Your search keyword '"Waltemath D"' showing total 21 results

1. Specifications of standards in systems and synthetic biology: status, developments, and tools in 2024

Author

Golebiewski Martin, Bader Gary, Gleeson Padraig, Gorochowski Thomas E., Keating Sarah M., König Matthias, Myers Chris J., Nickerson David P., Sommer Björn, Waltemath Dagmar, and Schreiber Falk

Subjects

Biotechnology, TP248.13-248.65

Published

2024

2. The simulation experiment description markup language (SED-ML): language specification for level 1 version 5

Author

Smith Lucian P., Bergmann Frank T., Garny Alan, Helikar Tomáš, Karr Jonathan, Nickerson David, Sauro Herbert, Waltemath Dagmar, and König Matthias

Subjects

Biotechnology, TP248.13-248.65

Abstract

Modern biological research is increasingly informed by computational simulation experiments, which necessitate the development of methods for annotating, archiving, sharing, and reproducing the conducted experiments. These simulations increasingly require extensive collaboration among modelers, experimentalists, and engineers. The Minimum Information About a Simulation Experiment (MIASE) guidelines outline the information needed to share simulation experiments. SED-ML is a computer-readable format for the information outlined by MIASE, created as a community project and supported by many investigators and software tools. Level 1 Version 5 of SED-ML expands the ability of modelers to define simulations in SED-ML using the Kinetic Simulation Algorithm Onotoloy (KiSAO). While it was possible in Version 4 to define a simulation entirely using KiSAO, Version 5 now allows users to define tasks, model changes, ranges, and outputs using the ontology as well. SED-ML is supported by a growing ecosystem of investigators, model languages, and software tools, including various languages for constraint-based, kinetic, qualitative, rule-based, and spatial models, and many simulation tools, visual editors, model repositories, and validators. Additional information about SED-ML is available at https://sed-ml.org/.

Published

2024

3. Specifications of standards in systems and synthetic biology: status and developments in 2022 and the COMBINE meeting 2022

Author

König Matthias, Gleeson Padraig, Golebiewski Martin, Gorochowski Thomas E., Hucka Michael, Keating Sarah M., Myers Chris J., Nickerson David P., Sommer Björn, Waltemath Dagmar, and Schreiber Falk

Subjects

Biotechnology, TP248.13-248.65

Abstract

This special issue of the Journal of Integrative Bioinformatics contains updated specifications of COMBINE standards in systems and synthetic biology. The 2022 special issue presents three updates to the standards: CellML 2.0.1, SBML Level 3 Package: Spatial Processes, Version 1, Release 1, and Synthetic Biology Open Language (SBOL) Version 3.1.0. This document can also be used to identify the latest specifications for all COMBINE standards. In addition, this editorial provides a brief overview of the COMBINE 2022 meeting in Berlin.

Published

2023

4. Specifications of standards in systems and synthetic biology: status and developments in 2021

Author

Schreiber Falk, Gleeson Padraig, Golebiewski Martin, Gorochowski Thomas E., Hucka Michael, Keating Sarah M., König Matthias, Myers Chris J., Nickerson David P., Sommer Björn, and Waltemath Dagmar

Subjects

Biotechnology, TP248.13-248.65

Abstract

This special issue of the Journal of Integrative Bioinformatics contains updated specifications of COMBINE standards in systems and synthetic biology. The 2021 special issue presents four updates of standards: Synthetic Biology Open Language Visual Version 2.3, Synthetic Biology Open Language Visual Version 3.0, Simulation Experiment Description Markup Language Level 1 Version 4, and OMEX Metadata specification Version 1.2. This document can also be consulted to identify the latest specifications of all COMBINE standards.

Published

2021

5. Towards standardization guidelines for in silico approaches in personalized medicine

Author

Brunak Søren, Bjerre Collin Catherine, Eva Ó Cathaoir Katharina, Golebiewski Martin, Kirschner Marc, Kockum Ingrid, Moser Heike, and Waltemath Dagmar

Subjects

data integration, in silico modelling, personalized medicine, reproducibility, standards, Biotechnology, TP248.13-248.65

Abstract

Despite the ever-progressing technological advances in producing data in health and clinical research, the generation of new knowledge for medical benefits through advanced analytics still lags behind its full potential. Reasons for this obstacle are the inherent heterogeneity of data sources and the lack of broadly accepted standards. Further hurdles are associated with legal and ethical issues surrounding the use of personal/patient data across disciplines and borders. Consequently, there is a need for broadly applicable standards compliant with legal and ethical regulations that allow interpretation of heterogeneous health data through in silico methodologies to advance personalized medicine. To tackle these standardization challenges, the Horizon2020 Coordinating and Support Action EU-STANDS4PM initiated an EU-wide mapping process to evaluate strategies for data integration and data-driven in silico modelling approaches to develop standards, recommendations and guidelines for personalized medicine. A first step towards this goal is a broad stakeholder consultation process initiated by an EU-STANDS4PM workshop at the annual COMBINE meeting (COMBINE 2019 workshop report in same issue). This forum analysed the status quo of data and model standards and reflected on possibilities as well as challenges for cross-domain data integration to facilitate in silico modelling approaches for personalized medicine.

Published

2020

6. The first 10 years of the international coordination network for standards in systems and synthetic biology (COMBINE)

Author

Waltemath Dagmar, Golebiewski Martin, Blinov Michael L, Gleeson Padraig, Hermjakob Henning, Hucka Michael, Inau Esther Thea, Keating Sarah M, König Matthias, Krebs Olga, Malik-Sheriff Rahuman S, Nickerson David, Oberortner Ernst, Sauro Herbert M, Schreiber Falk, Smith Lucian, Stefan Melanie I, Wittig Ulrike, and Myers Chris J

Subjects

combine, community building, meeting report, standardization, Biotechnology, TP248.13-248.65

Abstract

This paper presents a report on outcomes of the 10th Computational Modeling in Biology Network (COMBINE) meeting that was held in Heidelberg, Germany, in July of 2019. The annual event brings together researchers, biocurators and software engineers to present recent results and discuss future work in the area of standards for systems and synthetic biology. The COMBINE initiative coordinates the development of various community standards and formats for computational models in the life sciences. Over the past 10 years, COMBINE has brought together standard communities that have further developed and harmonized their standards for better interoperability of models and data. COMBINE 2019 was co-located with a stakeholder workshop of the European EU-STANDS4PM initiative that aims at harmonized data and model standardization for in silico models in the field of personalized medicine, as well as with the FAIRDOM PALs meeting to discuss findable, accessible, interoperable and reusable (FAIR) data sharing. This report briefly describes the work discussed in invited and contributed talks as well as during breakout sessions. It also highlights recent advancements in data, model, and annotation standardization efforts. Finally, this report concludes with some challenges and opportunities that this community will face during the next 10 years.

Published

2020

7. Specifications of standards in systems and synthetic biology: status and developments in 2020

Author

Schreiber Falk, Sommer Björn, Czauderna Tobias, Golebiewski Martin, Gorochowski Thomas E., Hucka Michael, Keating Sarah M., König Matthias, Myers Chris, Nickerson David, and Waltemath Dagmar

Subjects

ontologies, standards, systems biology, synthetic biology, Biotechnology, TP248.13-248.65

Abstract

This special issue of the Journal of Integrative Bioinformatics presents papers related to the 10th COMBINE meeting together with the annual update of COMBINE standards in systems and synthetic biology.

Published

2020

8. The simulation experiment description markup language (SED-ML): language specification for level 1 version 4

Author

Smith Lucian P., Bergmann Frank T., Garny Alan, Helikar Tomáš, Karr Jonathan, Nickerson David, Sauro Herbert, Waltemath Dagmar, and König Matthias

Subjects

computational modeling, reproducibility, simulation experiment, Biotechnology, TP248.13-248.65

Abstract

Computational simulation experiments increasingly inform modern biological research, and bring with them the need to provide ways to annotate, archive, share and reproduce the experiments performed. These simulations increasingly require extensive collaboration among modelers, experimentalists, and engineers. The Minimum Information About a Simulation Experiment (MIASE) guidelines outline the information needed to share simulation experiments. SED-ML is a computer-readable format for the information outlined by MIASE, created as a community project and supported by many investigators and software tools. The first versions of SED-ML focused on deterministic and stochastic simulations of models. Level 1 Version 4 of SED-ML substantially expands these capabilities to cover additional types of models, model languages, parameter estimations, simulations and analyses of models, and analyses and visualizations of simulation results. To facilitate consistent practices across the community, Level 1 Version 4 also more clearly describes the use of SED-ML constructs, and includes numerous concrete validation rules. SED-ML is supported by a growing ecosystem of investigators, model languages, and software tools, including eight languages for constraint-based, kinetic, qualitative, rule-based, and spatial models, over 20 simulation tools, visual editors, model repositories, and validators. Additional information about SED-ML is available at https://sed-ml.org/.

Published

2021

9. OMEX metadata specification (version 1.2)

Author

Gennari John H., König Matthias, Misirli Goksel, Neal Maxwell L., Nickerson David P., and Waltemath Dagmar

Subjects

biosimulation modeling, combine standards, metadata, semantics, Biotechnology, TP248.13-248.65

Abstract

A standardized approach to annotating computational biomedical models and their associated files can facilitate model reuse and reproducibility among research groups, enhance search and retrieval of models and data, and enable semantic comparisons between models. Motivated by these potential benefits and guided by consensus across the COmputational Modeling in BIology NEtwork (COMBINE) community, we have developed a specification for encoding annotations in Open Modeling and EXchange (OMEX)-formatted archives. This document details version 1.2 of the specification, which builds on version 1.0 published last year in this journal. In particular, this version includes a set of initial model-level annotations (whereas v 1.0 described exclusively annotations at a smaller scale). Additionally, this version uses best practices for namespaces, and introduces omex-library.org as a common root for all annotations. Distributing modeling projects within an OMEX archive is a best practice established by COMBINE, and the OMEX metadata specification presented here provides a harmonized, community-driven approach for annotating a variety of standardized model representations. This specification acts as a technical guideline for developing software tools that can support this standard, and thereby encourages broad advances in model reuse, discovery, and semantic analyses.

Published

2021

10. Specifications of Standards in Systems and Synthetic Biology: Status and Developments in 2019

Author

Schreiber Falk, Sommer Björn, Bader Gary D., Gleeson Padraig, Golebiewski Martin, Hucka Michael, Keating Sarah M., König Matthias, Myers Chris, Nickerson David, and Waltemath Dagmar

Subjects

Biotechnology, TP248.13-248.65

Abstract

This special issue of the Journal of Integrative Bioinformatics presents an overview of COMBINE standards and their latest specifications. The standards cover representation formats for computational modeling in synthetic and systems biology and include BioPAX, CellML, NeuroML, SBML, SBGN, SBOL and SED-ML. The articles in this issue contain updated specifications of SBGN Process Description Level 1 Version 2, SBML Level 3 Core Version 2 Release 2, SBOL Version 2.3.0, and SBOL Visual Version 2.1.

Published

2019

11. Open modeling and exchange (OMEX) metadata specification version 1.0

Author

Neal Maxwell L., Gennari John H., Waltemath Dagmar, Nickerson David P., and König Matthias

Subjects

data integration, metadata, semantics, simulation, Biotechnology, TP248.13-248.65

Abstract

A standardized approach to annotating computational biomedical models and their associated files can facilitate model reuse and reproducibility among research groups, enhance search and retrieval of models and data, and enable semantic comparisons between models. Motivated by these potential benefits and guided by consensus across the COmputational Modeling in BIology NEtwork (COMBINE) community, we have developed a specification for encoding annotations in Open Modeling and EXchange (OMEX)-formatted archives. Distributing modeling projects within these archives is a best practice established by COMBINE, and the OMEX metadata specification presented here provides a harmonized, community-driven approach for annotating a variety of standardized model and data representation formats within an archive. The specification primarily includes technical guidelines for encoding archive metadata, so that software tools can more easily utilize and exchange it, thereby spurring broad advancements in model reuse, discovery, and semantic analyses.

Published

2020

12. Specifications of Standards in Systems and Synthetic Biology: Status and Developments in 2017

Author

Schreiber Falk, Bader Gary D., Gleeson Padraig, Golebiewski Martin, Hucka Michael, Keating Sarah M., Novère Nicolas Le, Myers Chris, Nickerson David, Sommer Björn, and Waltemath Dagmar

Subjects

combine, systems biology, synthetic biology, standards, Biotechnology, TP248.13-248.65

Abstract

Standards are essential to the advancement of Systems and Synthetic Biology. COMBINE provides a formal body and a centralised platform to help develop and disseminate relevant standards and related resources. The regular special issue of the Journal of Integrative Bioinformatics aims to support the exchange, distribution and archiving of these standards by providing unified, easily citable access. This paper provides an overview of existing COMBINE standards and presents developments of the last year.

Published

2018

13. The Systems Biology Markup Language (SBML): Language Specification for Level 3 Version 2 Core Release 2

Author

Hucka Michael, Bergmann Frank T., Chaouiya Claudine, Dräger Andreas, Hoops Stefan, Keating Sarah M., König Matthias, Novère Nicolas Le, Myers Chris J., Olivier Brett G., Sahle Sven, Schaff James C., Sheriff Rahuman, Smith Lucian P., Waltemath Dagmar, Wilkinson Darren J., and Zhang Fengkai

Subjects

systems biology markup language, standards, visualization, representation, Biotechnology, TP248.13-248.65

Abstract

Computational models can help researchers to interpret data, understand biological functions, and make quantitative predictions. The Systems Biology Markup Language (SBML) is a file format for representing computational models in a declarative form that different software systems can exchange. SBML is oriented towards describing biological processes of the sort common in research on a number of topics, including metabolic pathways, cell signaling pathways, and many others. By supporting SBML as an input/output format, different tools can all operate on an identical representation of a model, removing opportunities for translation errors and assuring a common starting point for analyses and simulations. This document provides the specification for Release 2 of Version 2 of SBML Level 3 Core. The specification defines the data structures prescribed by SBML as well as their encoding in XML, the eXtensible Markup Language. Release 2 corrects some errors and clarifies some ambiguities discovered in Release 1. This specification also defines validation rules that determine the validity of an SBML document, and provides many examples of models in SBML form. Other materials and software are available from the SBML project website at http://sbml.org/.

Published

2019

14. Specifications of Standards in Systems and Synthetic Biology: Status and Developments in 2016

Author

Schreiber Falk, Bader Gary D., Gleeson Padraig, Golebiewski Martin, Hucka Michael, Novère Nicolas Le, Myers Chris, Nickerson David, Sommer Björn, and Waltemath Dagmar

Subjects

Biotechnology, TP248.13-248.65

Abstract

Standards are essential to the advancement of science and technology. In systems and synthetic biology, numerous standards and associated tools have been developed over the last 16 years. This special issue of the Journal of Integrative Bioinformatics aims to support the exchange, distribution and archiving of these standards, as well as to provide centralised and easily citable access to them.

Published

2016

15. The Systems Biology Markup Language (SBML): Language Specification for Level 3 Version 1 Core

Author

Hucka Michael, Bergmann Frank T., Dräger Andreas, Hoops Stefan, Keating Sarah M., Le Novère Nicolas, Myers Chris J., Olivier Brett G., Sahle Sven, Schaff James C., Smith Lucian P., Waltemath Dagmar, and Wilkinson Darren J.

Subjects

sbml, modeling, standards, Biotechnology, TP248.13-248.65

Abstract

Computational models can help researchers to interpret data, understand biological functions, and make quantitative predictions. The Systems Biology Markup Language (SBML) is a file format for representing computational models in a declarative form that different software systems can exchange. SBML is oriented towards describing biological processes of the sort common in research on a number of topics, including metabolic pathways, cell signaling pathways, and many others. By supporting SBML as an input/output format, different tools can all operate on an identical representation of a model, removing opportunities for translation errors and assuring a common starting point for analyses and simulations. This document provides the specification for Release 2 of Version 1 of SBML Level 3 Core. The specification defines the data structures prescribed by SBML, their encoding in XML (the eXtensible Markup Language), validation rules that determine the validity of an SBML document, and examples of models in SBML form. No design changes have been made to the description of models between Release 1 and Release 2; changes are restricted to the format of annotations, the correction of errata and the addition of clarifications. Other materials and software are available from the SBML project website at http://sbml.org/.

Published

2018

16. Simulation Experiment Description Markup Language (SED-ML) Level 1 Version 3 (L1V3)

Author

Bergmann Frank T., Cooper Jonathan, König Matthias, Moraru Ion, Nickerson David, Le Novère Nicolas, Olivier Brett G., Sahle Sven, Smith Lucian, and Waltemath Dagmar

Subjects

simulation experiment, computational modeling, reproducibility, Biotechnology, TP248.13-248.65

Abstract

The creation of computational simulation experiments to inform modern biological research poses challenges to reproduce, annotate, archive, and share such experiments. Efforts such as SBML or CellML standardize the formal representation of computational models in various areas of biology. The Simulation Experiment Description Markup Language (SED-ML) describes what procedures the models are subjected to, and the details of those procedures. These standards, together with further COMBINE standards, describe models sufficiently well for the reproduction of simulation studies among users and software tools. The Simulation Experiment Description Markup Language (SED-ML) is an XML-based format that encodes, for a given simulation experiment, (i) which models to use; (ii) which modifications to apply to models before simulation; (iii) which simulation procedures to run on each model; (iv) how to post-process the data; and (v) how these results should be plotted and reported. SED-ML Level 1 Version 1 (L1V1) implemented support for the encoding of basic time course simulations. SED-ML L1V2 added support for more complex types of simulations, specifically repeated tasks and chained simulation procedures. SED-ML L1V3 extends L1V2 by means to describe which datasets and subsets thereof to use within a simulation experiment.

Published

2018

17. The Systems Biology Markup Language (SBML): Language Specification for Level 3 Version 2 Core

Author

Hucka Michael, Bergmann Frank T., Dräger Andreas, Hoops Stefan, Keating Sarah M., Le Novère Nicolas, Myers Chris J., Olivier Brett G., Sahle Sven, Schaff James C., Smith Lucian P., Waltemath Dagmar, and Wilkinson Darren J.

Subjects

sbml, modeling, computational biology, systems biology, standards, Biotechnology, TP248.13-248.65

Abstract

Computational models can help researchers to interpret data, understand biological functions, and make quantitative predictions. The Systems Biology Markup Language (SBML) is a file format for representing computational models in a declarative form that different software systems can exchange. SBML is oriented towards describing biological processes of the sort common in research on a number of topics, including metabolic pathways, cell signaling pathways, and many others. By supporting SBML as an input/output format, different tools can all operate on an identical representation of a model, removing opportunities for translation errors and assuring a common starting point for analyses and simulations. This document provides the specification for Version 2 of SBML Level 3 Core. The specification defines the data structures prescribed by SBML, their encoding in XML (the eXtensible Markup Language), validation rules that determine the validity of an SBML document, and examples of models in SBML form. The design of Version 2 differs from Version 1 principally in allowing new MathML constructs, making more child elements optional, and adding identifiers to all SBML elements instead of only selected elements. Other materials and software are available from the SBML project website at http://sbml.org/.

Published

2018

18. Systems Biology Markup Language (SBML) Level 2 Version 5: Structures and Facilities for Model Definitions

Author

Hucka Michael, Bergmann Frank T., Dräger Andreas, Hoops Stefan, Keating Sarah M., Le Novère Nicolas, Myers Chris J., Olivier Brett G., Sahle Sven, Schaff James C., Smith Lucian P., Waltemath Dagmar, and Wilkinson Darren J.

Subjects

Biotechnology, TP248.13-248.65

Abstract

Computational models can help researchers to interpret data, understand biological function, and make quantitative predictions. The Systems Biology Markup Language (SBML) is a file format for representing computational models in a declarative form that can be exchanged between different software systems. SBML is oriented towards describing biological processes of the sort common in research on a number of topics, including metabolic pathways, cell signaling pathways, and many others. By supporting SBML as an input/output format, different tools can all operate on an identical representation of a model, removing opportunities for translation errors and assuring a common starting point for analyses and simulations. This document provides the specification for Version 5 of SBML Level 2. The specification defines the data structures prescribed by SBML as well as their encoding in XML, the eXtensible Markup Language. This specification also defines validation rules that determine the validity of an SBML document, and provides many examples of models in SBML form. Other materials and software are available from the SBML project web site, http://sbml.org/.

Published

2015

19. Simulation Experiment Description Markup Language (SED-ML) Level 1 Version 2

Author

Bergmann Frank T., Cooper Jonathan, Le Novère Nicolas, Nickerson David, and Waltemath Dagmar

Subjects

Biotechnology, TP248.13-248.65

Abstract

The number, size and complexity of computational models of biological systems are growing at an ever increasing pace. It is imperative to build on existing studies by reusing and adapting existing models and parts thereof. The description of the structure of models is not sufficient to enable the reproduction of simulation results. One also needs to describe the procedures the models are subjected to, as recommended by the Minimum Information About a Simulation Experiment (MIASE) guidelines.

Published

2015

20. Specifications of Standards in Systems and Synthetic Biology

Author

Schreiber Falk, Bader Gary D., Golebiewski Martin, Hucka Michael, Kormeier Benjamin, Le Novère Nicolas, Myers Chris, Nickerson David, Sommer Björn, Waltemath Dagmar, and Weise Stephan

Subjects

Biotechnology, TP248.13-248.65

Abstract

Standards shape our everyday life. From nuts and bolts to electronic devices and technological processes, standardised products and processes are all around us. Standards have technological and economic benefits, such as making information exchange, production, and services more efficient. However, novel, innovative areas often either lack proper standards, or documents about standards in these areas are not available from a centralised platform or formal body (such as the International Standardisation Organisation).

Published

2015

21. Ranked retrieval of Computational Biology models

Author

Henkel Ron, Endler Lukas, Peters Andre, Le Novère Nicolas, and Waltemath Dagmar

Subjects

Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background The study of biological systems demands computational support. If targeting a biological problem, the reuse of existing computational models can save time and effort. Deciding for potentially suitable models, however, becomes more challenging with the increasing number of computational models available, and even more when considering the models' growing complexity. Firstly, among a set of potential model candidates it is difficult to decide for the model that best suits ones needs. Secondly, it is hard to grasp the nature of an unknown model listed in a search result set, and to judge how well it fits for the particular problem one has in mind. Results Here we present an improved search approach for computational models of biological processes. It is based on existing retrieval and ranking methods from Information Retrieval. The approach incorporates annotations suggested by MIRIAM, and additional meta-information. It is now part of the search engine of BioModels Database, a standard repository for computational models. Conclusions The introduced concept and implementation are, to our knowledge, the first application of Information Retrieval techniques on model search in Computational Systems Biology. Using the example of BioModels Database, it was shown that the approach is feasible and extends the current possibilities to search for relevant models. The advantages of our system over existing solutions are that we incorporate a rich set of meta-information, and that we provide the user with a relevance ranking of the models found for a query. Better search capabilities in model databases are expected to have a positive effect on the reuse of existing models.

Published

2010