JESTR: Joint Embedding Space Technique for Ranking Candidate Molecules for the Annotation of Untargeted Metabolomics Data.

ArXiv Pub Date : 2024-11-25
Apurva Kalia, Dilip Krishnan, Soha Hassoun
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Abstract

Motivation: A major challenge in metabolomics is annotation: assigning molecular structures to mass spectral fragmentation patterns. Despite recent advances in molecule-to-spectra and in spectra-to-molecular fingerprint prediction (FP), annotation rates remain low.

Results: We introduce in this paper a novel paradigm (JESTR) for annotation. Unlike prior approaches that explicitly construct molecular fingerprints or spectra, JESTR leverages the insight that molecules and their corresponding spectra are views of the same data and effectively embeds their representations in a joint space. Candidate structures are ranked based on cosine similarity between the embeddings of query spectrum and each candidate. We evaluate JESTR against mol-to-spec and spec-to-FP annotation tools on three datasets. On average, for rank@[1-5], JESTR outperforms other tools by 23.6% - 71.6%. We further demonstrate the strong value of regularization with candidate molecules during training, boosting rank@1 performance by 11.4% and enhancing the model's ability to discern between target and candidate molecules. Through JESTR, we offer a novel promising avenue towards accurate annotation, therefore unlocking valuable insights into the metabolome.

Availability: Code and dataset available at https://github.com/HassounLab/JESTR1/.

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JESTR:为非目标代谢组学数据注释候选分子排序的联合嵌入空间技术。
动机代谢组学的一大挑战是标注:为质谱碎片模式分配分子结构。尽管最近在分子到光谱和光谱到分子指纹预测(FP)方面取得了进展,但注释率仍然很低:我们在本文中介绍了一种新的注释范式(JESTR)。与之前明确构建分子指纹或光谱的方法不同,JESTR 充分利用了分子及其相应光谱是同一数据的视图这一观点,并有效地将它们嵌入到一个联合空间中。候选结构根据查询光谱和每个候选结构的嵌入之间的余弦相似度进行排序。我们在三个数据集上对 JESTR 与 mol-to-spec 和 spec-toFP 注释工具进行了评估。平均而言,对于 rank@[1-5],JESTR 优于其他工具 23.6%-71.6%。我们进一步证明了在训练过程中对候选分子进行正则化的强大价值,将 rank@1 的性能提高了 11.4%,并增强了模型辨别目标分子和候选分子的能力。通过 JESTR,我们为实现精确注释提供了一种新的有前途的途径,从而开启了对代谢组的宝贵洞察。
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