Monitoring cellular stress responses to nanoparticles using a lab-on-a-chip

As nanotechnology moves towards widespread commercialization, new technologies are needed to adequately address the potential health impact of nanoparticles (NPs). Assessing the safety of over 30,000 NPs through animal testing would not only be expensive, but it would also raise a number of ethical...

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Published in:Lab on a chip 2011-08, Vol.11 (15), p.2551-2560
Main Authors: Richter, Lukas, Charwat, Verena, Jungreuthmayer, Christian, Bellutti, Florian, Brueckl, Hubert, Ertl, Peter
Format: Article
Language:English
Subjects:
Cells, Cultured
Cellular
Collagen - biosynthesis
Collagens
Fibroblasts
Fibroblasts - cytology
Fibroblasts - metabolism
Gold - pharmacology
Human
Humans
Metal Nanoparticles
Microfluidic Analytical Techniques - instrumentation
Microfluidic Analytical Techniques - methods
Monitoring
Nanoparticles
Silver
Silver - pharmacology
Stress, Physiological
Stresses
Time Factors
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cited_by cdi_FETCH-LOGICAL-c318t-aa7678719678abe091ac544c52c990c5d4576c7f15fcc0b9bcb343db86d3cf6e3
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container_issue 15
container_start_page 2551
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creator Richter, Lukas
Charwat, Verena
Jungreuthmayer, Christian
Bellutti, Florian
Brueckl, Hubert
Ertl, Peter
description As nanotechnology moves towards widespread commercialization, new technologies are needed to adequately address the potential health impact of nanoparticles (NPs). Assessing the safety of over 30,000 NPs through animal testing would not only be expensive, but it would also raise a number of ethical considerations. Furthermore, existing in vitro cell-based assays are not sufficient in scope to adequately address the complexity of cell-nanoparticle interactions including NP translocation, accumulation and co-transport of e.g. allergens. In particular, classical optical/fluorescent endpoint detection methods are known to provide irreproducible, inaccurate and unreliable results since these labels can directly react with the highly catalytic surfaces of NP. To bridge this technological gap we have developed a lab-on-a-chip capable of continuously and non-invasively monitoring the collagen production of primary human fibroblast cells (NHDF) using contactless dielectric microsensors. Human dermal fibroblast cells are responsible for the maintenance of soft tissue integrity, are found throughout the human body and their primary function is collagen expression. We show that cellular collagen production can be readily detected and used to assess cellular stress responses to a variety of external stimuli, including exposure to nanoparticles. Results of the study showed a 20% and 95% reduction of collagen production following 4 hour exposure to 10 μg mL(-1) gold and silver nanoparticles (dia.10 nm), respectively. Furthermore a prolonged perfusion of sub-toxic concentrations (0.1 μg mL(-1)) of silver NP reduced NHDF collagen production by 40% after 10 h indicating increased NP take up and accumulation. We demonstrate that the application of microfluidics for the tailored administration of different NP treatments constitutes a powerful new tool to study cell-nanoparticle interactions and nanoparticle accumulation effects in small cell populations.
doi_str_mv 10.1039/c1lc20256a
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source Royal Society of Chemistry
subjects Cells, Cultured
Cellular
Collagen - biosynthesis
Collagens
Fibroblasts
Fibroblasts - cytology
Fibroblasts - metabolism
Gold - pharmacology
Human
Humans
Metal Nanoparticles
Microfluidic Analytical Techniques - instrumentation
Microfluidic Analytical Techniques - methods
Monitoring
Nanoparticles
Silver
Silver - pharmacology
Stress, Physiological
Stresses
Time Factors
title Monitoring cellular stress responses to nanoparticles using a lab-on-a-chip
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