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author | eslerm |
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date | Wed, 02 May 2018 18:31:06 -0400 |
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# VKMZ version 1.0 VKMZ is a metabolomics vizualization tool which creates van Krevelen diagrams from mass spectrometry data. A van Krevelen diagram (VKD) plots a molecule on a scatterplot based on the molecule's oxygen to carbon ratio (O:C) against it's hydrogen to carbon ratio (H:C). Classes of metabolites cluster together on a VKD [0]. Plotting a complex mixture of metabolites on a VKD can be used to briefly convey untargeted metabolomics data. VKMZ can be used as a standalone tool or on the Galaxy Project web platform [1]. ## Using VKMZ VKMZ is designed to use XCMS [2] data as input. Tabular data can also be used as input. For each feature in the data VKMZ attempts to predict it's molecular formula by comparing the features mass to a database of known formula masses. Heristically generated databases for unlabeled and labeled data is included with VKMZ. Users can define their own database. A VKD is created from formulas with predictions and outputed as a webpage and tabular file. ### Input modes VKMZ has three modes: 1. `tsv` mode reads a specially formatted tabular file 2. `xcms` mode reads features in [XCMS](https://bioconductor.org/packages/release/bioc/html/xcms.html) data 3. `plot` mode replots VKMZ tabular data Select a mode by declaring it as the first argument to `vkmz.py`. > **Example:** > ``` > python vkmz.py xcms [options] > ``` Different modes take different parameters. All modes require an output parameter: * `--output [FILENAME]` * A `.tsv` and/or `.html` will be generated by VKMZ with this paraameter as the file name. * A `.tsv` and `.html` files generated by VKMZ are named by this option All modes allow these options: * `--plot-type [scatter-2d]` * `--size [INTEGER]` * Set base size of marker dots of the VKD * `--size-algorithm [{1,2}]` * Choose algorithm to modify marker size 1. Uniform base size 2. Intensity relative size #### xcms and tsv modes Both xcms and tsv mode require the mass error, in parts-per-million, of the mass spectrometer which generated the data: * `--error [PPM_ERROR_NUMBER]` There are several options for xcms and tsv modes: * `--database [DATABASE_FILE]` * default is BMRB's monoisotopic heuristically generated database [3] * `--directory [TOOL_PATH]` * define tool directory * `--no-plot` * disable html plot generation #### xcms mode xcms mode requires tabular files generated by XCMS: * `--data-matrix [XCMS_DATA_MATRIX_FILE]` * `--sample-metadata [XCMS_SAMPLE_METADATAFILE]` * `--variable-metadata [XCMS_VARIABLE_METADATAFILE]` ##### xcms mode example: ``` python vkmz.py xcms --data-matrix test-data/datamatrix.tabular --sample-metadata test-data/sampleMetadata.tabular --variable-metadata test-data/variableMetadata.tabular --output report --error 3 ``` #### tsv mode tsv mode requires a tabular file of a specific format as input. * `--input [TSV FILE]` The first five columns of the input tabular file must be: | sample ID | polarity | mz | retention time | intensity | |-----------|----------|----|----------------|-----------| #### plot mode plot mode reads previously generated VKMZ tabular files to create VKD html files. Specifying the VKMZ tabular file is required: * `--input [VKMZ_TSV_FILE]` ## Citations 0. Brockman et al. [doi:10.1007/s11306-018-1343-y](https://doi.org/10.1007/s11306-018-1343-y) 1. Galaxy Project [Galaxy](https://github.com/galaxyproject/galaxy) 2. Giacomoni et al. [doi:10.1093/bioinformatics/btu813](https://doi.org/10.1093/bioinformatics/btu813) 3. Hegeman et al. [doi:10.1021/ac070346t](https://doi.org/10.1021/ac070346t)