NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment

Antreas Afantitis; Georgia Melagraki; Panagiotis Isigonis; Andreas Tsoumanis; Dimitra Danai Varsou; Eugenia Valsami-jones; Anastasios Papadiamantis; Laura-jayne A. Ellis; Haralambos Sarimveis; Philip Doganis; Pantelis Karatzas; Periklis Tsiros; Irene Liampa; Vladimir Lobaskin; Dario Greco; Angela Serra; Pia Anneli Sofia Kinaret; Laura Aliisa Saarimäki; Roland Grafström; Pekka Kohonen; Penny Nymark; Egon Willighagen; Tomasz Puzyn; Anna Rybinska-fryca; Alexander Lyubartsev; Keld Alstrup Jensen; Jan Gerit Brandenburg; Stephen Lofts; Claus Svendsen; Samuel Harrison; Dieter Maier; Kaido Tamm; Jaak Jänes; Lauri Sikk; Maria Dusinska; Eleonora Longhin; Elise Rundén-pran; Espen Mariussen; Naouale El Yamani; Wolfgang Unger; Jörg Radnik; Alexander Tropsha; Yoram Cohen; Jerzy Leszczynski; Christine Ogilvie Hendren; Mark Wiesner; David Winkler; Noriyuki Suzuki; Tae Hyun Yoon; Jang-sik Choi; Natasha Sanabria; Mary Gulumian; Iseult Lynch

doi:10.1016/j.csbj.2020.02.023

NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment

Antreas Afantitis^*, Georgia Melagraki, Panagiotis Isigonis, Andreas Tsoumanis, Dimitra Danai Varsou, Eugenia Valsami-jones, Anastasios Papadiamantis, Laura-jayne A. Ellis, Haralambos Sarimveis, Philip Doganis, Pantelis Karatzas, Periklis Tsiros, Irene Liampa, Vladimir Lobaskin, Dario Greco, Angela Serra, Pia Anneli Sofia Kinaret, Laura Aliisa Saarimäki, Roland Grafström, Pekka KohonenPenny Nymark, Egon Willighagen, Tomasz Puzyn, Anna Rybinska-fryca, Alexander Lyubartsev, Keld Alstrup Jensen, Jan Gerit Brandenburg, Stephen Lofts, Claus Svendsen, Samuel Harrison, Dieter Maier, Kaido Tamm, Jaak Jänes, Lauri Sikk, Maria Dusinska, Eleonora Longhin, Elise Rundén-pran, Espen Mariussen, Naouale El Yamani, Wolfgang Unger, Jörg Radnik, Alexander Tropsha, Yoram Cohen, Jerzy Leszczynski, Christine Ogilvie Hendren, Mark Wiesner, David Winkler, Noriyuki Suzuki, Tae Hyun Yoon, Jang-sik Choi, Natasha Sanabria, Mary Gulumian, Iseult Lynch^*

^*Corresponding author for this work

Research output: Contribution to journal › (Systematic) Review article › peer-review

Abstract

Nanotechnology has enabled the discovery of a multitude of novel materials exhibiting unique physicochemical (PChem) properties compared to their bulk analogues. These properties have led to a rapidly increasing range of commercial applications; this, however, may come at a cost, if an association to long-term health and environmental risks is discovered or even just perceived. Many nanomaterials (NMs) have not yet had their potential adverse biological effects fully assessed, due to costs and time constraints associated with the experimental assessment, frequently involving animals. Here, the available NM libraries are analyzed for their suitability for integration with novel nanoinformatics approaches and for the development of NM specific Integrated Approaches to Testing and Assessment (IATA) for human and environmental risk assessment, all within the NanoSolveIT cloud-platform. These established and well-characterized NM libraries (e.g. NanoMILE, NanoSolutions, NANoREG, NanoFASE, caLIBRAte, NanoTEST and the Nanomaterial Registry (>2000 NMs)) contain physicochemical characterization data as well as data for several relevant biological endpoints, assessed in part using harmonized Organisation for Economic Co-operation and Development (OECD) methods and test guidelines. Integration of such extensive NM information sources with the latest nanoinformatics methods will allow NanoSolveIT to model the relationships between NM structure (morphology), properties and their adverse effects and to predict the effects of other NMs for which less data is available. The project specifically addresses the needs of regulatory agencies and industry to effectively and rapidly evaluate the exposure, NM hazard and risk from nanomaterials and nano-enabled products, enabling implementation of computational ‘safe-by-design’ approaches to facilitate NM commercialization.

Original language	English
Pages (from-to)	583-602
Number of pages	20
Journal	Computational and Structural Biotechnology Journal
Volume	18
DOIs	https://doi.org/10.1016/j.csbj.2020.02.023
Publication status	Published - 7 Mar 2020

Keywords

Nanoinformatics
Computational toxicology
Hazard assessment
Engineered nanomaterials
(quantitative) Structure-activity relationships
Integrated approach for testing and assessment
Safe-by-design
Machine learning
Read across
Toxicogenomics
Predictive modelling
METAL-OXIDE NANOPARTICLES
INDUCE OXIDATIVE STRESS
CARBON NANOTUBES
PROTEIN CORONA
QUANTITATIVE STRUCTURE
PULMONARY INFLAMMATION
DEPENDENT TOXICITY
CELLULAR TOXICITY
NANOMATERIAL DATA
FORCE-FIELD

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10.1016/j.csbj.2020.02.023Licence: CC BY

Cite this

Afantitis, A., Melagraki, G., Isigonis, P., Tsoumanis, A., Varsou, D. D., Valsami-jones, E., Papadiamantis, A., Ellis, L. A., Sarimveis, H., Doganis, P., Karatzas, P., Tsiros, P., Liampa, I., Lobaskin, V., Greco, D., Serra, A., Kinaret, P. A. S., Saarimäki, L. A., Grafström, R., ... Lynch, I. (2020). NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment. Computational and Structural Biotechnology Journal, 18, 583-602. https://doi.org/10.1016/j.csbj.2020.02.023

@article{8adc040ba1ec4282b43f64d008319049,

title = "NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment",

abstract = "Nanotechnology has enabled the discovery of a multitude of novel materials exhibiting unique physicochemical (PChem) properties compared to their bulk analogues. These properties have led to a rapidly increasing range of commercial applications; this, however, may come at a cost, if an association to long-term health and environmental risks is discovered or even just perceived. Many nanomaterials (NMs) have not yet had their potential adverse biological effects fully assessed, due to costs and time constraints associated with the experimental assessment, frequently involving animals. Here, the available NM libraries are analyzed for their suitability for integration with novel nanoinformatics approaches and for the development of NM specific Integrated Approaches to Testing and Assessment (IATA) for human and environmental risk assessment, all within the NanoSolveIT cloud-platform. These established and well-characterized NM libraries (e.g. NanoMILE, NanoSolutions, NANoREG, NanoFASE, caLIBRAte, NanoTEST and the Nanomaterial Registry (>2000 NMs)) contain physicochemical characterization data as well as data for several relevant biological endpoints, assessed in part using harmonized Organisation for Economic Co-operation and Development (OECD) methods and test guidelines. Integration of such extensive NM information sources with the latest nanoinformatics methods will allow NanoSolveIT to model the relationships between NM structure (morphology), properties and their adverse effects and to predict the effects of other NMs for which less data is available. The project specifically addresses the needs of regulatory agencies and industry to effectively and rapidly evaluate the exposure, NM hazard and risk from nanomaterials and nano-enabled products, enabling implementation of computational {\textquoteleft}safe-by-design{\textquoteright} approaches to facilitate NM commercialization.",

keywords = "Nanoinformatics, Computational toxicology, Hazard assessment, Engineered nanomaterials, (quantitative) Structure-activity relationships, Integrated approach for testing and assessment, Safe-by-design, Machine learning, Read across, Toxicogenomics, Predictive modelling, METAL-OXIDE NANOPARTICLES, INDUCE OXIDATIVE STRESS, CARBON NANOTUBES, PROTEIN CORONA, QUANTITATIVE STRUCTURE, PULMONARY INFLAMMATION, DEPENDENT TOXICITY, CELLULAR TOXICITY, NANOMATERIAL DATA, FORCE-FIELD",

author = "Antreas Afantitis and Georgia Melagraki and Panagiotis Isigonis and Andreas Tsoumanis and Varsou, {Dimitra Danai} and Eugenia Valsami-jones and Anastasios Papadiamantis and Ellis, {Laura-jayne A.} and Haralambos Sarimveis and Philip Doganis and Pantelis Karatzas and Periklis Tsiros and Irene Liampa and Vladimir Lobaskin and Dario Greco and Angela Serra and Kinaret, {Pia Anneli Sofia} and Saarim{\"a}ki, {Laura Aliisa} and Roland Grafstr{\"o}m and Pekka Kohonen and Penny Nymark and Egon Willighagen and Tomasz Puzyn and Anna Rybinska-fryca and Alexander Lyubartsev and {Alstrup Jensen}, Keld and Brandenburg, {Jan Gerit} and Stephen Lofts and Claus Svendsen and Samuel Harrison and Dieter Maier and Kaido Tamm and Jaak J{\"a}nes and Lauri Sikk and Maria Dusinska and Eleonora Longhin and Elise Rund{\'e}n-pran and Espen Mariussen and {El Yamani}, Naouale and Wolfgang Unger and J{\"o}rg Radnik and Alexander Tropsha and Yoram Cohen and Jerzy Leszczynski and {Ogilvie Hendren}, Christine and Mark Wiesner and David Winkler and Noriyuki Suzuki and Yoon, {Tae Hyun} and Jang-sik Choi and Natasha Sanabria and Mary Gulumian and Iseult Lynch",

note = "Funding Information: This work has received funding from the European Union {\textquoteright}s Horizon 2020 research and innovation programme via NanoSolveIT Project under grant agreement No 814572. Tae Hyun Yoon (THY) and Jang-Sik Choi (JSC) also appreciate partial support by the Korean Ministry of Science & ICT (MSIT) and the National Research Foundation (NRF) through the International Cooperative R&D Program (No. 2019K1A3A1A78112959), as a part of the European Union {\textquoteright}s Horizon 2020 NanoSolveIT Project. Funding Information: This work has received funding from the European Union's Horizon 2020 research and innovation programme via NanoSolveIT Project under grant agreement No 814572. Tae Hyun Yoon (THY) and Jang-Sik Choi (JSC) also appreciate partial support by the Korean Ministry of Science & ICT (MSIT) and the National Research Foundation (NRF) through the International Cooperative R&D Program (No. 2019K1A3A1A78112959), as a part of the European Union's Horizon 2020 NanoSolveIT Project. Publisher Copyright: {\textcopyright} 2020 The Authors",

year = "2020",

month = mar,

day = "7",

doi = "10.1016/j.csbj.2020.02.023",

language = "English",

volume = "18",

pages = "583--602",

journal = "Computational and Structural Biotechnology Journal",

issn = "2001-0370",

publisher = "Research Network of Computational and Structural Biotechnology",

}

Afantitis, A, Melagraki, G, Isigonis, P, Tsoumanis, A, Varsou, DD, Valsami-jones, E, Papadiamantis, A, Ellis, LA, Sarimveis, H, Doganis, P, Karatzas, P, Tsiros, P, Liampa, I, Lobaskin, V, Greco, D, Serra, A, Kinaret, PAS, Saarimäki, LA, Grafström, R, Kohonen, P, Nymark, P, Willighagen, E, Puzyn, T, Rybinska-fryca, A, Lyubartsev, A, Alstrup Jensen, K, Brandenburg, JG, Lofts, S, Svendsen, C, Harrison, S, Maier, D, Tamm, K, Jänes, J, Sikk, L, Dusinska, M, Longhin, E, Rundén-pran, E, Mariussen, E, El Yamani, N, Unger, W, Radnik, J, Tropsha, A, Cohen, Y, Leszczynski, J, Ogilvie Hendren, C, Wiesner, M, Winkler, D, Suzuki, N, Yoon, TH, Choi, J, Sanabria, N, Gulumian, M & Lynch, I 2020, 'NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment', Computational and Structural Biotechnology Journal, vol. 18, pp. 583-602. https://doi.org/10.1016/j.csbj.2020.02.023

NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment. / Afantitis, Antreas; Melagraki, Georgia; Isigonis, Panagiotis et al.
In: Computational and Structural Biotechnology Journal, Vol. 18, 07.03.2020, p. 583-602.

Research output: Contribution to journal › (Systematic) Review article › peer-review

TY - JOUR

T1 - NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment

AU - Afantitis, Antreas

AU - Melagraki, Georgia

AU - Isigonis, Panagiotis

AU - Tsoumanis, Andreas

AU - Varsou, Dimitra Danai

AU - Valsami-jones, Eugenia

AU - Papadiamantis, Anastasios

AU - Ellis, Laura-jayne A.

AU - Sarimveis, Haralambos

AU - Doganis, Philip

AU - Karatzas, Pantelis

AU - Tsiros, Periklis

AU - Liampa, Irene

AU - Lobaskin, Vladimir

AU - Greco, Dario

AU - Serra, Angela

AU - Kinaret, Pia Anneli Sofia

AU - Saarimäki, Laura Aliisa

AU - Grafström, Roland

AU - Kohonen, Pekka

AU - Nymark, Penny

AU - Willighagen, Egon

AU - Puzyn, Tomasz

AU - Rybinska-fryca, Anna

AU - Lyubartsev, Alexander

AU - Alstrup Jensen, Keld

AU - Brandenburg, Jan Gerit

AU - Lofts, Stephen

AU - Svendsen, Claus

AU - Harrison, Samuel

AU - Maier, Dieter

AU - Tamm, Kaido

AU - Jänes, Jaak

AU - Sikk, Lauri

AU - Dusinska, Maria

AU - Longhin, Eleonora

AU - Rundén-pran, Elise

AU - Mariussen, Espen

AU - El Yamani, Naouale

AU - Unger, Wolfgang

AU - Radnik, Jörg

AU - Tropsha, Alexander

AU - Cohen, Yoram

AU - Leszczynski, Jerzy

AU - Ogilvie Hendren, Christine

AU - Wiesner, Mark

AU - Winkler, David

AU - Suzuki, Noriyuki

AU - Yoon, Tae Hyun

AU - Choi, Jang-sik

AU - Sanabria, Natasha

AU - Gulumian, Mary

AU - Lynch, Iseult

N1 - Funding Information: This work has received funding from the European Union ’s Horizon 2020 research and innovation programme via NanoSolveIT Project under grant agreement No 814572. Tae Hyun Yoon (THY) and Jang-Sik Choi (JSC) also appreciate partial support by the Korean Ministry of Science & ICT (MSIT) and the National Research Foundation (NRF) through the International Cooperative R&D Program (No. 2019K1A3A1A78112959), as a part of the European Union ’s Horizon 2020 NanoSolveIT Project. Funding Information: This work has received funding from the European Union's Horizon 2020 research and innovation programme via NanoSolveIT Project under grant agreement No 814572. Tae Hyun Yoon (THY) and Jang-Sik Choi (JSC) also appreciate partial support by the Korean Ministry of Science & ICT (MSIT) and the National Research Foundation (NRF) through the International Cooperative R&D Program (No. 2019K1A3A1A78112959), as a part of the European Union's Horizon 2020 NanoSolveIT Project. Publisher Copyright: © 2020 The Authors

PY - 2020/3/7

Y1 - 2020/3/7

N2 - Nanotechnology has enabled the discovery of a multitude of novel materials exhibiting unique physicochemical (PChem) properties compared to their bulk analogues. These properties have led to a rapidly increasing range of commercial applications; this, however, may come at a cost, if an association to long-term health and environmental risks is discovered or even just perceived. Many nanomaterials (NMs) have not yet had their potential adverse biological effects fully assessed, due to costs and time constraints associated with the experimental assessment, frequently involving animals. Here, the available NM libraries are analyzed for their suitability for integration with novel nanoinformatics approaches and for the development of NM specific Integrated Approaches to Testing and Assessment (IATA) for human and environmental risk assessment, all within the NanoSolveIT cloud-platform. These established and well-characterized NM libraries (e.g. NanoMILE, NanoSolutions, NANoREG, NanoFASE, caLIBRAte, NanoTEST and the Nanomaterial Registry (>2000 NMs)) contain physicochemical characterization data as well as data for several relevant biological endpoints, assessed in part using harmonized Organisation for Economic Co-operation and Development (OECD) methods and test guidelines. Integration of such extensive NM information sources with the latest nanoinformatics methods will allow NanoSolveIT to model the relationships between NM structure (morphology), properties and their adverse effects and to predict the effects of other NMs for which less data is available. The project specifically addresses the needs of regulatory agencies and industry to effectively and rapidly evaluate the exposure, NM hazard and risk from nanomaterials and nano-enabled products, enabling implementation of computational ‘safe-by-design’ approaches to facilitate NM commercialization.

AB - Nanotechnology has enabled the discovery of a multitude of novel materials exhibiting unique physicochemical (PChem) properties compared to their bulk analogues. These properties have led to a rapidly increasing range of commercial applications; this, however, may come at a cost, if an association to long-term health and environmental risks is discovered or even just perceived. Many nanomaterials (NMs) have not yet had their potential adverse biological effects fully assessed, due to costs and time constraints associated with the experimental assessment, frequently involving animals. Here, the available NM libraries are analyzed for their suitability for integration with novel nanoinformatics approaches and for the development of NM specific Integrated Approaches to Testing and Assessment (IATA) for human and environmental risk assessment, all within the NanoSolveIT cloud-platform. These established and well-characterized NM libraries (e.g. NanoMILE, NanoSolutions, NANoREG, NanoFASE, caLIBRAte, NanoTEST and the Nanomaterial Registry (>2000 NMs)) contain physicochemical characterization data as well as data for several relevant biological endpoints, assessed in part using harmonized Organisation for Economic Co-operation and Development (OECD) methods and test guidelines. Integration of such extensive NM information sources with the latest nanoinformatics methods will allow NanoSolveIT to model the relationships between NM structure (morphology), properties and their adverse effects and to predict the effects of other NMs for which less data is available. The project specifically addresses the needs of regulatory agencies and industry to effectively and rapidly evaluate the exposure, NM hazard and risk from nanomaterials and nano-enabled products, enabling implementation of computational ‘safe-by-design’ approaches to facilitate NM commercialization.

KW - Nanoinformatics

KW - Computational toxicology

KW - Hazard assessment

KW - Engineered nanomaterials

KW - (quantitative) Structure-activity relationships

KW - Integrated approach for testing and assessment

KW - Safe-by-design

KW - Machine learning

KW - Read across

KW - Toxicogenomics

KW - Predictive modelling

KW - METAL-OXIDE NANOPARTICLES

KW - INDUCE OXIDATIVE STRESS

KW - CARBON NANOTUBES

KW - PROTEIN CORONA

KW - QUANTITATIVE STRUCTURE

KW - PULMONARY INFLAMMATION

KW - DEPENDENT TOXICITY

KW - CELLULAR TOXICITY

KW - NANOMATERIAL DATA

KW - FORCE-FIELD

U2 - 10.1016/j.csbj.2020.02.023

DO - 10.1016/j.csbj.2020.02.023

M3 - (Systematic) Review article

C2 - 32226594

SN - 2001-0370

VL - 18

SP - 583

EP - 602

JO - Computational and Structural Biotechnology Journal

JF - Computational and Structural Biotechnology Journal

ER -