Ion-Ion Chemistry for the Analysis of Biomolecular Ions via Tandem Mass Spectrometry: A Tutorial Review.

IF 7.5

Annual review of analytical chemistry (Palo Alto, Calif.) Pub Date : 2026-02-24 DOI:10.1146/annurev-anchem-082824-031923

Seth A Horn, Nicholas R Ellin, Scott A McLuckey

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Abstract

Gas-phase ion-ion reactions lead to well-defined changes in mass and charge that are readily detected via mass spectrometry. They have unusually large cross sections, which allow for rates on the order of 1-1,000 s-1 and, as a result, enable a variety of analytically useful measurements. Such applications rely on one or more of a variety of reaction mechanisms, such as proton transfer, electron transfer, metal ion transfer, and selective covalent bond formation. Electrodynamic ion traps make excellent reaction vessels for ion-ion reactions due to their ability to trap one or both polarities of ions, thereby allowing reactions to proceed with high reactant to product conversion. Understanding the underlying phenomena of ion-ion reactions, as well as the conditions under which they proceed, is essential to designing future experiments. This tutorial review summarizes the underlying phenomena of gas-phase ion-ion reactions and related practical considerations needed to optimize these reactions in an electrodynamic ion trap.

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离子-离子化学在串联质谱分析生物分子离子中的应用综述。

气相离子-离子反应导致质量和电荷的明确变化，这些变化很容易通过质谱法检测到。它们具有非常大的横截面，允许1-1,000 s-1的速率，因此可以进行各种有用的分析测量。这类应用依赖于一种或多种反应机制，如质子转移、电子转移、金属离子转移和选择性共价键形成。电动离子阱是离子-离子反应的优良反应容器，因为它们能够捕获离子的一个或两个极性，从而允许反应以高反应物到产物的转化进行。了解离子-离子反应的潜在现象，以及它们进行的条件，对于设计未来的实验至关重要。本教程综述了气相离子-离子反应的基本现象，以及在电动力离子阱中优化这些反应所需的相关实际考虑。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Annual review of analytical chemistry (Palo Alto, Calif.)

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