Perspectives on Automated Composition of Workflows in the Life Sciences

Overview

Journal F1000Res

Specialties Biomedical Engineering
Science

Date 2021 Nov 22

PMID 34804501

Citations 3

Authors

Anna-Lena Lamprecht

Magnus Palmblad

Jon Ison

Veit Schwammle

Mohammad Sadnan Al Manir

Ilkay Altintas

Christopher J O Baker

Ammar Ben Hadj Amor

Salvador Capella-Gutierrez

Paulos Charonyktakis

Michael R Crusoe

Yolanda Gil

Carole Goble

Timothy J Griffin

Paul Groth

Hans Ienasescu

Pratik Jagtap

Matus Kalas

Vedran Kasalica

Alireza Khanteymoori

Tobias Kuhn

Hailiang Mei

Herve Menager

Steffen Moller

Robin A Richardson

Vincent Robert

Stian Soiland-Reyes

Robert Stevens

Szoke Szaniszlo

Suzan Verberne

Aswin Verhoeven

Katherine Wolstencroft

Affiliations

Soon will be listed here.

Abstract

Scientific data analyses often combine several computational tools in automated pipelines, or workflows. Thousands of such workflows have been used in the life sciences, though their composition has remained a cumbersome manual process due to a lack of standards for annotation, assembly, and implementation. Recent technological advances have returned the long-standing vision of automated workflow composition into focus. This article summarizes a recent Lorentz Center workshop dedicated to automated composition of workflows in the life sciences. We survey previous initiatives to automate the composition process, and discuss the current state of the art and future perspectives. We start by drawing the "big picture" of the scientific workflow development life cycle, before surveying and discussing current methods, technologies and practices for semantic domain modelling, automation in workflow development, and workflow assessment. Finally, we derive a roadmap of individual and community-based actions to work toward the vision of automated workflow development in the forthcoming years. A central outcome of the workshop is a general description of the workflow life cycle in six stages: 1) scientific question or hypothesis, 2) conceptual workflow, 3) abstract workflow, 4) concrete workflow, 5) production workflow, and 6) scientific results. The transitions between stages are facilitated by diverse tools and methods, usually incorporating domain knowledge in some form. Formal semantic domain modelling is hard and often a bottleneck for the application of semantic technologies. However, life science communities have made considerable progress here in recent years and are continuously improving, renewing interest in the application of semantic technologies for workflow exploration, composition and instantiation. Combined with systematic benchmarking with reference data and large-scale deployment of production-stage workflows, such technologies enable a more systematic process of workflow development than we know today. We believe that this can lead to more robust, reusable, and sustainable workflows in the future.

Citing Articles

Applying the FAIR Principles to computational workflows.

Wilkinson S, Aloqalaa M, Belhajjame K, Crusoe M, de Paula Kinoshita B, Gadelha L Sci Data. 2025; 12(1):328.

PMID: 39994238 PMC: 11850811. DOI: 10.1038/s41597-025-04451-9.

Evaluating FAIR Digital Object and Linked Data as distributed object systems.

Soiland-Reyes S, Goble C, Groth P PeerJ Comput Sci. 2024; 10:e1781.

PMID: 38855229 PMC: 11157569. DOI: 10.7717/peerj-cs.1781.

Towards Machine-FAIR: Representing software and datasets to facilitate reuse and scientific discovery by machines.

Wagner M, Hogan W, Levander J, Diller M J Biomed Inform. 2024; 154:104647.

PMID: 38692465 PMC: 11250896. DOI: 10.1016/j.jbi.2024.104647.

A Checklist for Reproducible Computational Analysis in Clinical Metabolomics Research.

Du X, Aristizabal-Henao J, Garrett T, Brochhausen M, Hogan W, Lemas D Metabolites. 2022; 12(1).

PMID: 35050209 PMC: 8779534. DOI: 10.3390/metabo12010087.

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