Isotope Dilution DNA Logic Circuits for Multiple Output and Absolute Quantification

DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often su...

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Published in	Analytical chemistry (Washington) Vol. 97; no. 12; pp. 6670 - 6677
Main Authors	Zhu, Yiyan, Wei, Chao, Li, Ziyan, Li, Yan, Liu, Rui, Lv, Yi
Format	Journal Article
Language	English
Published	United States American Chemical Society 01.04.2025
Subjects	analytical chemistry Biomarkers Circuits Computation Computers, Molecular Deoxyribonucleic acid Dilution DNA DNA - chemistry DNA probes Gadolinium isotopes Humans International System of Units isotope dilution technique Isotopes Isotopes - chemistry lanthanides Lanthanoid Series Elements - chemistry Logic circuits Mass Spectrometry Mass spectroscopy microRNA MicroRNAs - analysis miRNA
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Abstract	DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The 155Gd-enriched isotope and 145Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis.
AbstractList	DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The Gd-enriched isotope and Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis. DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The 155Gd-enriched isotope and 145Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis.DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The 155Gd-enriched isotope and 145Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis. DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The 155Gd-enriched isotope and 145Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis. DNA logic circuits have gained great success in the past, thanks to their distinct performance regarding the scalability and correctness of computation. However, there are still two challenges often considered for DNA logic circuit-based computation. First, the mainstream optical probes are often subject to spectral overlapping interference for complex multitask analysis and outputs. Second, absolute quantification results traceable to the primary international system of units are mission impossible, especially for interlaboratory comparisons and quality assurances. Herein, we constructed DNA logic circuits encoded with lanthanide isotopes and decoded by elemental mass spectrometry. The ¹⁵⁵Gd-enriched isotope and ¹⁴⁵Nd-enriched isotope were incorporated in the DNA logic circuits for the isotope dilution-based absolute quantification of microRNAs. The proposed isotopic DNA logic circuits greatly enhance the multiplexity and computation accuracy, which poses a great potential for cancer biomarker-related diagnosis.
Author	Liu, Rui Li, Ziyan Wei, Chao Lv, Yi Zhu, Yiyan Li, Yan
AuthorAffiliation	Key Laboratory of Green Chemistry & Technology, College of Chemistry Key Laboratory of Green Chemistry & Technology, Analytical & Testing Center
AuthorAffiliation_xml	– name: Key Laboratory of Green Chemistry & Technology, Analytical & Testing Center – name: Key Laboratory of Green Chemistry & Technology, College of Chemistry
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SubjectTerms	analytical chemistry Biomarkers Circuits Computation Computers, Molecular Deoxyribonucleic acid Dilution DNA DNA - chemistry DNA probes Gadolinium isotopes Humans International System of Units isotope dilution technique Isotopes Isotopes - chemistry lanthanides Lanthanoid Series Elements - chemistry Logic circuits Mass Spectrometry Mass spectroscopy microRNA MicroRNAs - analysis miRNA
Title	Isotope Dilution DNA Logic Circuits for Multiple Output and Absolute Quantification
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