同位素稀释DNA逻辑电路多输出和绝对定量

IF 6.7 1区化学 Q1 CHEMISTRY, ANALYTICAL

Analytical Chemistry Pub Date : 2025-03-06 DOI:10.1021/acs.analchem.4c06637

Yiyan Zhu, Chao Wei, Ziyan Li, Yan Li, Rui Liu, Yi Lv

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引用次数: 0

摘要

DNA 逻辑电路凭借其在计算的可扩展性和正确性方面的独特性能，在过去取得了巨大成功。然而，基于 DNA 逻辑电路的计算通常仍面临两个挑战。首先，主流光学探针在进行复杂的多任务分析和输出时往往会受到光谱重叠干扰。其次，可追溯到主要国际单位制的绝对定量结果是不可能的，尤其是在实验室间比较和质量保证方面。在此，我们构建了用镧系同位素编码并用元素质谱解码的 DNA 逻辑电路。将富含 155Gd 的同位素和富含 145Nd 的同位素纳入 DNA 逻辑电路，用于基于同位素稀释的 microRNA 绝对定量分析。所提出的同位素 DNA 逻辑电路大大提高了复用性和计算精度，在癌症生物标志物相关诊断方面具有巨大潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Isotope Dilution DNA Logic Circuits for Multiple Output and Absolute Quantification

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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 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.

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来源期刊

Analytical Chemistry 化学-分析化学

CiteScore

12.10

自引率

12.20%

发文量

1949

审稿时长

1.4 months

期刊介绍： Analytical Chemistry, a peer-reviewed research journal, focuses on disseminating new and original knowledge across all branches of analytical chemistry. Fundamental articles may explore general principles of chemical measurement science and need not directly address existing or potential analytical methodology. They can be entirely theoretical or report experimental results. Contributions may cover various phases of analytical operations, including sampling, bioanalysis, electrochemistry, mass spectrometry, microscale and nanoscale systems, environmental analysis, separations, spectroscopy, chemical reactions and selectivity, instrumentation, imaging, surface analysis, and data processing. Papers discussing known analytical methods should present a significant, original application of the method, a notable improvement, or results on an important analyte.