SINGLE MOLECULE NANOPARTICLE NANOWIRE FOR MOLECULAR ELECTRONIC SENSING

§102 §103

DETAILED ACTION Status of the Claims 1. Claims 1-18 are pending. Continued Examination Under 37 CFR 1.114 2. 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and the fee set forth in 37 CFR 1.17(e) has been timely paid, the finality of the previous Office action has been withdrawn pursuant to 37 CFR 1.114.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 12/04/2025 has been entered. Status of the Rejections 3. Rejection of claims 1-8 and 12-17 in view of Choi et al. is being modified in view of applicant’s amendments. Claim Rejections - 35 USC § 102 The following is a quotation of the appropriate paragraphs of 35 U.S.C. 102 that form the basis for the rejections under this section made in this Office action: A person shall be entitled to a patent unless – (a)(1) the claimed invention was patented, described in a printed publication, or in public use, on sale, or otherwise available to the public before the effective filing date of the claimed invention. 3. Claim(s) 1-8 and 12-17 is/are rejected under 35 U.S.C. 102(a)(1) as being anticipated by Choi et al. (US 2019/0039065). Claim 1. Choi et al. teach a molecular complex configured to bridge a nanogap between a complementary pair of electrodes (DNA bridges nanogap between pair of electrodes; [0015]), the molecular complex comprising: an oligonucleotide biomolecule having first end and a second end (DNA has first and second ends; [0015][0024]), wherein at least one of the first end or the second ends of the oligonucleotide biomolecule comprises a terminal 3' thiol modification (DNA has thiol groups [0049]; since DNA binds to Au coated nanoparticles from both ends/terminal i.e. 3’ and 5’ (see Fig 7a), thus DNA comprises terminal 3’ thiol modification); a first nanoparticle to couple with the first end of the oligonucleotide biomolecule (see fig 7a); a second nanoparticle to couple with the second end of the oligonucleotide biomolecule (see fig 7a); and the first end of the oligonucleotide biomolecule is conjugated to the first nanoparticle and the second end of the oligonucleotide biomolecule is conjugated to the second nanoparticle (DNA is coupled to the nanoparticles using thiol group [0049]); wherein a combination of the oligonucleotide biomolecule and each of the first and the second nanoparticles forms an integrated molecular complex prior to disposition on the complementary electrode pair (DNA 72 already tagged with Au coated magnetic nanoparticles 71 is deposited on the electrode pair; [0066][0067] and wherein the oligonucleotide biomolecule comprises 15 or 25 nm thiolated forward and reverse sequences (thiolated DNA bridges nanogap of 5-20 nm [0039], thus it is apparent the DNA which inherently comprises forward and reverse strand sequences has 15 nm length sequences as claimed as it bridges a nanogap in a range from 5-20 nm). Claim 2. Choi et al. teach the oligonucleotide biomolecule comprises a double stranded nucleic acid (dsDNA) having a thiolated end and wherein the first nanoparticle couples to the biomolecule through the thiolated end of the biomolecule (DNA having SH end couple to nanoparticle; [0049], DNA is double stranded). Claim 3. Choi et al. teach the oligonucleotide biomolecule comprises one of a single strand or a double-stranded nucleic acid (the biomolecule is DNA; [0049]). Claim 4. Choi et al. teach the molecular complex is conductive (biomolecule is bridge in the nanogap through which electronic current or voltage signals are detected; [0039]). Claim 5. Choi et al. teach the first and the second nanoparticles are stabilized to prevent nanoparticle aggregation (the nanoparticles have slight surface oxidation as a protective coat to provide chemical stability; [0067], thus preventing nanoparticle aggregation). Claims 6 and 8. Choi et al. tach method for making a molecular complex configured to bridge a nanogap between a complementary pair of electrodes (biomolecule complex bridges nanogap between pair of electrodes; [0015]), the method comprising: forming a nucleic acid [ssDNA and dsDNA] having a first and a second functionalized ends (DNA has thiol groups on each terminal [0049][0015]; forming a plurality of nanoparticles, the plurality of nanoparticles comprising a first nanoparticle and a second nanoparticle (Au coated nanoparticles; [0015]; conjugating the first functionalized end of the nucleic acid with the first nanoparticle; and conjugating the second functionalized end of the nucleic acid with the second nanoparticle; wherein the nucleic acid comprises two complementary single stranded nucleic acids with terminal 3' thiol modification to conjugate separately with each of the first and the second nanoparticles (DNA has thiol groups on each terminal [0049]; since biomolecule binds to Au from both ends/terminal i.e. 3’ and 5’ (see Fig 7a), thus biomolecule comprises terminal 3’ thiol modification); and wherein a combination of the biomolecule and each of the first and the second nanoparticles forms an integrated molecular complex prior to disposition on the complementary electrode pair (biomolecule 72 already tagged with Au coated magnetic nanoparticles 71 is deposited on the electrode pair; [0066][0067] wherein the biomolecule comprises an oligonucleotide biomolecule having 15 or 25 nm thiolated forward and reverse sequences (thiolated DNA bridges nanogap of 5-20 nm [0039], thus it is apparent the DNA which inherently comprises forward and reverse strand sequences has 15 nm length sequences as claimed as it bridges a nanogap in a range from 5-20 nm). Claim 7. Choi et al. teach the oligonucleotide biomolecule comprises one of a single strand or a double-stranded nucleic acid (the biomolecule is DNA; [0049]). Claim 12. A molecular sensor array (molecular electronic device comprising parallel electronic sensing array [0047]), comprising: at least one sensor having: a first nanoelectrode and a second nanoelectrode, the first and the second nanoelectrodes separated by a gap, the first nanoelectrode and the second nanoelectrodes forming an electrode pair (nanogap between pair of electrodes; [0011]); a molecular complex extended between the first nanoelectrode and the second nanoelectrode (biomolecule complex bridges nanogap between pair of electrodes; [0011]), the molecular complex further comprising: a biomolecule having first end and a second end, wherein at least one of the first end or the second ends of the biomolecule comprises a terminal 3' thiol modification (biomolecule has thiol groups [0049]; since biomolecule binds to Au from both ends/terminal i.e. 3’ and 5’ (see Fig 1d), thus biomolecule comprises terminal 3’ thiol modification; a first nanoparticle to couple with the first end of the biomolecule (see Fig 1d); a second nanoparticle to couple with the second end of the biomolecule (see Fig 1d); and the first end of the biomolecule is conjugated to the first nanoparticle and the second end of the biomolecule is conjugated to the second nanoparticle (biomolecules is coupled to the nanoparticles using thiol group [0049]); wherein the biomolecule is functionalized with a terminal 3' thiol modification to conjugate separately with each of the first and the second nanoparticles (biomolecule has thiol groups [0049]; since biomolecule binds to Au from both ends/terminal i.e. 3’ and 5’ (see Fig 1d), thus biomolecule comprises terminal 3’ thiol modification; wherein the biomolecule further comprises oligonucleotide biomolecule having 15 or 25 nm thiolated forward and reverse sequences (thiolated DNA bridges nanogap of 5-20 nm [0039], thus it is apparent the DNA which inherently comprises forward and reverse strand sequences has 15 nm length sequences as claimed as it bridges a nanogap in a range from 5-20 nm). Claim 13. Choi et al. teach the biomolecule comprises one of a single strand or a double-stranded nucleic acid (the biomolecule is DNA; [0049]). Claim 14. Choi et al. teach the molecular complex is conductive (biomolecule is bridge in the nanogap through which electronic current or voltage signals are detected; [0039]). Claim 15. Choi et al. teach the first and the second nanoparticles are stabilized to prevent nanoparticle aggregation (the nanoparticles have slight surface oxidation as a protective coat to provide chemical stability; [0067], thus preventing nanoparticle aggregation). Claim 16. Choi et al. teach the molecular complex defines a length substantially equal to the gap and wherein the length is selected from the group consisting of 10-15 nm, 15-25nm, 25-35 nm, 35-45 nm, 45-100 nm, 100 nm - 500 nm, 500 nm - 1 um (the nanogap is 5-20 nm; [0039] and biomolecule complex bridges the gap, thus the biomolecule complex has a length substantially equal to the nanogap). Claim 17. Choi et al. teach a passivation layer supporting the nanoelectrodes and a substrate to support the passivation layer (substrate with SiO2 insulator surface; see Fig 2). Claim Rejections - 35 USC § 103 The following is a quotation of 35 U.S.C. 103 which forms the basis for all obviousness rejections set forth in this Office action: A patent for a claimed invention may not be obtained, notwithstanding that the claimed invention is not identically disclosed as set forth in section 102, if the differences between the claimed invention and the prior art are such that the claimed invention as a whole would have been obvious before the effective filing date of the claimed invention to a person having ordinary skill in the art to which the claimed invention pertains. Patentability shall not be negated by the manner in which the invention was made. The factual inquiries for establishing a background for determining obviousness under 35 U.S.C. 103 are summarized as follows: 1. Determining the scope and contents of the prior art. 2. Ascertaining the differences between the prior art and the claims at issue. 3. Resolving the level of ordinary skill in the pertinent art. 4. Considering objective evidence present in the application indicating obviousness or nonobviousness. Claim(s) 9-11 and 18 is/are rejected under 35 U.S.C. 103 as being unpatentable over Choi et al. as applied to claims 1, 6 and 12 above, and further in view of Strobel et al. (Phys.Chem. Chem. Phys., 2011, 13, 9973-9977). Claim 9. Choi et al. do not teach coupling the first nanoparticle to a first nanoelectrode via a surface ligand and wherein the surface ligands is selected from the group consisting of citrate, amine, tannic acid, dodecanethiol, carboxyl, polyethylene glycol (PEG), Polyvinylpyrrolidone (PVP) may be capped onto the nanoparticle. However, Strobel et al. teach method making DNA-coated gold nanoparticles comprising the step of forming citrate-stabilized gold nanoparticles with phosphine (bis(p-sulfonatophenyl)phenylphosphine dihydrate dipotassium salt for at least 12 hours and combining with thiolated dsDNA (page 9974, col.1, paragraph 2 over to col. 2). Therefore, it would have been obvious to one of ordinary skill in the art before the effective filing date of the invention in view of Strobel et al. teaching to add the step of reacting the nanoparticle with bis(p-sulfonatophenyl)phenylphosphine dihydrate dipotassium salt (BSPP) to form stable citrate nanoparticles and thereby provide stabilized DNA-nanoparticle. Claim 10, modified Choi et al. teach coupling the second nanoparticle to a second nanoelectrode and extending the molecular complex to substantially bridge a nanogap between the first and the second nanoelectrodes (biomolecule complex bridges nanogap between pair of electrodes; see Choi et al. [011]). Claim 11, Choi et al. do not teach method step of purifying plurality of nanoparticles by incubating a plurality of raw nanoparticles comprising incubating at least two nanoparticle with a citrate compound on the surface thereof with bis(p-sulfonatophenyl)phenylphosphine dihydrate dipotassium salt (BSPP) for a period of about 8 hours to substantially stabilize the citrate compound and combining the stabilized first and second nanoparticles with thiolated double stranded DNA (dsDNA). However, Strobel et al. teach method making DNA-coated gold nanoparticles comprising the step of forming citrate-stabilized gold nanoparticles with phosphine (bis(p-sulfonatophenyl)phenylphosphine dihydrate dipotassium salt for at least 12 hours and combining with thiolated dsDNA (page 9974, col.1, paragraph 2 over to col. 2). Therefore, it would have been obvious to one of ordinary skill in the art before the effective filing date of the invention in view of Strobel et al. teaching to add the step of reacting the nanoparticle with bis(p-sulfonatophenyl)phenylphosphine dihydrate dipotassium salt (BSPP) to form stable citrate nanoparticles and thereby provide stabilized DNA-nanoparticle. Claim 18. Choi et al. teach positioning of the molecular complex in the nanogap [0011] but do not explicitly teach an induction source to induce positioning of the molecular complex substantially in the gap. However, Strobel et al. teach trapping DNA-Au nanoparticles in the nanogap using dielectrophoretic field in order to achieve controlled functionalization of nanogap (see 9974, col. 2, paragraph 2). Therefore, it would have been obvious to one of ordinary skill in the art before the effective filing date of the invention in view of Strobel to use dielectrophoretic force to place the molecular complex of Choi et al. into the nanogap because dielectrophoretic force would place the DNA-Au complex in nanogap in a controlled manner in order to properly sequence the DNA. Response to Arguments Applicant's arguments filed 12/04/2025 have been fully considered but they are not persuasive. Applicant argues on pages 7-8 of remarks that the cited prior art, Choi et al. does not teach oligonucleotide biomolecule comprises 15 or 25 nm thiolated forward and reverse sequences. In response, examiner respectfully disagrees with applicant’s assertion. Choi et al. teach thiolated DNA bridges nanogap of 5-20 nm [0039], thus it is apparent the DNA which inherently comprises forward and reverse strand sequences has 15 nm length sequences as claimed as it bridges a nanogap in a range from 5-20 nm which includes 15 nm. Conclusion Any inquiry concerning this communication or earlier communications from the examiner should be directed to GURPREET KAUR whose telephone number is (571)270-7895. The examiner can normally be reached M-F 9:30-6. 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, Curtis Mayes can be reached at 571-272-1234. 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