MetGem Software for the Generation of Molecular Networks Based on the t-SNE Algorithm.
Florent OlivonNicolas ElieGwendal GrelierFanny RoussiMarc LitaudonDavid TouboulPublished in: Analytical chemistry (2018)
Molecular networking (MN) is becoming a standard bioinformatics tool in the metabolomic community. Its paradigm is based on the observation that compounds with a high degree of chemical similarity share comparable MS2 fragmentation pathways. To afford a clear separation between MS2 spectral clusters, only the most relevant similarity scores are selected using dedicated filtering steps requiring time-consuming parameter optimization. Depending on the filtering values selected, some scores are arbitrarily deleted and a part of the information is ignored. The problem of creating a reliable representation of MS2 spectra data sets can be solved using algorithms developed for dimensionality reduction and pattern recognition purposes, such as t-distributed stochastic neighbor embedding (t-SNE). This multivariate embedding method pays particular attention to local details by using nonlinear outputs to represent the entire data space. To overcome the limitations inherent to the GNPS workflow and the networking architecture, we developed MetGem. Our software allows the parallel investigation of two complementary representations of the raw data set, one based on a classic GNPS-style MN and another based on the t-SNE algorithm. The t-SNE graph preserves the interactions between related groups of spectra, while the MN output allows an unambiguous separation of clusters. Additionally, almost all parameters can be tuned in real time, and new networks can be generated within a few seconds for small data sets. With the development of this unified interface ( https://metgem.github.io ), we fulfilled the need for a dedicated, user-friendly, local software for MS2 comparison and spectral network generation.
Keyphrases
- electronic health record
- mass spectrometry
- data analysis
- multiple sclerosis
- machine learning
- ms ms
- big data
- deep learning
- liquid chromatography
- neural network
- healthcare
- optical coherence tomography
- working memory
- mental health
- room temperature
- artificial intelligence
- computed tomography
- density functional theory
- magnetic resonance
- transition metal
- health information
- single molecule
- dual energy