BACKGROUND: Scientific workflows improve the process of scientific experiments by making computations explicit, underscoring data flow, and emphasizing the participation of humans in the process when intuition and human reasoning are required. Workflows for experiments also highlight transitions among experimental phases, allowing intermediate results to be verified and supporting the proper handling of semantic mismatches and different file formats among the various tools used in the scientific process. Thus, scientific workflows are important for the modeling and subsequent capture of bioinformatics-related data. While much research has been conducted on the implementation of scientific workflows, the initial process of actually designing and generating the workflow at the conceptual level has received little consideration. RESULTS: We propose a structured process to capture scientific workflows at the conceptual level that allows workflows to be documented efficiently, results in concise models of the workflow and more-correct workflow implementations, and provides insight into the scientific process itself. The approach uses three modeling techniques to model the structural, data flow, and control flow aspects of the workflow. The domain of biomolecular structure determination using Nuclear Magnetic Resonance spectroscopy is used to demonstrate the process. Specifically, we show the application of the approach to capture the workflow for the process of conducting biomolecular analysis using Nuclear Magnetic Resonance (NMR) spectroscopy. CONCLUSION: Using the approach, we were able to accurately document, in a short amount of time, numerous steps in the process of conducting an experiment using NMR spectroscopy. The resulting models are correct and precise, as outside validation of the models identified only minor omissions in the models. In addition, the models provide an accurate visual description of the control flow for conducting biomolecular analysis using NMR spectroscopy experiment

Ellis, Heidi JC

Gryk, Michael R

Verdi, Kacy K

English

PubMed

Abstract Background Scientific workflows improve the process of scientific experiments by making computations explicit, underscoring data flow, and emphasizing the participation of humans in the process when intuition and human reasoning are required. Workflows for experiments also highlight transitions among experimental phases, allowing intermediate results to be verified and supporting the proper handling of semantic mismatches and different file formats among the various tools used in the scientific process. Thus, scientific workflows are important for the modeling and subsequent capture of bioinformatics-related data. While much research has been conducted on the implementation of scientific workflows, the initial process of actually designing and generating the workflow at the conceptual level has received little consideration. Results We propose a structured process to capture scientific workflows at the conceptual level that allows workflows to be documented efficiently, results in concise models of the workflow and more-correct workflow implementations, and provides insight into the scientific process itself. The approach uses three modeling techniques to model the structural, data flow, and control flow aspects of the workflow. The domain of biomolecular structure determination using Nuclear Magnetic Resonance spectroscopy is used to demonstrate the process. Specifically, we show the application of the approach to capture the workflow for the process of conducting biomolecular analysis using Nuclear Magnetic Resonance (NMR) spectroscopy. Conclusion Using the approach, we were able to accurately document, in a short amount of time, numerous steps in the process of conducting an experiment using NMR spectroscopy. The resulting models are correct and precise, as outside validation of the models identified only minor omissions in the models. In addition, the models provide an accurate visual description of the control flow for conducting biomolecular analysis using NMR spectroscopy experiment.</p

Gryk Michael R

Ellis Heidi JC

Verdi Kacy K

Directory of Open Access Journals

BMC Bioinformatics

Conceptual-level workflow modeling of scientific experiments using NMR as a case study

Kacy K Verdi

Heidi JC Ellis

Michael R Gryk

Springer - Publisher Connector

A Notation and System for Expressing and Executing Cleanly Typed Workflows on Messy Scientific Data. SIGMOD Record

A: Designing and executing scientific workflows with a programmable integrator. Bioinformatics

A: NMRPipe: a multidimensional spectral processing system based on UNIX pipes.

A: Visual Grid Workflow in Triana.

Altman RB: Modeling and analyzing biomedical processes using Work-flow/Petri Net models and tools.

Altman RB: Using Petri Net Tools to Study Properties and Dynamics of Biological Systems.

Bacarin E: WOODSS and the Web: Annotating and Reusing Scientific Workflows. SIGMOD Record

Continuous Process Improvement San Franciso: Jossey-Bass/ Pfeiffer;

Delineation and Analysis of the Conceptual Data Model Implied by the IUPAC Recommendations for Biochemical Nomenclature. Protein Science

Gracio D: Participatory Workflow Analysis: Unveiling Scientific Research Processes with Scientists.

Gryk MR: Development of an Integrated Framework for Protein Structure Determinations: A Logical Data Model for NMR Data Analysis.

Honavar VG: Ontology-Extended Component-Based Workflows: A Framework for Constructing Complex Workflows from Semantically Heterogeneous Software Components.

HV: Supporting modeling and problem solving from precedent experiences: the role of workflows and case-based reasoning. Environmental Modeling & Software

Incorporating Semantics in Scientific Workflow Authoring.

Integrating databases and workflow systems.

Kepler: An Extensible System for Design and Execution of Scientific Workflows.

LL: The Unified Process Inception Phase: Best Practices for Completing the Unified Process Lawrence:

Ludäscher B: Actor-Oriented Design of Scientific Work-flows.

Ludäscher B: An Ontology-Driven Framework for Data Transformation in Scientific Workflows.

Mapping Work Processes ASQ

Scientific Workflow Management and the Kepler System. Concurrency and Computation: Practice & Experience

Semantics and Verification of Data Flow

Software Requirements Second edition.

Taverna: A tool for the composition and enactment of bioinformatics workflows. Bioinformatics

ter Hofstede AHM, Russell N: Pattern-based Analysis of UML Activity Diagrams.

The Workflow Reference Model: 10 Years On, The Workflow Handbook

Triana Applications within Grid Computing and Peer to Peer Environments.

Villazon A: A-GWL: Abstract Grid Workflow Language.

Wang I: Programming scientific and distributed workflow with Triana services. Concurrency and Computation: Practice and Experience

WOODSS – a spatial decision support system based on workflows. Decision Support Systems

Workflows in bioinformatics: meta-analysis and prototype implementation of a workflow generator.

Wroe C: Taverna: lessons in creating a workflow environment for the life sciences. Concurrency and Computation: Practice and Experience

file:///data/remote/core/dit/data/Springer-OA/pdf/841/aHR0cDovL2xpbmsuc3ByaW5nZXIuY29tLzEwLjExODYvMTQ3MS0yMTA1LTgtMzEucGRm.pdf

Conceptual-level workflow modeling of scientific experiments using NMR as a case study

Abstract

Similar works

Full text

Available Versions

Directory of Open Access Journals

Springer - Publisher Connector

Springer - Publisher Connector