Cellular uptake and localization of inhaled gold nanoparticles in lungs of mice with chronic obstructive pulmonary disease

BackgroundInhalative nanocarriers for local or systemic therapy are promising. Gold nanoparticles (AuNP) have been widely considered as candidate material. Knowledge about their interaction with the lungs is required, foremost their uptake by surface macrophages and epithelial cells.Diseased lungs are of specific interest, since these are the main recipients of inhalation therapy. We, therefore, used Scnn1b-transgenic (Tg) mice as a model of chronic obstructive pulmonary disease (COPD) and compared uptake and localization of inhaled AuNP in surface macrophages and lung tissue to wild-type (Wt) mice.MethodsScnn1b-Tg and Wt mice inhaled a 21-nm AuNP aerosol for 2 h. Immediately (0 h) or 24 h thereafter, bronchoalveolar lavage (BAL) macrophages and whole lungs were prepared for stereological analysis of AuNP by electron microscopy.ResultsAuNP were mainly found as singlets or small agglomerates of ≤ 100 nm diameter, at the epithelial surface and within lung-surface structures. Macrophages contained also large AuNP agglomerates (> 100 nm). At 0 h after aerosol inhalation, 69.2±4.9% AuNP were luminal, i.e. attached to the epithelial surface and 24.0±5.9% in macrophages in Scnn1b-Tg mice. In Wt mice, 35.3±32.2% AuNP were on the epithelium and 58.3±41.4% in macrophages. The percentage of luminal AuNP decreased from 0 h to 24 h in both groups. At 24 h, 15.5±4.8% AuNP were luminal, 21.4±14.2% within epithelial cells and 63.0±18.9% in macrophages in Scnn1b-Tg mice. In Wt mice, 9.5±5.0% AuNP were luminal, 2.2±1.6% within epithelial cells and 82.8±0.2% in macrophages. BAL-macrophage analysis revealed enhanced AuNP uptake in Wt animals at 0 h and in Scnn1b-Tg mice at 24 h, confirming less efficient macrophage uptake and delayed clearance of AuNP in Scnn1b-Tg mice.ConclusionsInhaled AuNP rapidly bound to the alveolar epithelium in both Wt and Scnn1b-Tg mice. Scnn1b-Tg mice showed less efficient AuNP uptake by surface macrophages and concomitant higher particle internalization by alveolar type I epithelial cells compared to Wt mice. This likely promotes AuNP depth translocation in Scnn1b-Tg mice, including enhanced epithelial targeting. These results suggest AuNP nanocarrier delivery as successful strategy for therapeutic targeting of alveolar epithelial cells and macrophages in COPD.

[1]  R. Shukla,et al.  Biocompatibility of gold nanoparticles and their endocytotic fate inside the cellular compartment: a microscopic overview. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[2]  I. Rahman,et al.  Oxidative stress in asthma and COPD: antioxidants as a therapeutic strategy. , 2006, Pharmacology & therapeutics.

[3]  L M Cruz-Orive,et al.  Efficiency of airway macrophage recovery by bronchoalveolar lavage in hamsters: a stereological approach. , 1995, The European respiratory journal.

[4]  J. Crapo,et al.  Allometric relationships of cell numbers and size in the mammalian lung. , 1992, American journal of respiratory cell and molecular biology.

[5]  W G Kreyling,et al.  Distribution Pattern of Inhaled Ultrafine Gold Particles in the Rat Lung , 2006, Inhalation toxicology.

[6]  Maureen R. Gwinn,et al.  Nanoparticles: Health Effects—Pros and Cons , 2006, Environmental health perspectives.

[7]  S. Hodge,et al.  Smoking alters alveolar macrophage recognition and phagocytic ability: implications in chronic obstructive pulmonary disease. , 2007, American journal of respiratory cell and molecular biology.

[8]  O. Schmid,et al.  Effects and uptake of gold nanoparticles deposited at the air-liquid interface of a human epithelial airway model. , 2010, Toxicology and applied pharmacology.

[9]  Wolfgang Kreyling,et al.  Ultrafine Particles Cross Cellular Membranes by Nonphagocytic Mechanisms in Lungs and in Cultured Cells , 2005, Environmental health perspectives.

[10]  Ja Chronic Obstructive Pulmonary Disease , 1986 .

[11]  Richard C Boucher,et al.  Increased airway epithelial Na+ absorption produces cystic fibrosis-like lung disease in mice , 2004, Nature Medicine.

[12]  Marianne Geiser,et al.  Update on macrophage clearance of inhaled micro- and nanoparticles. , 2010, Journal of aerosol medicine and pulmonary drug delivery.

[13]  S. Pokhrel,et al.  Gold nanoparticle aerosols for rodent inhalation and translocation studies , 2013, Journal of Nanoparticle Research.

[14]  W. Kreyling Lung deposition and biokinetics of inhaled nanoparticles , 2013 .

[15]  Gerhard Scheuch,et al.  Deposition, retention, and translocation of ultrafine particles from the central airways and lung periphery. , 2008, American journal of respiratory and critical care medicine.

[16]  W. Kreyling,et al.  Generation and characterization of stable, highly concentrated titanium dioxide nanoparticle aerosols for rodent inhalation studies , 2011 .

[17]  E K Fram,et al.  Morphometric characteristics of cells in the alveolar region of mammalian lungs. , 2015, The American review of respiratory disease.

[18]  D. Postma,et al.  Chronic obstructive pulmonary disease. , 2002, Clinical evidence.

[19]  W. Scherle,et al.  A simple method for volumetry of organs in quantitative stereology. , 1970, Mikroskopie.

[20]  Marianne Geiser,et al.  Deposition and biokinetics of inhaled nanoparticles , 2010, Particle and Fibre Toxicology.

[21]  Christian Mühlfeld,et al.  Translocation and cellular entering mechanisms of nanoparticles in the respiratory tract. , 2008, Swiss medical weekly.

[22]  E R Weibel,et al.  A simple tool for stereological assessment of digital images: the STEPanizer , 2011, Journal of microscopy.

[23]  Christian Mühlfeld,et al.  Quantitative evaluation of cellular uptake and trafficking of plain and polyethylene glycol-coated gold nanoparticles. , 2010, Small.

[24]  P. Valberg,et al.  Deposition of Aerosol in the Respiratory Tract1–3 , 2015 .

[25]  J. Heyder,et al.  Techniques for the Determination of Particle Deposition in Lungs of Hamsters , 1989 .

[26]  A. Livraghi,et al.  Development of chronic bronchitis and emphysema in beta-epithelial Na+ channel-overexpressing mice. , 2008, American journal of respiratory and critical care medicine.

[27]  G. W. Snedecor Statistical Methods , 1964 .

[28]  H. Kauczor,et al.  In vivo monitoring of cystic fibrosis-like lung disease in mice by volumetric computed tomography , 2011, European Respiratory Journal.

[29]  W. Kreyling,et al.  Biodistribution of inhaled gold nanoparticles in mice and the influence of surfactant protein D. , 2013, Journal of aerosol medicine and pulmonary drug delivery.

[30]  M. Mall Role of cilia, mucus, and airway surface liquid in mucociliary dysfunction: lessons from mouse models. , 2008, Journal of aerosol medicine and pulmonary drug delivery.

[31]  T. Mayhew,et al.  A novel quantitative method for analyzing the distributions of nanoparticles between different tissue and intracellular compartments. , 2007, Journal of aerosol medicine : the official journal of the International Society for Aerosols in Medicine.

[32]  P. Valberg,et al.  Deposition of aerosol in the respiratory tract. , 1979, The American review of respiratory disease.

[33]  L. Cruz-Orive,et al.  Does lack of Cftr gene lead to developmental abnormalities in the lung? , 2000, Experimental lung research.

[34]  C. Schultz,et al.  The ENaC-overexpressing mouse as a model of cystic fibrosis lung disease. , 2011, Journal of cystic fibrosis : official journal of the European Cystic Fibrosis Society.

[35]  A. Walch,et al.  Efficient internalization and intracellular translocation of inhaled gold nanoparticles in rat alveolar macrophages. , 2012, Nanomedicine.