Systems medicine disease maps: community-driven comprehensive representation of disease mechanisms

Mazein, Alexander; Ostaszewski, Marek; Kuperstein, Inna; Watterson, Steven; Novère, Nicolas Le; Lefaudeux, Diane; Meulder, Bertrand De; Pellet, Johann; Balaur, Irina; Saqi, Mansoor; Nogueira, Maria Manuela; He, Feng; Parton, Andrew; Lemonnier, Nathanaël; Gawron, Piotr; Gebel, Stephan; Hainaut, Pierre; Ollert, Markus; Doğrusöz, Uğur; Barillot, Emmanuel; Zinovyev, Andreï; Schneider, Reinhard; Balling, Rudi; Auffray, Charles

doi:10.1038/s41540-018-0059-y

Cited by 96 publications

(86 citation statements)

References 53 publications

(79 reference statements)

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“…The Health Research and Innovation Cloud (HRIC), as described in this manuscript, would help to facilitate this transition, providing access to larger datasets, cutting-edge tools, and knowledge, as envisioned by Auffray et al [3]. For example, the HRIC should ease the incorporation of domain expert knowledge into systems disease maps in a format that can be both understood by all stakeholders (patients and clinicians, scientists, and drug developers) and processed by highperformance computers, thus supporting the development of innovative medicines and diagnostics [4,5]. Cloud technologies (accessed through Hadoop applications, for example) also make it possible to collaborate and to access and reuse data in situations when privacy concerns or regulation prohibits remote users from downloading data-an important benefit in Europe where national regulations can differ significantly.…”

Section: Introductionmentioning

confidence: 98%

Towards a European health research and innovation cloud (HRIC)

Aarestrup

Albeyatti

Armitage³

et al. 2020

Genome Med

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The European Union (EU) initiative on the Digital Transformation of Health and Care (Digicare) aims to provide the conditions necessary for building a secure, flexible, and decentralized digital health infrastructure. Creating a European Health Research and Innovation Cloud (HRIC) within this environment should enable data sharing and analysis for health research across the EU, in compliance with data protection legislation while preserving the full trust of the participants. Such a HRIC should learn from and build on existing data infrastructures, integrate best practices, and focus on the concrete needs of the community in terms of technologies, governance, management, regulation, and ethics requirements. Here, we describe the vision and expected benefits of digital data sharing in health research activities and present a roadmap that fosters the opportunities while answering the challenges of implementing a HRIC. For this, we put forward five specific recommendations and action points to ensure that a European HRIC: i) is built on established standards and guidelines, providing cloud technologies through an open and decentralized infrastructure; ii) is developed and certified to the highest standards of interoperability and data security that can be trusted by all stakeholders; iii) is supported by a robust ethical and legal framework that is compliant with the EU General Data Protection Regulation (GDPR); iv) establishes a proper environment for the training of new generations of data and medical scientists; and v) stimulates research and innovation in transnational collaborations through public and private initiatives and partnerships funded by the EU through Horizon 2020 and Horizon Europe.

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Section: Introductionmentioning

confidence: 98%

Towards a European health research and innovation cloud (HRIC)

Aarestrup

Albeyatti

Armitage³

et al. 2020

Genome Med

Self Cite

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“…Disease maps are repositories of knowledge of disease-relevant mechanisms that provide qualitative guidance for the interpretation of experimental ndings (2). Actually, disease maps are the supporting foundation of different tools able to model the information contained in them in order to provide a detailed quantitative explanation for experimental results (5). In particular, mechanistic models of disease maps are becoming increasingly relevant for genomic data interpretation because they provide a natural link between omics data measurements and cell behavior and outcome (6), which ultimately accounts for the phenotype of the infection.…”

Section: Introductionmentioning

confidence: 99%

Mechanistic modeling of the SARS-CoV-2 disease map

Rian

Esteban-Medina

Hidalgo

et al. 2020

Preprint

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Here we present a web interface that implements a comprehensive mechanistic model of the SARS-CoV-2 disease map. In this framework, the detailed activity of the human signaling circuits related to the viral infection, covering from the entry and replication mechanisms to the downstream consequences as inflammation and antigenic response, can be inferred from gene expression experiments. Moreover, the effect of potential interventions, such as knock-downs, or drug effects (currently the system models the effect of more than 8000 DrugBank drugs) can be studied. This freely available tool not only provides an unprecedentedly detailed view of the mechanisms of viral invasion and the consequences in the cell but has also the potential of becoming an invaluable asset in the search for efficient antiviral treatments.

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“…Others, such as the interplay of multiple pathways in complex diseases or the functioning of whole cells, need large models to be described (Hass et al, 2017;Karr et al, 2012;Swainston et al, 2016). Due to the advances in experimental and computational methods, many large-scale models have been developed in recent years (Froehlich et al, 2018;Khodayari and Maranas, 2017;Mazein et al, 2018). As the data acquisition speed continuously increases (Barretina et al, 2012;Li et al, 2017) and more sophisticated tools for model development appear (Gyori et al, 2017), this trend is likely to persist.…”

Section: Introductionmentioning

confidence: 99%

Challenges in the calibration of large-scale ordinary differential equation models

Kapfer

Stapor

Hasenauer

2019

Preprint

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Mathematical models based on ordinary differential equations have been employed with great success to study complex biological systems. With soaring data availability, more and more models of increasing size are being developed. When working with these large-scale models, several challenges arise, such as high computation times or poor identifiability of model parameters. In this work, we review and illustrate the most common challenges using a published model of cellular metabolism. We summarize currently available methods to deal with some of these challenges while focusing on reproducibility and reusability of models, efficient and robust model simulation and parameter estimation.

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Systems medicine disease maps: community-driven comprehensive representation of disease mechanisms

Cited by 96 publications

References 53 publications

Towards a European health research and innovation cloud (HRIC)

Towards a European health research and innovation cloud (HRIC)

Mechanistic modeling of the SARS-CoV-2 disease map

Challenges in the calibration of large-scale ordinary differential equation models

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