Your search keyword '"Muth, Thilo"' showing total 7 results

1. Machine learning-assisted equivalent circuit identification for dielectric spectroscopy of polymers

Author

Albakri, Bashar, Diniz, Analice Turski Silva, Benner, Philipp, Muth, Thilo, Nakajima, Shinichi, Favaro, Marco, and Kister, Alexander

Published

2024

2. Machine learning methods for compound annotation in non‐targeted mass spectrometry—A brief overview of fingerprinting, in silico fragmentation and de novo methods.

Author

Russo, Francesco F., Nowatzky, Yannek, Jaeger, Carsten, Parr, Maria K., Benner, Phillipp, Muth, Thilo, and Lisec, Jan

Subjects

MACHINE learning, RESEARCH personnel, MASS spectrometry, ENVIRONMENTAL sciences, DATA analysis

Abstract

Non‐targeted screenings (NTS) are essential tools in different fields, such as forensics, health and environmental sciences. NTSs often employ mass spectrometry (MS) methods due to their high throughput and sensitivity in comparison to, for example, nuclear magnetic resonance–based methods. As the identification of mass spectral signals, called annotation, is labour intensive, it has been used for developing supporting tools based on machine learning (ML). However, both the diversity of mass spectral signals and the sheer quantity of different ML tools developed for compound annotation present a challenge for researchers in maintaining a comprehensive overview of the field. In this work, we illustrate which ML‐based methods are available for compound annotation in non‐targeted MS experiments and provide a nuanced comparison of the ML models used in MS data analysis, unravelling their unique features and performance metrics. Through this overview we support researchers to judiciously apply these tools in their daily research. This review also offers a detailed exploration of methods and datasets to show gaps in current methods, and promising target areas, offering a starting point for developers intending to improve existing methodologies. [ABSTRACT FROM AUTHOR]

Published

2024

3. The Peptonizer2000: graphical model based taxonomic identifications of metaprotoemic samples

Author

Holstein, Tanja, primary, Verschaffelt, Pieter, additional, Van den Bossche, Tim, additional, Martens, Lennart, additional, and Muth, Thilo, additional

Published

2024

4. Fiora: Local neighborhood-based prediction of compound mass spectra from single fragmentation events

Author

Nowatzky, Yannek, primary, Russo, Francesco, additional, Lisec, Jan, additional, Kister, Alexander, additional, Reinert, Knut, additional, Muth, Thilo, additional, and Benner, Philipp, additional

Published

2024

5. MPA Portable: A Stand-Alone Software Package for Analyzing Metaproteome Samples on the Go

Author

Muth, Thilo, Kohrs, Fabian, Heyer, Robert, Benndorf, Dirk, Rapp, Erdmann, Reichl, Udo, Martens, Lennart, and Renard, Bernhard Y.

Abstract

Metaproteomics, the mass spectrometry-based analysis of proteins from multispecies samples faces severe challenges concerning data analysis and results interpretation. To overcome these shortcomings, we here introduce the MetaProteomeAnalyzer (MPA) Portable software. In contrast to the original server-based MPA application, this newly developed tool no longer requires computational expertise for installation and is now independent of any relational database system. In addition, MPA Portable now supports state-of-the-art database search engines and a convenient command line interface for high-performance data processing tasks. While search engine results can easily be combined to increase the protein identification yield, an additional two-step workflow is implemented to provide sufficient analysis resolution for further postprocessing steps, such as protein grouping as well as taxonomic and functional annotation. Our new application has been developed with a focus on intuitive usability, adherence to data standards, and adaptation to Web-based workflow platforms. The open source software package can be found at https://github.com/compomics/meta-proteome-analyzer.

Published

2024

6. gNOMO2: a comprehensive and modular pipeline for integrated multi-omics analyses of microbiomes.

Author

Arikan M and Muth T

Subjects

Humans, Metagenome, Multiomics, Microbiota, Metagenomics methods, RNA, Ribosomal, 16S genetics, Software, Computational Biology methods, Proteomics methods

Abstract

Background: In recent years, omics technologies have offered an exceptional chance to gain a deeper insight into the structural and functional characteristics of microbial communities. As a result, there is a growing demand for user-friendly, reproducible, and versatile bioinformatic tools that can effectively harness multi-omics data to provide a holistic understanding of microbiomes. Previously, we introduced gNOMO, a bioinformatic pipeline tailored to analyze microbiome multi-omics data in an integrative manner. In response to the evolving demands within the microbiome field and the growing necessity for integrated multi-omics data analysis, we have implemented substantial enhancements to the gNOMO pipeline., Results: Here, we present gNOMO2, a comprehensive and modular pipeline that can seamlessly manage various omics combinations, ranging from 2 to 4 distinct omics data types, including 16S ribosomal RNA (rRNA) gene amplicon sequencing, metagenomics, metatranscriptomics, and metaproteomics. Furthermore, gNOMO2 features a specialized module for processing 16S rRNA gene amplicon sequencing data to create a protein database suitable for metaproteomics investigations. Moreover, it incorporates new differential abundance, integration, and visualization approaches, enhancing the toolkit for a more insightful analysis of microbiomes. The functionality of these new features is showcased through the use of 4 microbiome multi-omics datasets encompassing various ecosystems and omics combinations. gNOMO2 not only replicated most of the primary findings from these studies but also offered further valuable perspectives., Conclusions: gNOMO2 enables the thorough integration of taxonomic and functional analyses in microbiome multi-omics data, offering novel insights in both host-associated and free-living microbiome research. gNOMO2 is available freely at https://github.com/muzafferarikan/gNOMO2., (© The Author(s) 2024. Published by Oxford University Press GigaScience.)

Published

2024

7. Bioinformatic Workflows for Metaproteomics.

Author

Holstein T and Muth T

Subjects

Humans, Databases, Protein, Metagenomics methods, Proteomics methods, Computational Biology methods, Workflow, Software, Microbiota genetics

Abstract

The strong influence of microbiomes on areas such as ecology and human health has become widely recognized in the past years. Accordingly, various techniques for the investigation of the composition and function of microbial community samples have been developed. Metaproteomics, the comprehensive analysis of the proteins from microbial communities, allows for the investigation of not only the taxonomy but also the functional and quantitative composition of microbiome samples. Due to the complexity of the investigated communities, methods developed for single organism proteomics cannot be readily applied to metaproteomic samples. For this purpose, methods specifically tailored to metaproteomics are required. In this work, a detailed overview of current bioinformatic solutions and protocols in metaproteomics is given. After an introduction to the proteomic database search, the metaproteomic post-processing steps are explained in detail. Ten specific bioinformatic software solutions are focused on, covering various steps including database-driven identification and quantification as well as taxonomic and functional assignment., (© 2024. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024