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Adverse Biophysical Effects of Hydroxyapatite Nanoparticles on Natural Pulmonary Surfactant

Inhaled nanoparticles (NPs) must first interact with the pulmonary surfactant (PS) lining layer that covers the entire internal surface of the respiratory tract and plays an important role in surface tension reduction and host defense. Interactions with the PS film determine the subsequent clearance...

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Published in:	ACS nano 2011-08, Vol.5 (8), p.6410-6416
Main Authors:	Fan, Qihui, Wang, Yi E, Zhao, Xinxin, Loo, Joachim S. C, Zuo, Yi Y
Format:	Article
Language:	English
Subjects:	Adsorption - drug effects Biological Products - chemistry Biological Products - metabolism Biophysical Phenomena - drug effects Bronchi - cytology Cell Survival - drug effects Cytotoxins - adverse effects Cytotoxins - chemistry Drug delivery systems Durapatite - adverse effects Durapatite - chemistry Epithelial Cells - cytology Epithelial Cells - drug effects Epithelial Cells - metabolism Epithelial Cells - ultrastructure Humans Hydroxyapatite Inhibition Nanoparticles Nanoparticles - adverse effects Nanostructure Phospholipids - chemistry Phospholipids - metabolism Pulmonary Surfactant-Associated Protein B - chemistry Pulmonary Surfactant-Associated Protein B - metabolism Pulmonary Surfactant-Associated Protein C - chemistry Pulmonary Surfactant-Associated Protein C - metabolism Pulmonary Surfactants - chemistry Pulmonary Surfactants - metabolism Surface chemistry Surface Properties Surfactants Toxicity Toxicity Tests Vesicles
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creator	Fan, Qihui Wang, Yi E Zhao, Xinxin Loo, Joachim S. C Zuo, Yi Y
description	Inhaled nanoparticles (NPs) must first interact with the pulmonary surfactant (PS) lining layer that covers the entire internal surface of the respiratory tract and plays an important role in surface tension reduction and host defense. Interactions with the PS film determine the subsequent clearance, retention, and translocation of the inhaled NPs and hence their potential toxicity. To date, little is known how NPs interact with PS, and whether or not NPs have adverse effects on the biophysical function of PS. We found a time-dependent toxicological effect of hydroxyapatite NPs (HA-NPs) on a natural PS, Infasurf, and the time scale of surfactant inhibition after particle exposure was comparable to the turnover period of surfactant metabolism. Using a variety of in vitro biophysicochemical characterization techniques, we have determined the inhibition mechanism to be due to protein adsorption onto the HA-NPs. Consequently, depletion of surfactant proteins from phospholipid vesicles caused conversion of original large vesicles into much smaller vesicles with poor surface activity. These small vesicles, in turn, inhibited biophysical function of surfactant films after adsorption at the air–water interface. Cytotoxicity study found that the HA-NPs at the studied concentration were benign to human bronchial epithelial cells, thereby highlighting the importance of evaluating biophysical effect of NPs on PS. The NP–PS interaction mechanism revealed by this study may not only provide new insight into the toxicological study of nanoparticles but also shed light on the feasibility of NP-based pulmonary drug delivery.
doi_str_mv	10.1021/nn2015997
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Using a variety of in vitro biophysicochemical characterization techniques, we have determined the inhibition mechanism to be due to protein adsorption onto the HA-NPs. Consequently, depletion of surfactant proteins from phospholipid vesicles caused conversion of original large vesicles into much smaller vesicles with poor surface activity. These small vesicles, in turn, inhibited biophysical function of surfactant films after adsorption at the air–water interface. Cytotoxicity study found that the HA-NPs at the studied concentration were benign to human bronchial epithelial cells, thereby highlighting the importance of evaluating biophysical effect of NPs on PS. 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Using a variety of in vitro biophysicochemical characterization techniques, we have determined the inhibition mechanism to be due to protein adsorption onto the HA-NPs. Consequently, depletion of surfactant proteins from phospholipid vesicles caused conversion of original large vesicles into much smaller vesicles with poor surface activity. These small vesicles, in turn, inhibited biophysical function of surfactant films after adsorption at the air–water interface. Cytotoxicity study found that the HA-NPs at the studied concentration were benign to human bronchial epithelial cells, thereby highlighting the importance of evaluating biophysical effect of NPs on PS. 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We found a time-dependent toxicological effect of hydroxyapatite NPs (HA-NPs) on a natural PS, Infasurf, and the time scale of surfactant inhibition after particle exposure was comparable to the turnover period of surfactant metabolism. Using a variety of in vitro biophysicochemical characterization techniques, we have determined the inhibition mechanism to be due to protein adsorption onto the HA-NPs. Consequently, depletion of surfactant proteins from phospholipid vesicles caused conversion of original large vesicles into much smaller vesicles with poor surface activity. These small vesicles, in turn, inhibited biophysical function of surfactant films after adsorption at the air–water interface. Cytotoxicity study found that the HA-NPs at the studied concentration were benign to human bronchial epithelial cells, thereby highlighting the importance of evaluating biophysical effect of NPs on PS. 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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	Adsorption - drug effects Biological Products - chemistry Biological Products - metabolism Biophysical Phenomena - drug effects Bronchi - cytology Cell Survival - drug effects Cytotoxins - adverse effects Cytotoxins - chemistry Drug delivery systems Durapatite - adverse effects Durapatite - chemistry Epithelial Cells - cytology Epithelial Cells - drug effects Epithelial Cells - metabolism Epithelial Cells - ultrastructure Humans Hydroxyapatite Inhibition Nanoparticles Nanoparticles - adverse effects Nanostructure Phospholipids - chemistry Phospholipids - metabolism Pulmonary Surfactant-Associated Protein B - chemistry Pulmonary Surfactant-Associated Protein B - metabolism Pulmonary Surfactant-Associated Protein C - chemistry Pulmonary Surfactant-Associated Protein C - metabolism Pulmonary Surfactants - chemistry Pulmonary Surfactants - metabolism Surface chemistry Surface Properties Surfactants Toxicity Toxicity Tests Vesicles
title	Adverse Biophysical Effects of Hydroxyapatite Nanoparticles on Natural Pulmonary Surfactant
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