactly how to make or use the invention. The more that is known in the prior art about the nature of the invention, how to make, and how to use the invention, and the more predictable the art is, the less information needs to be explicitly stated in the specification. In contrast, if little is known in the prior art about the nature of the invention and the art is unpredictable, the specification would need more detail as to how to make and use the invention in order to be enabling. Here, the art of record and the specification do not provide sufficient disclosure regarding a method of decreasing expression of RNF213 polypeptide in a liver cell in a human subject, the method comprising administering a RNF213 inhibitor, comprising an antisense nucleic acid molecule (ASN), siRNA or shRNA that hybridizes to RNF213 mRNA, wherein the subject is RNF213 reference. Thus, due to the lack of guidance, the application “need[s] more detail as to how to make and use the invention in order to be enabling.” And here, the application fails to provide details sufficient to make and use the invention since there is an unreasonable need of experimentation required and the invention is not enabling and the rejection is maintained as discussed below. In the instant case: The breadth of the claims/nature of the invention: Claim 1 recites a method of decreasing expression of RNF213 polypeptide in a liver cell in a human subject following administration of a RNF213 inhibitor to a human subject, wherein the inhibitor comprises one of claimed nucleic acid inhibitor that hybridizes to an RNF213 and wherein the subject is RNF213 reference, and wherein the RNF213 inhibitor comprises an antisense nucleic acid molecule (ANM), siRNA, or a shRNA that hybridizes to an RNF213 mRNA, and wherein the subject is RNF213 reference. The specification defines RNF213 reference as “when the human does not have a copy of an RNF213 predicted loss-of-function or missense variant” (pg. 9, line 2-3). In light of the specification, the claimed invention encompasses a method of administering the claimed RNF213 inhibitor that hybridizes to a RNF213 mRNA with a subject lacking a copy of an RNF213 predicted loss-of-function or missense variant; thus, under BRI, the subject’s RNF213 is considered wild-type. Although not stated, but in light of the specification, which notes treating a subject having various liver diseases comprising administering an RNF213 inhibitor (e.g., see pg. 2 and cl. 97 and 98), the claimed subject matter encompasses treating a liver disease. Thus, the Wands factor analysis will focus on treatment of claimed liver disease and/or decreasing expression of a RNF213 following administration of claimed RNF213 inhibitor. Independent cl. 37 is directed to a method of decreasing expression of RNF213 polypeptide in a liver cell in a human subject comprising 1) determining whether a human subject has a RNF213 predicted loss-of-function or missense variant nucleic acid molecule by genotyping for RNF213 predicted loss-of-function (pLof) or missense variant nucleic acid molecule and, 2) if the subject is RNF213 reference, then administering claimed dose of therapeutic agent that treats liver disease and administer to the subject an RNF213 inhibitor, and, 3) if the subject is heterozygous for an RNF213 pLof or missense variant nucleic acid molecule, then administer claimed dose of therapeutic agent and administer an RNF213 inhibitor, wherein the RNF213 pLof or missense variant nucleic acid molecule comprises a nucleic acid molecule encoding claimed variants and the RNF213 inhibitor is the claimed nucleic acid inhibitors. Thus, the Wands factor analysis will focus on treatment of claimed liver disease and/or decreasing expression of a RNF213 following administration of claimed RNF213 inhibitor. The state of the prior art: RNF213: Otten et al. (5/2021, Nature, 594, 111-116) note that RNF213 is the largest recognized human E3 ligase, a mass of about 600 kDa, and is a major susceptibility gene for a cerebrovascular disorder called moyamoya disease (MMD), which is caused by a missense mutation in RNF213 (pg. 113). Further, RNF213 physiological and pathophysiological role is not well understood: an involvement in lipotoxicity, lipid droplet formation, cell death and NF-kB signaling have been reported (pg. 113). One case study of two patients with MMD, indicates an association with liver disease and a variant RNF213 genotype. Strong et al.’s (5/2021, American Medical J. of Medical Genetics, 185A, 2168-2174) analysis of a couple of children patients with MMD identified RNF213 variants potentially associated with MMD (L4139W, C4856R) and other symptoms, such as “liver disease with elevated aminotransferase [AST],” along with other physiological abnormalities, but indicate that it “is unknown at this time why these patients demonstrate such severe cerebral and extra-cerebral manifestations” and noting that the RNF213 variants identified could be a culprit (pg. 2172). Further, the authors note that it “will be interesting to determine if RNF213 variants can produce exclusively extra-cerebral disease with isolated kidney, liver and skin findings. Such patients would be critical in truly elucidating the biology of RNF213 and the mechanism of disease” (pg. 2173). Morito and Nagata (JP2020105134, pub date 07/09/2020, of record) disclose that RNF213 (also known as mysterin) is associated with the accumulation of lipid droplets, Morito and Nagata teach that inhibiting or suppressing the expression of RNF213/mysterin by use of siRNA targeting RNF213 leads to decomposition/metabolism of lipid droplets consequently leading to reduction in lipid droplets in cells, and leading the authors to conclude the potential role of these mutations in MMD (par. 6 (pg. 4) and par. 8 (pg. 6) of Espacenet provided machine translation, accessed 07/09/2023, of record). Further, based on its in vitro studies, the authors extrapolate that mysterin inhibitors can be used to treat lifestyle diseases caused by the accumulation of lipid droplets, one such disease is non-alcoholic hepatis, cirrhosis (par. 17). Nucleic Acid inhibitors: The claims encompass treatment with RNF213 inhibitor comprising antisense nucleic acid molecule (ASN), siRNA, or shRNA that hybridizes to an RNF213 mRNA. It is known that various nucleic acid inhibitors, including siRNAs and antisense oligonucleotide (ASOs), have been approved for human treatment. Usually, prior to human administration, there are series of steps/studies that need to be taken before a siRNA/shRNA/ASN drug can be administered to a human subject. Focusing on one type of nucleic acid inhibitor, an siRNA, Paton (2017, Drugs of the Future, 42, 335-343) discloses steps taken to identify a therapeutic siRNA: 1) identify siRNA(s) that specifically hybridizes with the target gene, ideally in multiple species, including human; 2) conduct bioinformatic analysis to design ~100 siRNAs for cross-species hybridization/activity (pg. 337); 3) conduct in vitro studies to identify a handful of siRNAs with ideal inhibition (i.e. ED50) values (pg. 337); 4) conduct in vivo studies in model organisms (usually includes mice and monkeys) to demonstrate inhibition of target gene using modified siRNA that is sufficiently stable and is protected from in vivo degradation enzymes and effects (pg. 337); 5) identify a delivery vehicle to improve delivery of siRNAs and maximize potency, which either includes further modification of the siRNA or identify a vector to deliver the siRNA to target organ/tissue (pg. 337-338); 6) undergo clinical studies to identify modified siRNAs in delivery vehicle that has least side-effects with optimal outcome (pg. 338-339). The level of predictability in the art: The level of predictability in the art is low. As noted above under MPEP 2164.03, due to the lack of guidance in the prior art, the application needs more detail as to how to make and use the invention in order to be enabling. However, the specification fails to provide sufficient guidance. First, as Otten notes that there is a lack of understanding of RNF213: there is uncertainty regarding its cellular and physiological function, and its role in liver disease, and, further, uncertainty whether the inhibition of RNF213 mRNA in a human subject of RNF213 reference will treat any liver disease or NASH. Further, prior art of record does not indicate that therapeutic agents that treat a liver disease would treat a human subject with a liver disease harboring a RNF213 reference, i.e. without a pLoF or missense variant. Second, although Strong et al. show an association between RNF213 and a liver disease, the authors indicate that it “is unknown at this time why these patients demonstrate such severe cerebral and extra-cerebral manifestations” and indicate that further studies need to be conducted (pg. 2172, 2173). Strong et al. is silent whether RNF213 inhibition would treat the patient with noted liver ailment. Thus, the art of record does not provide studies/suggestion that demonstrate that inhibition of non-variant RNF213 in a human subject or decreasing the levels of RNF213 mRNA treats any liver disease (claims 1, 37) or NASH (claims 97,98). Based on the little information known about the large 600 kDa protein, it is unpredictable whether administration of any one of ASN, siRNA or shRNA that hybridizes to an RNF213 mRNA of a human subject, who is RNF213 reference, will treat a human subject having any liver disease or decrease the expression of RNF213. Third, even following extensive in vitro/in vivo studies and optimal outcome in clinical studies, it is still uncertain that the drug may achieve its desired results. Paton article, noted above, discusses the steps of bringing the siRNA drug inclisiran to market, and Zhang (1/2021, Biochemical Pharmacology, 189, 1-12) indicates, despite noting some promising possibilities with siRNA drugs, that “[d]espite inclisiran’s projected success, however, some experts caution that it may not live up to expectations,” that although it decreased the target gene’s expression level, it did not achieve desired outcome, i.e. an improved cardiovascular outcome (pg. 8). Thus, it is unpredictable that inhibiting a transcript’s expression at its optimal level will result in desired physiological outcome, here it is unpredictable whether inhibiting expression of RNF213 in a human subject with RNF reference will treat any liver disease or NASH. Also, here, the claimed subject matter recites some 40,000 ASNs and siRNAs, and under BRI and, also, one of skill in the art would expect that all these Markush group species when administered along with a recited dosage of therapeutic agent to a human subject having NASH or any liver disease, will treat the aforementioned disease or decrease expression of a RNF213 by hybridization in a human subject. However, here, the specification does not disclose a specific single siRNA or ASN or shRNA hybridizing to the target mRNA in a human subject, nor disclose an in vitro study to show inhibition of target molecule, nor disclose a study of a human subject treated with recited RNF213 inhibitor(s) that hybridizes to and inhibits expression of target mRNA in vivo and bring about the outcome of treating any liver disease/NASH. Including the results of aforementioned studies would aid a skilled artisan in overcoming the uncertainty regarding the subject matter of the invention. One of skill in the art is aware of many software platforms that identify exemplary siRNAs, however, Gavrilov (2012, Yale J. Biol. Med., 85, pg. 187-200) points out that “[o]ff-target silencing cannot be ignored in developing siRNA-based therapeutics, and all potential therapeutic siRNA candidate sequences must be heavily tested for perturbation of normal protein expression profiles” (pg. 191). Exome sequencing studies — Although genome/exome sequence studies are gaining in prominence due to reduced costs, there are still issues concerning the causal link that is suggested between the genetic variation and a disease phenotype. Burgess et al. (2018, Ann. Rev. of Genomics and Human Genetics, 19, 303-327) disclose that an observational correlation between a suspected risk factor and an outcome does not necessarily imply that interventions on levels of risk factor will have a causal impact on the outcome (correlation is not causation) (Abstract). It could be an issue of confounders, common determinants of the risk factor and the outcome, that give rise to the association (pg. 305). Another observation noted in the specification is a “strongest variant for AST” is Glu3915Gly, while strongest variant for ALT was an intronic variant that results in Val3838Leu protein mutation. ALT, alanine transaminase, is produced only in hepatocytes and is a “very specific marker of hepatocellular injury,” while AST, aspartate transaminase, is a cytosolic enzyme present in various tissues, such as skeletal muscle, heart muscle, and kidney tissue, not just only liver tissues (Hall and Cash, Ulster Medical Journal, 2012, Table 1). Thus, Hall and Cash caution in using AST levels to evaluate hepatocellular damage and note that AST usually rises in conjunction with ALT to indicate hepatocellular injury (Hall and Cash, 2012, Ulster Medical Journal, 81, pg. 30-36, Table 1). Thus, leading one to question if the putative protective genetic mutations are correlative with AST or ALT levels and not associated with reducing the risk of NASH/liver damage since AST levels are not conclusively tied with status of liver function. A doctoral thesis by Lin (The Role of Ring Finger Protein 213 in Fatty Acid-induced lipotoxicity, 6/1/2023) evaluating the role of RNF213 in RNF213 knock out (KO) mice in a dietary NASH model indicated that KO mouse livers “show a mild protection phenotype against liver damage and does not alter hepatic steatosis” and the results led the author to conclude that “the data did not favorably support the role of RNF213 in NASH in the context of saturated fatty acid toxicity in vivo, which may be due to the diet not raising levels conducive for severe NASH development” (Abstract). The amount of direction provided by the inventor/existence of working examples: Here, the applicant claims to have a probable “rare variant” or a list of probable rare variants with a reduced risk of liver disease (pg. 7, line 28-29). The specification describes a “discovery analysis in UKB and GHS was performed to identify new genetic variants and genes associated with liver injury as measured by aspartate aminotransferase (AST) and alanine aminotransferase (ALT), which are widely used measures of liver damage” (pg. 96, lines 22-25). The goal of the genome association studies was to “discover protective genes” (pg. 96, line 24-25, line 29; Ex. 1). Second, association of rare predicted loss-of-function (pLof) in RNF213 gene with ALT and AST was estimated using exome sequence data (pg. 97, lines 2-4). The result demonstrated 1,773 carriers of a pLoF variants in RNF213 had significantly reduced circulating AST and ALT levels (pg. 98, line 10). Paton provides needed steps to identify a therapeutic siRNA and these studies are usually expected by a person skill in the art (including a medical professional) before attempting to administer the siRNA drug to a human subject: the siRNA hybridization to target mRNA and consequent decrease in the expression of target mRNA/protein, treatment of the recited ailment following, and, ideally, also understanding of potential unexpected side-effects. Instant specification also does not provide any studies demonstrating administration of recited RNF213 inhibitor in an in vivo animal model with a reference RNF213 mRNA that treats liver disease, alone or co-administration with a therapeutic agent. Nor does the specification provide “protective” studies with the pLoF/missense variants recited in claim 37. All these studies, i.e. in vitro and in vivo studies, are missing in instant specification for one of skill in the art to practice the invention as claimed. The quantity of experimentation: undue experimentation: MPEP 2161.01 (III) provides that for enablement: The specification need not teach what is well known in the art. However, applicant cannot rely on the knowledge of one skilled in the art to supply information that is required to enable the novel aspect of the claimed invention when the enabling knowledge is in fact not known in the art. ALZA Corp. v. Andrx Pharms., LLC, 603 F.3d 935, 941, 94 USPQ2d 1823, 1827 (Fed. Cir. 2010) ("ALZA was required to provide an adequate enabling disclosure in the specification; it cannot simply rely on the knowledge of a person of ordinary skill to serve as a substitute for the missing information in the specification.") . . .The Federal Circuit has stated that "‘[i]t is the specification, not the knowledge of one skilled in the art, that must supply the novel aspects of an invention in order to constitute adequate enablement.’" Auto. Technologies, 501 F.3d at 1283, 84 USPQ2d at 1115 (quoting Genentech, Inc. v. Novo Nordisk A/S, 108 F.3d 1361, 1366, 42 USPQ2d 1001, 1005 (Fed. Cir. 1997)). . . Therefore, the specification must contain the information necessary to enable the novel aspects of the claimed invention. Id. at 941, 94 USPQ2d at 1827; Auto. Technologies, 501 F.3d at 1283-84, 84 USPQ2d at 1115 ("[T]he ‘omission of minor details does not cause a specification to fail to meet the enablement requirement. However, when there is no disclosure of any specific starting material or of any of the conditions under which a process can be carried out, undue experimentation is required.’") (emphasis added). As provided by MPEP2161.01(III), here the specification does not provide adequate enabling disclosure of its claimed novel aspects of the invention. The specification does not provide 1) if a) the “predicted loss-of-function” is actually a loss-of-function mutant and not a benign mutation; b) any studies demonstrating a causal link between genetic mutations and their protective nature, either in vivo or in vitro, and/or 2) how the noted mutations are able to lower the risk of NASH or liver disease and 3) studies demonstrating the use of any ASN, siRNA or shRNA RNF213 inhibitor that hybridizes to the target RNF213 mRNA in human subject and that treats any liver disease, including NASH, in a human subject. Thus, the quantity of experimentation needed to make or use the invention is undue or unreasonable. Thus, for all the reasons noted above, claims 1, 8, 17, 37-39, 41-43, 58, 97-98 do not provide adequate disclosure to enable a person of ordinary skill in the art to use the claimed invention without resorting to undue experimentation and are rejected under 35 U.S.C. 112(a). Response to Arguments Applicant's arguments filed 01/23/2026 (“the Remarks”) have been fully considered but they are not persuasive. The main argument, under the basis that undue experimentation is not required, is that “design of siRNA molecules was sufficiently mature as of the earliest filing date to which the present application is entitled” and provides screenshot of “at least one supplier” that is “willing to offer a guarantee of effective silencing of target mRNA molecules in vivo” (pg. 12-13). The guarantee offer, based on WayBackMachine entry, predates Paton’s reference and thus “more closely approximates the state of the art” (pg. 13). The argument is not persuasive. Putting aside contract law consideration of an offer of guarantee, the guarantee only indicates that the supplier is willing to test out various siRNAs to identify one that works and provide it to the customer. The guarantee only shifts the undue experimentation to the supplier, but undue experimentation remains. Although the supplier’s guarantee predates Paton’s reference, the supplier does not provide a claimed RNF213 nucleic acid inhibitor that decreases the expression of RNF213 in liver of a human subject, nor to the subject matter of the invention, to treat a liver disease. Nor has the supplier nor the Applicant conducted all or some of the steps indicated by Paton to be able to administer a siRNA to the liver of a human subject to either decrease expression of target protein or to treat a liver disease with a reasonable success. Thus, the rejection is maintained. 35 U.S.C. 112(b): Rejection of claims 37-39, 41-43, 58 and 98 under 112(b) is withdrawn. Allowable Subject Matter No claims are allowed. Conclusion Any inquiry concerning this communication or earlier communications from the examiner should be directed to KEYUR A. VYAS whose telephone number is (571)272-0924. The examiner can normally be reached M-F 9am - 4 pm (EST). Examiner interviews are available via telephone, in-person, and video conferencing using a USPTO supplied web-based collaboration tool. To schedule an interview, applicant is encouraged to use the USPTO Automated Interview Request (AIR) at http://www.uspto.gov/interviewpractice. If attempts to reach the examiner by telephone are unsuccessful, the examiner’s supervisor, Jennifer Dunston can be reached on 571-272-2916. The fax phone number for the organization where this application or proceeding is assigned is 571-273-8300. Information regarding the status of published or unpublished applications may be obtained from Patent Center. Unpublished application information in Patent Center is available to registered users. To file and manage patent submissions in Patent Center, visit: https://patentcenter.uspto.gov. Visit https://www.uspto.gov/patents/apply/patent-center for more information about Patent Center and https://www.uspto.gov/patents/docx for information about filing in DOCX format. For additional questions, contact the Electronic Business Center (EBC) at 866-217-9197 (toll-free). If you would like assistance from a USPTO Customer Service Representative, call 800-786-9199 (IN USA OR CANADA) or 571-272-1000. /KEYUR A VYAS/Examiner, Art Unit 1637 /Soren Harward/Primary Examiner, TC 1600