NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter?

Iseult Lynch; Sara Linse; C. Vyvyan Howard; MacIej Stepnik; Konrad Rydzynski; John Hanrahan; Wim De Jong; Dominique Langevin; Joachim Rädler; Wolfgang Parak; Yuri Volkov; Marek Radomski; Robert Thomas; Jacob Klein; Andrew A. Barron; Colin Janssen; Fiona M. Lyons; Francis Quinn; Bert Swennen; Peter Cuypers; Angela Duffy; Kenneth A. Dawson

doi:10.1088/1742-6596/170/1/012040

NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter?

Iseult Lynch^*, Sara Linse, C. Vyvyan Howard, MacIej Stepnik, Konrad Rydzynski, John Hanrahan, Wim De Jong, Dominique Langevin, Joachim Rädler, Wolfgang Parak, Yuri Volkov, Marek Radomski, Robert Thomas, Jacob Klein, Andrew A. Barron, Colin Janssen, Fiona M. Lyons, Francis Quinn, Bert Swennen, Peter CuypersAngela Duffy, Kenneth A. Dawson

^*Corresponding author for this work

Department of Molecular Chemistry and Materials Science Perlman

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

The importance of understanding the interactions between nanoscale materials and living matter has now begun to be appreciated by an extraordinaryly large range of stakeholders, including researchers, industry, governments and society, all of whom appreciate both the opportunities presented by and challenges raised by this arena of research. Not only does it open up new directions in nanomedicine and nanodiagnostics, but it also offers the chance to implement nanotechnology across all industry in a safe and responsible manner. The underlying reasons for this arena as a new scientific paradigm are real and durable. Less than 100 nm nanoparticles can enter cells, less that 40 nm they can enter cell nucleus, and less that 35 nm they can pass through the blood brain barrier. These are fundamental length scales of biological relevance that will ensure that engineered nanoscience will impinge on biology and medicine for many decades to come. One important issue is the current lack of reproducibility of the outcomes of many experiments in this arena. Differences are likely a consequence of such things as uncontrolled nanoparticle aggregation leading to unpredictable doses being presented to cells, interference of the nanoparticles themselves with many of the tests being applied, differences in the degree of confluency of the cells used, and a host of other factors. NanoInteract has shown how careful control of all aspects of the test system, combined with round robin type approaches, can help resolve these issues and begin to ensure that the field can become a quantitative science. The basic principle of NanoInteract is that given identical nanomaterials, cells and biological materials, and using a common protocol, experiments must yield identical answers. Thus, any deviations result from errors in (applying) the protocol which can be tracked and eliminated, until quantitatively reproducible results are obtained by any researcher in any location. This paper outlines the NanoInteract programme, illustrates key advances, and highlights early successes. (www.nanointeract.net)

Original language	English
Article number	012040
Journal	Journal of Physics: Conference Series
Volume	170
DOIs	https://doi.org/10.1088/1742-6596/170/1/012040
Publication status	Published - 1 Jan 2009

Bibliographical note

The authors wish to thank the entire NanoInteract consortium. This work is funded by the EU FP6 STReP project NanoInteract 033231. Many postgraduate students and postdoctoral researchers have been involved in this work, and their names can be found in the original articles. Clearly this article represents a very limited selection of the findings from the NanoInteract project. Additional summary articles from the NanoInteract consortium are envisaged in these other areas.

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1088/1742-6596/170/1/012040Licence: Unspecified

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Lynch, I., Linse, S., Vyvyan Howard, C., Stepnik, M., Rydzynski, K., Hanrahan, J., De Jong, W., Langevin, D., Rädler, J., Parak, W., Volkov, Y., Radomski, M., Thomas, R., Klein, J., Barron, A. A., Janssen, C., Lyons, F. M., Quinn, F., Swennen, B., ... Dawson, K. A. (2009). NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter? Journal of Physics: Conference Series, 170, Article 012040. https://doi.org/10.1088/1742-6596/170/1/012040

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title = "NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter?",

abstract = "The importance of understanding the interactions between nanoscale materials and living matter has now begun to be appreciated by an extraordinaryly large range of stakeholders, including researchers, industry, governments and society, all of whom appreciate both the opportunities presented by and challenges raised by this arena of research. Not only does it open up new directions in nanomedicine and nanodiagnostics, but it also offers the chance to implement nanotechnology across all industry in a safe and responsible manner. The underlying reasons for this arena as a new scientific paradigm are real and durable. Less than 100 nm nanoparticles can enter cells, less that 40 nm they can enter cell nucleus, and less that 35 nm they can pass through the blood brain barrier. These are fundamental length scales of biological relevance that will ensure that engineered nanoscience will impinge on biology and medicine for many decades to come. One important issue is the current lack of reproducibility of the outcomes of many experiments in this arena. Differences are likely a consequence of such things as uncontrolled nanoparticle aggregation leading to unpredictable doses being presented to cells, interference of the nanoparticles themselves with many of the tests being applied, differences in the degree of confluency of the cells used, and a host of other factors. NanoInteract has shown how careful control of all aspects of the test system, combined with round robin type approaches, can help resolve these issues and begin to ensure that the field can become a quantitative science. The basic principle of NanoInteract is that given identical nanomaterials, cells and biological materials, and using a common protocol, experiments must yield identical answers. Thus, any deviations result from errors in (applying) the protocol which can be tracked and eliminated, until quantitatively reproducible results are obtained by any researcher in any location. This paper outlines the NanoInteract programme, illustrates key advances, and highlights early successes. (www.nanointeract.net)",

author = "Iseult Lynch and Sara Linse and {Vyvyan Howard}, C. and MacIej Stepnik and Konrad Rydzynski and John Hanrahan and {De Jong}, Wim and Dominique Langevin and Joachim R{\"a}dler and Wolfgang Parak and Yuri Volkov and Marek Radomski and Robert Thomas and Jacob Klein and Barron, {Andrew A.} and Colin Janssen and Lyons, {Fiona M.} and Francis Quinn and Bert Swennen and Peter Cuypers and Angela Duffy and Dawson, {Kenneth A.}",

note = "The authors wish to thank the entire NanoInteract consortium. This work is funded by the EU FP6 STReP project NanoInteract 033231. Many postgraduate students and postdoctoral researchers have been involved in this work, and their names can be found in the original articles. Clearly this article represents a very limited selection of the findings from the NanoInteract project. Additional summary articles from the NanoInteract consortium are envisaged in these other areas. ",

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Lynch, I, Linse, S, Vyvyan Howard, C, Stepnik, M, Rydzynski, K, Hanrahan, J, De Jong, W, Langevin, D, Rädler, J, Parak, W, Volkov, Y, Radomski, M, Thomas, R, Klein, J, Barron, AA, Janssen, C, Lyons, FM, Quinn, F, Swennen, B, Cuypers, P, Duffy, A & Dawson, KA 2009, 'NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter?', Journal of Physics: Conference Series, vol. 170, 012040. https://doi.org/10.1088/1742-6596/170/1/012040

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AU - Stepnik, MacIej

AU - Rydzynski, Konrad

AU - Hanrahan, John

AU - De Jong, Wim

AU - Langevin, Dominique

AU - Rädler, Joachim

AU - Parak, Wolfgang

AU - Volkov, Yuri

AU - Radomski, Marek

AU - Thomas, Robert

AU - Klein, Jacob

AU - Barron, Andrew A.

AU - Janssen, Colin

AU - Lyons, Fiona M.

AU - Quinn, Francis

AU - Swennen, Bert

AU - Cuypers, Peter

AU - Duffy, Angela

AU - Dawson, Kenneth A.

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NANOINTERACT: A rational approach to the interaction between nanoscale materials and living matter?

Abstract

Bibliographical note

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