MassSpecGym:发现和识别分子的基准。

ArXiv Pub Date : 2024-10-30
Roman Bushuiev, Anton Bushuiev, Niek F de Jonge, Adamo Young, Fleming Kretschmer, Raman Samusevich, Janne Heirman, Fei Wang, Luke Zhang, Kai Dührkop, Marcus Ludwig, Nils A Haupt, Apurva Kalia, Corinna Brungs, Robin Schmid, Russell Greiner, Bo Wang, David S Wishart, Li-Ping Liu, Juho Rousu, Wout Bittremieux, Hannes Rost, Tytus D Mak, Soha Hassoun, Florian Huber, Justin J J van der Hooft, Michael A Stravs, Sebastian Böcker, Josef Sivic, Tomáš Pluskal
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引用次数: 0

摘要

发现和鉴定生物与环境样本中的分子对于推动生物医学和化学科学的发展至关重要。串联质谱(MS/MS)是高通量阐明分子结构的领先技术。然而,从质谱中解码分子结构是一项极具挑战性的工作,即使由人类专家来完成也是如此。因此,绝大多数获得的 MS/MS 图谱仍然无法解读,从而限制了我们对潜在(生物)化学过程的了解。尽管从 MS/MS 图谱预测分子结构的机器学习应用取得了几十年的进展,但由于缺乏标准数据集和评估协议,新方法的开发受到严重阻碍。为了解决这个问题,我们提出了 MassSpecGym -- 第一个从 MS/MS 数据中发现和识别分子的综合基准。我们的基准包括最大的公开高质量标记 MS/MS 图谱集,并定义了三个 MS/MS 注释挑战:\文本{de novo}分子结构生成、分子检索和光谱模拟。它包括新的评估指标和泛化需求的数据拆分,从而实现了 MS/MS 注释任务的标准化,并使广泛的机器学习社区能够解决这一问题。MassSpecGym 在 \url{https://github.com/pluskal-lab/MassSpecGym} 上公开发布。
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MassSpecGym: A benchmark for the discovery and identification of molecules.

The discovery and identification of molecules in biological and environmental samples is crucial for advancing biomedical and chemical sciences. Tandem mass spectrometry (MS/MS) is the leading technique for high-throughput elucidation of molecular structures. However, decoding a molecular structure from its mass spectrum is exceptionally challenging, even when performed by human experts. As a result, the vast majority of acquired MS/MS spectra remain uninterpreted, thereby limiting our understanding of the underlying (bio)chemical processes. Despite decades of progress in machine learning applications for predicting molecular structures from MS/MS spectra, the development of new methods is severely hindered by the lack of standard datasets and evaluation protocols. To address this problem, we propose MassSpecGym -- the first comprehensive benchmark for the discovery and identification of molecules from MS/MS data. Our benchmark comprises the largest publicly available collection of high-quality labeled MS/MS spectra and defines three MS/MS annotation challenges: \textit{de novo} molecular structure generation, molecule retrieval, and spectrum simulation. It includes new evaluation metrics and a generalization-demanding data split, therefore standardizing the MS/MS annotation tasks and rendering the problem accessible to the broad machine learning community. MassSpecGym is publicly available at \url{https://github.com/pluskal-lab/MassSpecGym}.

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