Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier

Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier

Pulmonary barrier function plays a pivotal role in protection from inhaled particles. However, some nano-scaled particles, such as carbon nanotubes (CNT), have demonstrated the ability to penetrate this barrier in animal models, resulting in an unusual, rapid interstitial fibrosis. To delineate the...

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Main Authors: Raymond Derk, Donna C. Davidson, Amruta Manke, Todd A. Stueckle, Yon Rojanasakul, Liying Wang
Format: Article
Language:English
Published: Elsevier 2015-03-01
Series:Sensing and Bio-Sensing Research
Subjects:
Nanoparticles
Lung
In vitro model
Pulmonary barrier
Toxicology
Online Access:http://www.sciencedirect.com/science/article/pii/S2214180414000439
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spelling doaj-3772ed8682e3489c8d31f259e38997fc2020-11-25T01:01:37ZengElsevierSensing and Bio-Sensing Research2214-18042015-03-013C384510.1016/j.sbsr.2014.12.002Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrierRaymond Derk0Donna C. Davidson1Amruta Manke2Todd A. Stueckle3Yon Rojanasakul4Liying Wang5National Institute for Occupational Safety and Health, HELD/PPRB, Morgantown, WV 26505, USANational Institute for Occupational Safety and Health, HELD/PPRB, Morgantown, WV 26505, USAWest Virginia University, School of Pharmacy, Morgantown, WV 26506, USANational Institute for Occupational Safety and Health, HELD/PPRB, Morgantown, WV 26505, USAWest Virginia University, School of Pharmacy, Morgantown, WV 26506, USANational Institute for Occupational Safety and Health, HELD/PPRB, Morgantown, WV 26505, USAPulmonary barrier function plays a pivotal role in protection from inhaled particles. However, some nano-scaled particles, such as carbon nanotubes (CNT), have demonstrated the ability to penetrate this barrier in animal models, resulting in an unusual, rapid interstitial fibrosis. To delineate the underlying mechanism and specific bio-effect of inhaled nanoparticles in respiratory toxicity, models of lung epithelial barriers are required that allow accurate representation of in vivo systems; however, there is currently a lack of consistent methods to do so. Thus, this work demonstrates a well-characterized in vitro model of pulmonary barrier function using Calu-3 cells, and provides the experimental conditions required for achieving tight junction complexes in cell culture, with trans-epithelial electrical resistance measurement used as a biosensor for proper barrier formation and integrity. The effects of cell number and serum constituents have been examined and we found that changes in each of these parameters can greatly affect barrier formation. Our data demonstrate that use of 5.0 × 104 Calu-3 cells/well in the Transwell cell culture system, with 10% serum concentrations in culture media is optimal for assessing epithelial barrier function. In addition, we have utilized CNT exposure to analyze the dose-, time-, and nanoparticle property-dependent alterations of epithelial barrier permeability as a means to validate this model. Such high throughput in vitro cell models of the epithelium could be used to predict the interaction of other nanoparticles with lung epithelial barriers to mimic respiratory behavior in vivo, thus providing essential tools and bio-sensing techniques that can be uniformly employed.http://www.sciencedirect.com/science/article/pii/S2214180414000439NanoparticlesLungIn vitro modelPulmonary barrierToxicology
collection DOAJ
language English
format Article
sources DOAJ
author Raymond Derk
Donna C. Davidson
Amruta Manke
Todd A. Stueckle
Yon Rojanasakul
Liying Wang
spellingShingle Raymond Derk
Donna C. Davidson
Amruta Manke
Todd A. Stueckle
Yon Rojanasakul
Liying Wang
Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
Sensing and Bio-Sensing Research
Nanoparticles
Lung
In vitro model
Pulmonary barrier
Toxicology
author_facet Raymond Derk
Donna C. Davidson
Amruta Manke
Todd A. Stueckle
Yon Rojanasakul
Liying Wang
author_sort Raymond Derk
title Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
title_short Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
title_full Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
title_fullStr Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
title_full_unstemmed Potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
title_sort potential in vitro model for testing the effect of exposure to nanoparticles on the lung alveolar epithelial barrier
publisher Elsevier
series Sensing and Bio-Sensing Research
issn 2214-1804
publishDate 2015-03-01
description Pulmonary barrier function plays a pivotal role in protection from inhaled particles. However, some nano-scaled particles, such as carbon nanotubes (CNT), have demonstrated the ability to penetrate this barrier in animal models, resulting in an unusual, rapid interstitial fibrosis. To delineate the underlying mechanism and specific bio-effect of inhaled nanoparticles in respiratory toxicity, models of lung epithelial barriers are required that allow accurate representation of in vivo systems; however, there is currently a lack of consistent methods to do so. Thus, this work demonstrates a well-characterized in vitro model of pulmonary barrier function using Calu-3 cells, and provides the experimental conditions required for achieving tight junction complexes in cell culture, with trans-epithelial electrical resistance measurement used as a biosensor for proper barrier formation and integrity. The effects of cell number and serum constituents have been examined and we found that changes in each of these parameters can greatly affect barrier formation. Our data demonstrate that use of 5.0 × 104 Calu-3 cells/well in the Transwell cell culture system, with 10% serum concentrations in culture media is optimal for assessing epithelial barrier function. In addition, we have utilized CNT exposure to analyze the dose-, time-, and nanoparticle property-dependent alterations of epithelial barrier permeability as a means to validate this model. Such high throughput in vitro cell models of the epithelium could be used to predict the interaction of other nanoparticles with lung epithelial barriers to mimic respiratory behavior in vivo, thus providing essential tools and bio-sensing techniques that can be uniformly employed.
topic Nanoparticles
Lung
In vitro model
Pulmonary barrier
Toxicology
url http://www.sciencedirect.com/science/article/pii/S2214180414000439
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