In vivo clearance of nanoparticles by transcytosis across alveolar epithelial cells

Authors: Pascal Detampel ^aff001; Anutosh Ganguly ^aff002; Sara Tehranian ^aff004; Francis Green ^aff005; Santiswarup Singha ^aff002; Pere Santamaria ^aff002; Ayodeji A. Jeje ^aff004; Clifford S. Cho ^aff003; Björn Petri ^aff002; Matthias W. Amrein ^aff001
Authors place of work: Department of Cell Biology and Anatomy, University of Calgary, Calgary, Canada ^aff001; Department of Microbiology, Immunology and Infectious Diseases, University of Calgary, Calgary, Canada ^aff002; Department of Surgery, University of Michigan at Ann Arbor, Ann Arbor, Michigan, United States of America ^aff003; Department of Chemical and Petroleum Engineering, University of Calgary, Calgary, Canada ^aff004; Department Pathology & Laboratory Medicine, University of Calgary, Calgary, Canada ^aff005; The Snyder Institute for Chronic Diseases, University of Calgary, Calgary, Canada ^aff006
Published in the journal: PLoS ONE 14(9)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0223339

Summary

Nanoparticles in polluted air or aerosolized drug nanoparticles predominantly settle in the alveolar lung. Here, we describe a novel, highly effective pathway for the particles to cross the alveolar epithelium and reach the lymph and bloodstream. Amorphous silica nanoparticles, suspended in perfluorocarbon, were instilled into the lungs of mice for intravital microscopy. Particles formed agglomerates that settled on the alveolar wall, half of which were removed from the lung within 30 minutes. TEM histology showed agglomerates in stages of crossing the alveolar epithelium, in large compartments inside the epithelial cells and crossing the basal membrane into the interstitium. This pathway is consistent with published kinetic studies in rats and mice, using a host of (negatively) charged and polar nanoparticles.

Keywords:

Body weight – Pulmonary imaging – Epithelial cells – Epithelium – Fluorescence microscopy – Nanoparticles – Transmission electron microscopy – Alveolar macrophages

Introduction

Amorphous silica nanoparticles from natural sources [1] and at workplaces are common in ambient air. Upon breathing, the nanoparticles (<0.1 μm, also termed ultrafine particles) reach the alveolar region of the lung to an increasing extent with decreasing size and are mainly deposited in the alveolar region [2]. Unlike crystalline silica that can cause silicosis, chronic obstructive pulmonary disease (COPD), and lung cancer [3,4], amorphous silica is quickly cleared, potentially explaining why it has few if any pathologic effects [5]. A detailed kinetic study in rats using silica-coated as well as other radiolabeled nanoparticles reported a biphasic clearance from the lung with a t_1/2 of only 0.2–0.3 hours for the first phase and t_1/2 of 1.2 days for the second phase, leading to complete clearance [6]. Another study found a large range of nanoparticles with noncationic surface charges to be rapidly translocated from the lung lumen to the mediastinal lymph nodes [7]. The speed and efficiency of clearance for these particles are inconsistent with removal by alveolar macrophages [8] that takes weeks to years to complete [9,10]. As well, particles within macrophages leave the lung via the mucociliary pathway. For alveolar particles to rapidly reach the lymph and blood implies that they first cross the epithelium.

Here we show by intravital microscopy in mice how particles settle on the alveolar wall in agglomerates and are then removed from the area at a rate consistent with the published kinetics for these and similar nanoparticles. Electron microscopy of the lungs show the agglomerates in stages of crossing the alveolar epithelium: Particles adhered to the epithelium, inside the epithelial cells in large compartments, or in the interstitium. The process appears geared towards agglomerates but also occurs for individual particles. Note that agglomerates are the predominant form for nanoparticles in aerosols and in liquids [11].

The novel pathway, described in this paper, constitutes a key advance in understanding inhalation toxicology and clearance of nanoparticles. Considering access to the transepithelial pathway may also be relevant to inhalation drug design.

Materials and methods

Materials

Fluorescent (red and infrared, Table 1) amorphous silica particles of 50 nm in size were purchased from Kisker Biotech (Steinfurt, Germany). Silica nanoparticles with a size of 58 nm and silver core of 28 nm were obtained from nanoComposix (San Diego, USA). Nanopowder of titanium (IV) dioxide (contains 1% Mn as dopant, nanopowder, <100 nm particle size (BET), ≥97%), sodium azide (NaN₃), and 2-deoxy-D-glucose were purchased from Sigma-Aldrich (Oakville, Canada), perfluorocarbon FC-43 (PFC) was obtained from 3M (London, Canada).

Nanoparticles and concentrations used <i>in vivo</i>. — **Tab. 1. Nanoparticles and concentrations used *in vivo*.**

Intravital imaging

We adapted a protocol [12]. for inverted lung microscopy to now include partial liquid ventilation. Female C57BL/6 mice were obtained from Jackson Laboratories (Bar Harbor, ME) and used between 8 and 16 weeks of age. The entire protocol (no. AC13-0105) was approved by the University of Calgary Animal Care Committee. Mice were anesthetized with ketamine (150 μg/g body weight) and xylazine (10 μg/g body weight) i.p and the jugular vein was cannulated for further central access. Tracheotomy was performed and a ventilation cannula (outer diameter 1.2 mm, inner diameter 0.8 mm) was inserted into the trachea and secured around the lower front teeth with sutures. Inside the cannula, PE-10 tubing was inserted into the cannula to facilitate administration of nanoparticles, while, at the same time, ventilating the mouse. Ventilation was performed at 120 breaths per minute, a stroke volume of 200 μl, and a positive-end expiratory pressure (PEEP) of 3 cm H₂O. Mice were laid in the lateral decubitus position on the right side and the thorax was opened for direct access to the lung [12]. A thoracic suction window with a 12 mm coverslip (#1.5) was placed in a custom-built microscopy stage holder and the lung was restrained from moving with a vacuum of around 130 mm Hg. The mouse stage was turned upside down and placed on an inverted Nikon A1plus microscope on a 40x water-immersion objective (NA 1.15) with a resonance scanner. After focusing on a lung region, a z-stack was acquired without particles. Next, the lung was ventilated with pure oxygen for several minutes, ventilation stopped for 60 to 90 seconds until the alveolar space collapsed and particles (3.8 μg/g body weight particles, Table 1) in perfluorocarbon FC-43 (PFC) instilled through the PE-10 tubing directly into the lung.

The particles in PFC were prepared immediately before instillation as follows: an aqueous suspension of Ø 50 nm red fluorescent silica particle was emulsified in PFC by three consecutive sonication of 30 seconds each on ice, (Sonic Ruptor 250, Omni International, USA).

Z-Stacks were acquired at the indicated time points; all images were taken with Nikon NIS-Elements AR 4.20. Calculations were performed with ImageJ 1.50e and the “analyze particles” plugin. Stacks of images were merged for maximum intensity Z projection. The threshold was adjusted for the images prior to, and after, particle exposure according to Otsu [13], and the numbers and sizes of the agglomerates were analyzed. After background subtraction, the number and sizes of agglomerates were calculated following the initial settling at 2 minutes and every 10 minutes thereafter. For single plane analysis Renyi’s Entropy threshold was applied before analyzing.

In vivo preparation for transmission electron microscopy

Mice were anesthetized using 5% isoflurane and fluorescent amorphous silica particles of 50 nm or silica nanoparticles with a size of 58 nm and silver core of 28 nm were instilled into the trachea at concentrations described in Table 1. After 1 and 24 h, mice were euthanized with 22 mg/kg pentobarbital (Ceva, France). Samples of the lower left lobe of the lung were fixed in 2.5% gluteraldehyde, 1.6% formaldehyde in 0.1 M cacodylate buffer, pH 7.4 overnight. For TiO₂ samples were post-fixed in 1% osmium tetroxide buffered with cacodylate for 1 h for later analysis by transmission electron microscopy (TEM). After polymerization 70 nm thin vertical sections were cut from a representative area with cells (Ultracut E, Reichert-Jung, Vienna, Austria). Sections were stained with aqueous uranyl acetate and Reynolds’s lead citrate and observed under a Hitachi H-7650 TEM (Hitachi) at 80 kV with an AMT16000 digital camera (Advanced Microscopy Techniques, USA).

Whole organ imaging

Far-red fluorescent particles were instilled at 36 μg/g body weight. After 24 h liver, spleen and kidneys were collected. Images were acquired in a small animal imaging system (In-Vivo Xtreme 4MP, USA) at an excitation and emission wavelength of 730 and 790 nm, respectively and with a 5 seconds exposure time.

In vitro uptake studies

A549 (ATCC, Virginia, USA) were maintained in F12 (Gibco, USA) supplemented with 10% of fetal bovine serum (Gibco, USA), 2 mM L-Glutamine, and 10 mM Hepes (Life Technologies, Canada). 2–2.5 μg of 50 nm red fluorescent nanoparticles were added to a confluent monolayer of A549 in a 35 mm ibidi bottom dish for 1 h and then washed to remove unbound nanoparticles. Samples were then fixed and visualized by an ELYRA PS.1 inverted confocal microscope equipped with 63x 1.4NA objective (Zeiss, Germany). Stacks were recorded 0.3 μm apart from apical side to basolateral side. A representative plane near to the middle of the stack was chosen for mean fluorescence intensity (MFI) calculation and to ensure the particle was within the cell. By using imageJ MFI was calculated from five arbitrary areas within every cell and a minimum of 20 cells were counted to obtain mean fluorescence intensity/unit area (MFI/μm²). A minimum of four experiments were performed. Alternatively, we have also measured total fluorescence from a maximum intensity projection of all the optical sections. Both measurement strategies showed a similar result. Particle uptake for cells at the middle of the stack was quantified using the imageJ analyze particle plug-in.

Data and statistical analysis

All experiments were performed either in triplicate or as indicated in the figure legends. The results are described as mean ± standard deviation. Statistical analysis was performed by student's t-test and, where applicable, p-values were adjusted according to Bonferroni for multiple comparisons. Significant levels are indicated as * p < 0.05, ** p < 0.01, *** p < 0.001, and **** p < 0.0001. Statistical calculations and graphs were performed using either GraphPad Prism (version 5.0) or R software (version 3.5.1) [14] and the plot3D (version 1.1.1) package [15].

Results

To investigate particle clearance from the alveolar region in situ, in real time, we employed intravital microscopy. We used perfluorocarbon (PFC) to homogenously deliver dispersed nanoparticles to the peripheral lung. PFC also improved the microscopy (see “discussion”). During the microscopy, the animals were subjected to partial-liquid ventilation, a procedure that is not harmful [16,17].

For the microscopy, z-stacks of 60-μm depth were acquired before and directly after instillation of bright, exceptionally stable fluorescent nanoparticles (S1H Fig). Z-stacks were then acquird in intervals of at most ten minutes for one hour. The alveolar walls were easily identified due to their strong auto-fluorescent at 488 nm (maximum projection image, Fig 1A), a property previously exploited for lung imaging [18]. The instilled particles settled on the alveolar wall in agglomerates of variable size and shape (Fig 1C and 1D). Smaller agglomerates disappeared one-by-one from view whereas larger entities were gradually reduced in size (Fig 1E and 1F). For instance, arrows in Fig 1D indicate agglomerates that vanished or diminished in Fig 1F. Quantifying the number and area of agglomerates in the stack showed a reduction to about half after 30 minutes (Fig 2C), consistent with the published biokinetics for the initial phase of clearance [19]. A fraction of particle agglomerates remained stationary within the observation timeframe of one hour (Fig 2C), reflecting a second, slower phase of clearance, also found by Kreyling et al. [19].

**Fig. 1. Intravital lung imaging of silica nanoparticles in mice.**

Quantification of <i>in vivo</i> silica nanoparticle clearance. — **Fig. 2. Quantification of *in vivo* silica nanoparticle clearance.**

Next, we analyzed the z-stacks for movement of particles towards alveolar ducts over time (i.e. we analyzed whether particles agglomerates changed position within the alveolar lumen over the time of observation). This was not observed within the experimental timeframe (Fig 2A and 2B). Rather the agglomerates did not change their location when becoming reduced in size or before disappearing. We therefore hypothesized that the rapid phase of particle removal from the alveolar lumen occurs by crossing of the epithelium at the site of where particles have settled. Before investigating this hypothesis in mice, we tested as a control in vitro whether exposure to PFC affects particle interaction with the epithelium. A confluent layer of A549 alveolar epithelial cells was exposed to nanoparticles either dispersed in PFC or in media under fluorescent microscopy (S2A Fig). In both cases, the response of the cells to the particles was rapid endocytosis, with no significant difference between the two exposure types (S2B Fig). Further, we did not observe an increase of apoptotic cells under the microscope in our in vitro experiments.

To see if particles removed from the lung had become systemic, In-Vivo Xtreme 4MP whole-animal imaging was conducted. Results with entire animals were not achieved because of a high background against a low signal. However, after examining isolated organs, we found particle accumulation in the liver and kidneys 24 h after instillation (Fig 2D). This indicates that particles had become systemic. Renal- and hepatobiliary clearance has been shown for systemic silica nanoparticles, explaining their accumulation in the respective organs [6,20].

To investigate the alveolar epithelial crossing, we instilled particles in buffer suspension into the lungs of mice, euthanized them at either 1 h or 24 h after exposure, and prepared the lower left lobes of the lungs for transmission electron microscopy (TEM). We used a range of different particles and concentrations (Table 1). Following the 1 h exposure, nanoparticles were found in various stages of crossing the epithelium. The particles were mostly in agglomerates as described by Liu et al. [11] (see also S1E, S1F and S1G Fig). Agglomerates adhered to the apical side of the alveolar epithelium (Fig 3A), or were in the process of being internalized (Fig 3B). Some particles were also found entangled in the tubular myelin of surfactant (Fig 3F). Tubular myelin is the secretion form of pulmonary surfactant and is recognized by its fishnet appearance in TEM of lung sections. Agglomerates were also inside large, membrane-bound endosomal structures within type II epithelial cells (Fig 3C) and adherent to the apical- and basolateral side of alveolar type I cells (Fig 3D). However, they were not directly observed inside type I cells, possible because crossing of these very thin cells (of the order of a few times the diameter of the nanoparticles) is bound to be fast and unlikely to be observed by TEM. Finally, we observed particles in the lumen of pulmonary venules/arterioles (S3A and S3B Fig) indicating that they had crossed the endothelium to reach the blood stream. Another route for the particles to become systemic after crossing of the epithelium is via the lymph [7].

**Fig. 3. Electron micrographs of lung sections after instillation of 50 nm-silica nanoparticles into the lungs of mice (3.8 μg/g body weight).**

Interestingly, we also found alveolar macrophages with intracellular compartments of agglomerates (Fig 3F). Unlike epithelial cells, the agglomerates within macrophages were always associated with tubular myelin, suggesting that this might be required for macrophage phagocytosis (S4A and S4B Fig). Overall, macrophages were scarce within sections, and alveolar epithelial cells were the primary cells involved in processing of nanoparticles (Fig 3G). We did not observe an increase in macrophages or other inflammatory cells into the exposed lung regions or detect signs of edema or epithelial damage.

In conclusion, trans-epithelial clearance is an effective and fast path for silica nanoparticles to be removed from the lung. The process does not appear to cause lung injury.

To investigate the fate of particles that had not accessed the rapid transepithelial pathway, we exposed mice as described above and sacrificed them after 24 h. At this point, the particles overall were relatively scarce, as compared to the 1 h-time point. Remaining particles in the alveolar lumen were associated with tubular myelin. Size and morphology of the particles were no different for the 1 h- and the 24 h-timepoints, indicating that particles themselves were stable. There were no particles adherent to- or within epithelial cells (Fig 3I). Macrophages contained agglomerates of particles within large endocytic compartments (Fig 3H). These particles were always associated with tubular myelin.

For the TEM experiments, we used moderate to low particle concentrations as compared to reported mouse silica particle instillation experiments [21] (3.0–3.8 μg/g body weight, comparable to intravital microscopy). In addition, a dose ~20 times lower (0.15 μg/g body weight) was used to determine if the dose affects the nature of the clearance pathway. At this low dose, particles were more often found individually rather than in agglomerates. They were few and far between in TEM sections. Clearance appeared to follow the same path to the agglomerates formed at higher concentrations (Fig 4A–4D).

**Fig. 4. Electron micrographs of low dose exposure (0.15 μg/g body weight) of silica nanoparticles in the lungs of mice.**

To investigate if this pathway is relevant to other particle chemistries, we instilled TiO₂ nanoparticles of < 100 nm (1% Mn-doped). TiO₂ nanoparticles have an overall low toxicity [22]. Histology revealed a similar transport process across the lung epithelium as for amorphous silica (S3C Fig and S5A and S5B Fig).

In summary, amorphous silica and TiO₂ are cleared from the peripheral lung by rapidly crossing the alveolar epithelium. Alveolar macrophages internalized particles associated with tubular myelin.

Discussion

Inhaled nanoparticles are predominantly deposited in the alveolar region [2,23]. The current publication shows for silica and TiO₂ that nanoparticles may effectively be transcytosed across the alveolar epithelium to be cleared from the lung. We found that particles predominantly crossed as agglomerates which may have contributed to the efficiency of this pathway. This pathway has been predicted for the particle types used here as well as many other nanoparticles. Published biokinetics for noncationic synthetic nanoparticles, ZnO₂-, TiO₂- and silica-, among other nanoparticles indicates rapid and effective translocation from the alveolar lumen into the bloodstream [6,7]. Choi, et al [7] state:“…there is rapid transepithelial translocation of nanoparticles from the alveolar luminal surface into the septal interstitium, followed by quick translocation to the regional draining lymph nodes where further translocation into the bloodstream could occur…”. A review by Oberdörster et al. [10] describes passage via the lymph to the lung periphery close to the pleura [24].

Regarding intravital lung microscopy of the particle exposure, the use of PFC proved important. Intravital lung microscopy suffers from excessive movement during ventilation and light scattering at the air-tissue interface. Another problem, the procedure limits the observable lung to a small region that cannot be changed once the microscopy has commenced. Sucessful imaging therefore depends on a homogenous and reliable deposition of particles within the field of view. Particle exposure via an aqueous bolus is not well suited for intravital microscopy because the distal region of the lung under observation is often shut off from the exposure by trapped air. Using a particle emulsion in PFC (i.e. an aqueous suspension of particles is emulsified in PFC) solved these problems. When instilled, the dispersion filled up the entire airspaces of the lower lung regions owing to its low viscosity, very low surface tension, high density (twice that of water), and immiscibility with water. In addition to reliably carrying the particles into the field of view, PFC improved the microscopy because it matches the refractive index of the alveolar lumen to the tissue to reduce light scattering. The motion of breathing was also strongly reduced and allowed us to observe nanoparticles over an extended period of time. We note that PFC preserves the airway and alveolar structure including the surfactant layer at the air-tissue interface [9], the thin layer of alveolar fluid and the epithelium, without causing injury or affecting gas exchange. PFC emulsions have been successful for delivery of emulsified nanoparticulate drugs to the lungs [25] [26].

What is the significance of the rapid transcytosis mechanism described in the current paper for lung homeostasis? The lung-air interface must be clear of foreign objects to ensure unobstructed air flow, gas exchange and prevent inflammation. The nasal cavity or the trachea-bronchial tree trap and remove larger particles. Nanoparticles behave increasingly like gas molecules with decreasing size and therefore bypass these defence mechanisms and settle where gas exchange occurs, in the alveolar lung. Clearance of these particles via the lymph and the blood proved highly effective for the particle types studied. Inhaled nanoparticles, while predominantly deposited in the alveolar region, may also settle in the bronchi and bronchioles. It will be interesting to see whether these particles are cleared via the mucociliary escalator like larger particles or traverse the (airway) epithelium. We note that the mucus with particles will mostly enter the gastrointestinal tract from where they potentially also can become systemic.

Not all nanoparticles follow the pathway described here and will be the subject of future studies. For example, carbon particles from coal mining or cigarette smoke [27] may accumulate within the alveolar lumen resulting in emphysema. Particles that accumulate in the interstitium may induce pneumoconiosis [28]. As well, not all particles that reach the bloodstream will be cleared without causing damage, but be responsible for cardiovascular, renal or neural effects [29]. Another subject that warrants more research is the detailed cell-biology of the transcytosis mechanism.

In conclusion, the current paper contributes an essential pathway that aligns with the reported kinetics of lung clearance of a broad spectrum of nanoparticles [5–7]. In addition to the implications for nanoparticle toxicicty, understanding of the transepithelial pathway may may be important for the design of inhaled particulate drugs, broadening the spectrum of drugs that may be delivered via the lung. Therapeutic substances may include new peptide and protein drugs, where delivery via the lungs is particularly important because of the many limitations of other delivery modes [30–32].

Supporting information

S1 Fig [pbs]
Nanoparticle characterization.

S2 Fig [pfc]
nanoparticle uptake in perfluorocarbon.

S3 Fig [tif]
Silica and TiO nanoparticles transported in the bloodstream.

S4 Fig [tif]
Particle uptake in alveolar epithelial cells vs. macrophages.

S5 Fig [tif]
Titanium oxide nanoparticles cross the epithelium-like silica nanoparticles.

Zdroje

1. Tegen I, Heinold B, Todd M, Helmert J, Washington R, Dubovik O. Modelling soil dust aerosol in the Bodélé depression during the BoDEx campaign. Atmospheric Chemistry and Physics. 2006;6: 4345–4359.

2. Gehr P, Heyder J. Particle-Lung Interactions. 1st edition. New York, NY: Marcel Dekker Incorporated; 2000.

3. Merget R, Bauer T, Küpper H, Philippou S, Bauer H, Breitstadt R, et al. Health hazards due to the inhalation of amorphous silica. Arch Toxicol. 2002;75: 625–634. doi: 10.1007/s002040100266 11876495

4. U.S. EPA. Health effects of inhaled crystalline and amorphous silica [Internet]. 11 Apr 2000 [cited 8 Jan 2018]. Available: https://cfpub.epa.gov/si/si_public_record_Report.cfm?dirEntryId=12999&CFID=46400977&CFTOKEN=68103288&jsessionid=cc30d3874075a6729c38314d51639151e4f5

5. Fruijtier-Pölloth C. The toxicological mode of action and the safety of synthetic amorphous silica—A nanostructured material. Toxicology. 2012;294: 61–79. doi: 10.1016/j.tox.2012.02.001 22349641

6. Konduru NV, Murdaugh KM, Sotiriou GA, Donaghey TC, Demokritou P, Brain JD, et al. Bioavailability, distribution and clearance of tracheally-instilled and gavaged uncoated or silica-coated zinc oxide nanoparticles. Particle and Fibre Toxicology. 2014;11: 44. doi: 10.1186/s12989-014-0044-6 25183210

7. Choi HS, Ashitate Y, Lee JH, Kim SH, Matsui A, Insin N, et al. Rapid translocation of nanoparticles from the lung airspaces to the body. Nature Biotechnology. 2010;28: 1300. doi: 10.1038/nbt.1696 21057497

8. Lehnert BE. Pulmonary and thoracic macrophage subpopulations and clearance of particles from the lung. Environ Health Perspect. 1992;97: 17–46. doi: 10.1289/ehp.929717 1396454

9. Schürch S, Green FHY, Bachofen H. Formation and structure of surface films: captive bubble surfactometry. Biochimica et Biophysica Acta (BBA)—Molecular Basis of Disease. 1998;1408: 180–202. doi: 10.1016/S0925-4439(98)00067-2

10. Oberdörster G, Oberdörster E, Oberdörster J. Nanotoxicology: An Emerging Discipline Evolving from Studies of Ultrafine Particles. Environ Health Perspect. 2005;113: 823–839. doi: 10.1289/ehp.7339 16002369

11. Liu HH, Surawanvijit S, Rallo R, Orkoulas G, Cohen Y. Analysis of Nanoparticle Agglomeration in Aqueous Suspensions via Constant-Number Monte Carlo Simulation. Environ Sci Technol. 2011;45: 9284–9292. doi: 10.1021/es202134p 21916459

12. Looney MR, Thornton EE, Sen D, Lamm WJ, Glenny RW, Krummel MF. Stabilized imaging of immune surveillance in the mouse lung. Nature methods. 2011;8: 91–96. doi: 10.1038/nmeth.1543 21151136

13. Otsu N. A Threshold Selection Method from Gray-Level Histograms. IEEE Transactions on Systems, Man, and Cybernetics. 1979;9: 62–66. doi: 10.1109/TSMC.1979.4310076

14. R: The R Project for Statistical Computing [Internet]. [cited 11 Aug 2019]. Available: https://www.r-project.org/

15. Soetaert K. plot3D: Plotting Multi-Dimensional Data [Internet]. 2017. Available: https://CRAN.R-project.org/package=plot3D

16. Weis CM, Wolfson MR, Shaffer TH. Liquid-assisted Ventilation: Physiology and Clinica Application. Annals of Medicine. 1997;29: 509–517. doi: 10.3109/07853899709007475 9562517

17. Sarkar S, Paswan A, Prakas S. Liquid ventilation. Anesth Essays Res. 2014;8: 277–282. doi: 10.4103/0259-1162.143109 25886321

18. Thiberville L, Salaün M, Lachkar S, Dominique S, Moreno-Swirc S, Vever-Bizet C, et al. Human in vivo fluorescence microimaging of the alveolar ducts and sacs during bronchoscopy. Eur Respir J. 2009;33: 974–985. doi: 10.1183/09031936.00083708 19213792

19. Kreyling WG, Semmler-Behnke M, Takenaka S, Möller W. Differences in the biokinetics of inhaled nano- versus micron-sized particles. Acc Chem Res. 2013;46: 714–722. doi: 10.1021/ar300043r 22980029

20. Longmire M, Choyke PL, Kobayashi H. Clearance Properties of Nano-sized Particles and Molecules as Imaging Agents: Considerations and Caveats. Nanomedicine (Lond). 2008;3: 703–717. doi: 10.2217/17435889.3.5.703 18817471

21. Roursgaard M, Poulsen SS, Poulsen LK, Hammer M, Jensen KA, Utsunomiya S, et al. Time-response relationship of nano and micro particle induced lung inflammation. Quartz as reference compound. Hum Exp Toxicol. 2010;29: 915–933. doi: 10.1177/0960327110363329 20237177

22. Park H-G, Kim JI, Kang M, Yeo M-K. The effect of metal-doped TiO2 nanoparticles on zebrafish embryogenesis. Mol Cell Toxicol. 2014;10: 293–301. doi: 10.1007/s13273-014-0033-8

23. Geiser M, Kreyling WG. Deposition and biokinetics of inhaled nanoparticles. Part Fibre Toxicol. 2010;7: 2. doi: 10.1186/1743-8977-7-2 20205860

24. Johnston CJ, Finkelstein JN, Mercer P, Corson N, Gelein R, Oberdörster G. Pulmonary effects induced by ultrafine PTFE particles. Toxicol Appl Pharmacol. 2000;168: 208–215. doi: 10.1006/taap.2000.9037 11042093

25. Fernandes DA, Fernandes DD, Li Y, Wang Y, Zhang Z, Rousseau D, et al. Synthesis of Stable Multifunctional Perfluorocarbon Nanoemulsions for Cancer Therapy and Imaging. Langmuir. 2016;32: 10870–10880. doi: 10.1021/acs.langmuir.6b01867 27564412

26. Lehmler H-J. Perfluorocarbon compounds as vehicles for pulmonary drug delivery. Expert Opinion on Drug Delivery. 2007;4: 247–262. doi: 10.1517/17425247.4.3.247 17489652

27. Kuempel ED, Wheeler MW, Smith RJ, Vallyathan V, Green FHY. Contributions of dust exposure and cigarette smoking to emphysema severity in coal miners in the United States. Am J Respir Crit Care Med. 2009;180: 257–264. doi: 10.1164/rccm.200806-840OC 19423717

28. Husain M, Wu D, Saber AT, Decan N, Jacobsen NR, Williams A, et al. Intratracheally instilled titanium dioxide nanoparticles translocate to heart and liver and activate complement cascade in the heart of C57BL/6 mice. Nanotoxicology. 2015;9: 1013–1022. doi: 10.3109/17435390.2014.996192 25993494

29. Donaldson K, Brown D, Clouter A, Duffin R, MacNee W, Renwick L, et al. The pulmonary toxicology of ultrafine particles. J Aerosol Med. 2002;15: 213–220. doi: 10.1089/089426802320282338 12184871

30. Almeida AJ, Souto E. Solid lipid nanoparticles as a drug delivery system for peptides and proteins. Adv Drug Deliv Rev. 2007;59: 478–490. doi: 10.1016/j.addr.2007.04.007 17543416

31. de Kruijf W, Ehrhardt C. Inhalation delivery of complex drugs-the next steps. Curr Opin Pharmacol. 2017;36: 52–57. doi: 10.1016/j.coph.2017.07.015 28846876