Your search keyword '"Air–liquid interface"' showing total 1,271 results

151. Disease modeling following organoid-based expansion of airway epithelial cells.

Author

Eenjes, Evelien, van Riet, Sander, Kroon, Andre A., Slats, Annelies M., Khedoe, P. Padmini S. J., Munck, Anne Boerema-de, Kempen, Marjon Buscop-van, Ninaber, Dennis K., Reiss, Irwin K. M., Clevers, Hans, Rottier, Robbert J., and Hiemstra, Pieter S.

Subjects

*EPITHELIAL cells, *UNFOLDED protein response, *AIRWAY (Anatomy), *NOTCH effect, *CIGARETTE smoke

Abstract

Air-liquid interface (ALI) cultures are frequently used in lung research but require substantial cell numbers that cannot readily be obtained from patients. We explored whether organoid expansion [three-dimensional (3D)] can be used to establish ALI cultures from clinical samples with low epithelial cell numbers. Airway epithelial cells were obtained from tracheal aspirates (TA) from preterm newborns and from bronchoalveolar lavage (BAL) or bronchial tissue (BT) from adults. TA and BAL cells were 3D-expanded, whereas cells from BT were expanded in 3D and 2D. Following expansion, cells were cultured at ALI to induce differentiation. The impact of cell origin and 2D or 3D expansion was assessed with respect to 1) cellular composition, 2) response to cigarette smoke exposure, and 3) effect of Notch inhibition or IL-13 stimulation on cellular differentiation. We established well-differentiated ALI cultures from all samples. Cellular compositions (basal, ciliated, and goblet cells) were comparable. All 3D-expanded cultures showed a similar stress response following cigarette smoke exposure but differed from the 2D-expanded cultures. Higher peak levels of antioxidant genes HMOX1 and NQO1 and a more rapid return to baseline, and a lower unfolded protein response was observed after cigarette smoke exposure in 3D-derived cultures compared to 2D-derived cultures. In addition, TA- and BAL-derived cultures were less sensitive to modulation by DAPT or IL-13 than BT-derived cultures. Organoid-based expansion of clinical samples with low cell numbers, such as TA from preterm newborns is a valid method and tool to establish ALI cultures. [ABSTRACT FROM AUTHOR]

Published

2021

152. Improved SARS-CoV-2 Spike Glycoproteins for Pseudotyping Lentiviral Vectors

Author

Paul G. Ayoub, Arunima Purkayastha, Jason Quintos, Curtis Tam, Lindsay Lathrop, Kevin Tam, Marlene Ruiz, Roger P. Hollis, Brigitte N. Gomperts, and Donald B. Kohn

Subjects

SARS-CoV-2, pseudotype, COVID-19, lentivirus, air-liquid interface, Microbiology, QR1-502

Abstract

The spike (S) glycoprotein of SARS-Cov-2 facilitates viral entry into target cells via the cell surface receptor angiotensin-converting enzyme 2 (ACE2). Third generation HIV-1 lentiviral vectors can be pseudotyped to replace the native CD4 tropic envelope protein of the virus and thereby either limit or expand the target cell population. We generated a modified S glycoprotein of SARS-Cov-2 to pseudotype lentiviral vectors which efficiently transduced ACE2-expressing cells with high specificity and contain minimal off-target transduction of ACE2 negative cells. By utilizing optimized codons, modifying the S cytoplasmic tail domain, and including a mutant form of the spike protein, we generated an expression plasmid encoding an optimized protein that produces S-pseudotyped lentiviral vectors at an infectious titer (TU/mL) 1000-fold higher than the unmodified S protein and 4 to 10-fold more specific than the widely used delta-19 S-pseudotyped lentiviral vectors. S-pseudotyped replication-defective lentiviral vectors eliminate the need for biosafety-level-3 laboratories required when developing therapeutics against SARS-CoV-2 with live infectious virus. Furthermore, S-pseudotyped vectors with high activity and specificity may be used as tools to understand the development of immunity against SARS-CoV-2, to develop assays of neutralizing antibodies and other agents that block viral binding, and to allow in vivo imaging studies of ACE2-expressing cells.

Published

2021

153. Interactions between O2 Nanobubbles and the Pulmonary Surfactant in the Presence of Inhalation Medicines

Author

Katarzyna Dobrowolska, Marcin Odziomek, Karol Ulatowski, Weronika Kędziora, Karolina Soszyńska, Paweł Sobieszuk, and Tomasz R. Sosnowski

Subjects

interfacial rheology, dispersion of oxygen nanobubbles, pulmonary surfactant, air–liquid interface, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

A dispersion of oxygen nanobubbles (O2-NBs) is an extraordinary gas–liquid colloidal system where spherical gas elements can be considered oxygen transport agents. Its conversion into inhalation aerosol by atomization with the use of nebulizers, while maintaining the properties of the dispersion, gives new opportunities for its applications and may be attractive as a new concept in treating lung diseases. The screening of O2-NBs interactions with lung fluids is particularly needed in view of an O2-NBs application as a promising aerosol drug carrier with the additional function of oxygen supplementation. The aim of the presented studies was to investigate the influence of O2-NBs dispersion combined with the selected inhalation drugs on the surface properties of two types of pulmonary surfactant models (lipid and lipid–protein model). The characteristics of the air–liquid interface were carried out under breathing-like conditions using two selected tensiometer systems: Langmuir–Wilhelmy trough and the oscillating droplet tensiometer. The results indicate that the presence of NBs has a minor effect on the dynamic characteristics of the air–liquid interface, which is the desired effect in the context of a potential use in inhalation therapies.

Published

2022

154. Gene transfer vector development to treat lung disease : the use of a dual-function lentiviral vector containing ENaC RNAi and the CFTR gene to treat Cystic Fibrosis lung disease

Author

Harding-Smith, Rebekka, Gill, Deborah, and Hyde, Stephen

Subjects

616.2, Gene therapy, Lung disease, RNA interference, shRNA, shRNAmir, CFTR, Epithelial sodium channel, ENaC, Lentivirus, Air-liquid interface, Cystic fibrosis

Abstract

Cystic Fibrosis (CF) is a degenerative disorder that is often associated with chronic lung disease. CF is caused by mutations in the gene encoding the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) chloride channel, which lead to defective chloride and sodium ion movement across epithelia. Subsequent dehydration of the airway surface liquid (ASL) on airway epithelia, is associated with poor mucociliary clearance and chronic lung infection. The monogenic nature of CF, along with the accessibility of the lung, makes the disease amenable to gene replacement therapy. Gene therapy clinical trials have focused on replacing the mutated CFTR with a functional copy, which has led to improved chloride transport, but has shown no significant effects on sodium transport. An alternative strategy for CF gene therapy therefore, could be to reduce the expression of the epithelial sodium channel (ENaC) in the lung, using RNA interference (RNAi), combined with CFTR delivery. Developing a dual-function gene transfer vector could potentially restore chloride and sodium levels in the ASL and help alleviate CF lung disease. The aim of this thesis was to develop a recombinant lentivirus delivery system capable of simultaneously delivering CFTR expression and knocking down ENaC expression in the airways. A modular HIV vector genome plasmid was developed to allow simple insertion of various promoter elements, transgenes and knockdown sequences, for subsequent virus production. Insertion of the CFTR transgene and a short-hairpin RNA (shRNA) sequence targeting the ENaC alpha subunit (ENaCα) resulted in significant knockdown of human ENaCα and simultaneous expression of CFTR in A549 (human lung carcinoma) cell culture. Replacement of the ENaCα shRNA with an shRNA targeting the transcription factor BACH1 resulted in target gene knockdown and concomitant HMOX1 up-regulation, confirming specific knockdown effects, and demonstrating that the dual-function rLV vector could mediate target gene knockdown irrespective of the target. Attempts were made to knock down BACH1 in primary cultures of human bronchial epithelial cells grown at the air-liquid interface (ALI), but improved transduction efficiencies from the apical surface will be required to generate successful knockdown in this experimental model. These studies provide proof-of-principle for the utility of this versatile dual-function prototype virus. The dual function vector not only has the potential for treatment of CF lung disease, but could be readily altered to target other lung diseases where combinations of prolonged target gene knockdown and gene expression/up-regulation could collectively provide an appropriate therapy. In conclusion, the focus on the rational design of gene transfer vectors for specific therapeutic effects will aid the development and translation of gene therapy approaches to human studies.

Published

2014

155. Air−Liquid Interface Cultures of the Healthy and Diseased Human Respiratory Tract: Promises, Challenges, and Future Directions

Author

Domizia Baldassi, Bettina Gabold, and Olivia M. Merkel

Subjects

air-liquid interface, lung, pulmonary administration, respiratory tract, SARS Cov-2, 3D co-culture models, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Air−liquid interface (ALI) culture models currently represent a valid instrument to recreate the typical aspects of the respiratory tract in vitro in both healthy and diseased state. They can help reducing the number of animal experiments, and hence support the 3R principle. This review discusses ALI cultures and co‐cultures derived from immortalized as well as primary cells, which are used to study the most common disorders of the respiratory tract, in terms of both pathophysiology and drug screening. The article displays ALI models used to simulate inflammatory lung diseases such as chronic obstructive pulmonary disease (COPD), asthma, cystic fibrosis, lung cancer, and viral infections. It also focuses on ALI cultures described in literature studying respiratory viruses such as SARS‐CoV‐2 causing the global Covid‐19 pandemic at the time of writing this review. Additionally, commercially available models of ALI cultures are presented. Ultimately, the aim of this review is to provide a detailed overview of ALI models currently available and to critically discuss them in the context of the most prevalent diseases of the respiratory tract.

Published

2021

156. Cytotoxicity analysis of biomass combustion particles in human pulmonary alveolar epithelial cells on an air–liquid interface/dynamic culture platform.

Author

Ke, Shaorui, Liu, Qi, Zhang, Xinlian, Yao, Yuhan, Yang, Xudong, and Sui, Guodong

Subjects

BIOMASS burning, EPITHELIAL cells, INDOOR air pollution, AIR pollutants, SCANNING electron microscopes, CHEMICAL-looping combustion, LUNGS

Abstract

Background: Exposure to indoor air pollution from solid fuel combustion is associated with lung diseases and cancer. This study investigated the cytotoxicity and molecular mechanisms of biomass combustion-derived particles in human pulmonary alveolar epithelial cells (HPAEpiC) using a platform that combines air–liquid interface (ALI) and dynamic culture (DC) systems. Methods: HPAEpiC were cultured on the surface of polycarbonate (PC) membranes on the ALI–DC platform. The cells were sprayed with an aerosolized solution of biomass combustion soluble constituents (BCSCs) and simultaneously nourished with culture medium flowing beneath the permeable PC membranes. The ALI–DC method was compared with the traditional submerged culture approach. BCSC particle morphology and dosages deposited on the chip were determined for particle characterization. Flow cytometry, scanning electron microscopy, and transmission electron microscopy were used to investigate the apoptosis rate of HPAEpiC and changes in the cell ultrastructure induced by BCSCs. Additionally, the underlying apoptotic pathway was examined by determining the protein expression levels by western blotting. Results: Scanning electron microscope images demonstrated that the sample processing and delivering approach of the ALI–DC platform were suitable for pollutant exposure. Compared with the submerged culture method, a significant decline in cell viability and increase in apoptosis rate was observed after BCSC exposure on the ALI–DC platform, indicating that the ALI–DC platform is a more sensitive system for investigating cytotoxicity of indoor air pollutants in lung cells. The morphology and ultrastructure of the cells were damaged after exposure to BCSCs, and the p53 pathway was activated. The Bcl-2/Bax ratio was reduced, upregulating caspase-9 and caspase-3 expression and subsequently inducing apoptosis of HPAEpiC. The addition of N-acetyl cysteine antioxidant significantly alleviated the cytotoxicity induced by BCSCs. Conclusion: A novel ALI–DC platform was developed to study the cytotoxicity of air pollutants on lung cells. Using the platform, we demonstrated that BCSCs could damage the mitochondria, produce reactive oxygen species, and activate p53 in HPAEpiC, ultimately inducing apoptosis. [ABSTRACT FROM AUTHOR]

Published

2021

157. Understanding Viral Infection and Lifecycle with Single Cell Transcriptomics

Author

Jung, Kyle Lawrence

Subjects

Bioinformatics, Biology, Molecular Biology, Virology, virus, viral infection, Severe Fever with Thrombocytopenia Syndrome Virus, Kaposi’s Sarcoma-Associated Herpesvirus, single cell RNA sequencing, air-liquid interface, epithelial differentation, viral reactivation

Abstract

Understanding the viral infection and lifecycle of Severe Fever with Thrombocytopenia Syndrome Virus (SFTSV) and Kaposi’s Sarcoma-Associated Herpesvirus (KSHV) is important in improving disease outcomes and reducing viral prevalence. In our SFTSV study, we discovered specific cytokine profiles associated with the severity of clinical symptoms. We used single cell RNA sequencing (scRNAseq) on patient blood samples to identify a unique expansion of the B cell population in SFTSV-induced fatal cases which indicated that plasma B cells are a primary reservoir of SFSTV replication. These findings present a potential method of reducing the severity of SFTSV infection, especially in aged patients who are more susceptible to adverse outcomes.In our KSHV study, we developed a novel oral 3D infection model and demonstrated that KSHV can only infect exposed basal epithelial cells in the oral epithelia. We used scRNAseq to show that keratinocyte differentiation and cell death pathways were affected by KSHV infection, suggesting that epithelial differentiation could contribute to KSHV reactivation through changes in epigenetic regulation. In addition, we found a unique population of infected cells with limited early lytic gene expression and a unique gene expression profile, which we termed latent-2 cells. These findings demonstrate that our in vitro 3D epithelial ALI culture model should be a valuable tool to further understand oral KSHV infection for the development of future anti-viral therapeutics to block KSHV transmission.

Published

2024

158. Novel air-liquid interface culture model to investigate stiffness-dependent behaviors of alveolar epithelial cells.

Author

Takahashi, Yuto, Ito, Satoru, Wang, Jungfeng, Kim, Jeonghyun, Matsumoto, Takeo, and Maeda, Eijiro

Subjects

*EPITHELIAL cells, *PULMONARY alveoli, *INTERSTITIAL lung diseases, *CELL morphology, *CELL size, *GAS exchange in plants

Abstract

Pulmonary alveoli are functional units in gas exchange in the lung, and their dysfunctions in lung diseases such as interstitial pneumonia are accompanied by fibrotic changes in structure, elevating the stiffness of extracellular matrix components. The present study aimed to test the hypothesis that such changes in alveoli stiffness induce functional alteration of epithelial cell functions, exacerbating lung diseases. For this, we have developed a novel method of culturing alveolar epithelial cells on polyacrylamide gel with different elastic modulus at an air-liquid interface. It was demonstrated that A549 cells on soft gels, mimicking the modulus of a healthy lung, upregulated mRNA expression and protein synthesis of surfactant protein C (SFTPC). By contrast, the cells on stiff gels, mimicking the modulus of the fibrotic lung, exhibited upregulation of SFTPC gene expression but not at the protein level. Cell morphology, as well as cell nucleus volume, were also different between the two types of gels. • Stiffness-dependent regulation of alveolar epithelial cell (A549) function was studied. • Novel air-liquid interface culture model was developed using polyacrylamide gel. • Soft and stiff gels mimicked elastic modulus of healthy and fibrotic lung tissues. • Soft gel selectively induced type II alveolar epithelial cell functions. • Stiff environments induced non-physiological epithelial functions. [ABSTRACT FROM AUTHOR]

Published

2024

159. The decreased interface tension increased the transmembrane transport of soy hull polysaccharide-derived SCFAs in the Caco-2 cells.

Author

Li, Li, Xia, Mingjie, Yang, Lina, He, Yutang, Liu, He, Xie, Mengxi, and Yu, Miao

Subjects

*SHORT-chain fatty acids, *NUCLEAR transport, *STRUCTURE-activity relationships, *OXIDATIVE phosphorylation, *INTERFACIAL bonding, *POLYSACCHARIDES

Abstract

Polysaccharides impact intestinal fermentation and regulate interfacial properties which affect absorption and transportation. Short-chain fatty acids (SCFAs), the main metabolites of soy hull polysaccharide lysate, are readily absorbed by the body and perform various physiological functions. We analysed the interfacial properties and transport of soy hull polysaccharide-derived SCFAs in the Caco-2 cell model to clarify the transmembrane transport mechanism. The results showed that the interfacial properties of the co-culture system were influenced by both transit time and concentration of SCFAs, the uptake and transit rates of SCFAs at 1–3 h increased significantly with time (P < 0.05). With increasing transit time and concentration, the transit rates of SCFAs on the apical side (AP) → basolateral side (BL) and BL → AP sides increased and then stabilised, the transit rate of the AP → BL side was higher than that of the BL → AP side. Proteomic analysis showed that soy hull polysaccharide-derived SCFAs resulted in the differential expression of 285 upregulated and 501 downregulated after translocation across Caco-2 cells. The differentially expressed proteins were mainly enriched in ribosomes, oxidative phosphorylation, nuclear transport, and SNARE vesicular transport. This study lays the theoretical foundation for understanding the structure-activity relationship of soy hull polysaccharides in the intestine. [ABSTRACT FROM AUTHOR]

Published

2024

160. The role of suspended biomass in PFAS enrichment in wastewater treatment foams.

Author

We, Angel Chyi En, Stickland, Anthony D., Clarke, Bradley O., and Freguia, Stefano

Subjects

*FLUOROALKYL compounds, *WASTEWATER treatment, *SEWAGE disposal plants, *FOAM, *AIR injection of groundwater, *BIOMASS

Abstract

• Long-chain PFAS enrichment occurred in aerated bioreactors' foams. • Low to marginal enrichment was observed for short-chain PFAS. • PFAS enrichment was observed in both aqueous and solid phases of foamates. • PFAS sorption to the solid phase of foamates should be accounted. • Further investigations for foam fractionation implementation at WWTPs are needed. Foaming in aerated bioreactors at wastewater treatment plants (WWTPs) has been identified as an operational issue for decades. However, the affinity of per- and polyfluoroalkyl substances (PFAS) for air-liquid interfaces suggests that foam harvesting has the potential to become a sustainable method for PFAS removal from sewage. Aerated bioreactors' foams are considered three-phase systems, comprising air, aqueous and solid components, the latter consisting of activated sludge biomass. To achieve a comprehensive understanding of the capability of aerated bioreactors' foams to enrich PFAS, we analysed PFAS concentrations from WWTPs in both the solid and aqueous phases of the collapsed foams (foamate) and underlying bulk mixed liquors. Our findings show that PFAS enrichment occurs not only in the aqueous phase but also in the solid phase of the foamate. This suggests that previous field studies that only analysed the aqueous phase may have underestimated the capability of the aerated bioreactors' foams to enrich PFAS. Fractions of PFOA and PFOS sorbed to the solid phase of the foamate can be as high as 60 % and 95 %, respectively. Our findings highlight the importance of implementing effective foamate management strategies that consider both the aqueous and solid phases. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

161. Organization of malonamides from the interface to the organic bulk phase.

Author

Micheau, Cyril, Ueda, Yuki, Motokawa, Ryuhei, Akutsu-Suyama, Kazuhiro, Yamada, Norifumi L., Yamada, Masako, Moussaoui, Sayed Ali, Makombe, Elizabeth, Meyer, Daniel, Berthon, Laurence, and Bourgeois, Damien

Subjects

*SMALL-angle neutron scattering, *SMALL-angle X-ray scattering, *LIQUID-liquid interfaces, *NEUTRON reflectivity, *X-ray scattering, *MALONAMIDES, *INTERFACIAL tension

Abstract

Dense interfacial layer in n -heptane leads to rapid extraction compared to diffuse interfacial layer in toluene. [Display omitted] • Selectivity and kinetics in solvent extraction were explained by supramolecular organization of malonamide extractants. • Supramolecular organization of malonamide extractants is strongly related to diluent polar character. • Extractant dimers are highly selective for Pd(II) over Nd(III) ion in toluene. • Extractant large aggregates do not display specific selectivity for Pd(II) or Nd(III) ions in n -heptane. Supramolecular organization of amphiphilic extractant molecules is involved in metal cation selectivity and separation kinetics during solvent extraction. The relationship between extractant associates/aggregates formed in the organic bulk phase and at the liquid–liquid interface is poorly understood even though it affects the extraction mechanism. The nanoscopic structures of the extraction systems N , N , N′ , N′ -tetrahexylmalonamide (THMA) in toluene and N , N′ -dibutyl- N , N′ -dimethyl-2-tetradecylmalonamide (DBMA) in n -heptane, used for either Pd(II) or Nd(III) selective extraction from an acidic aqueous phase, were examined. These systems present markedly different affinity for Pd(II) and Nd(III), and extraction kinetics. Extractant organization in the organic bulk phase and at the interface were compared by small-angle X-ray scattering, interfacial tension, and neutron reflectivity. THMA in toluene forms small associates in the organic bulk phase and accumulates in a diffuse layer at the interface, decreasing Pd(II) coordination probability and resulting in slow extraction. DBMA in n -heptane forms large aggregates and a compact, dense interfacial layer, resulting in rapid Pd(II) and Nd(III) extraction. Thus, Pd(II) extraction is driven by interfacial coordination alone, whereas the incorporation of Nd(III) into the core of large aggregates governs Nd(III) extraction in the interfacial layer. These results suggest that the interface should be described as a nanoscale interphase containing a high extractant concentration compared with the organic bulk phase. [ABSTRACT FROM AUTHOR]

Published

2024

162. Acute exposure to seasonal PM2.5 induces toxicological responses in A549 cells cultured at the air-liquid interface mediated by oxidative stress and endoplasmic reticulum stress.

Author

Chen, Wankang, Ge, Pengxiang, Lu, Zhenyu, Liu, Xiaoming, Cao, Maoyu, Yan, Zhansheng, and Chen, Mindong

Subjects

*OXIDATIVE stress, *ENDOPLASMIC reticulum, *PARTICULATE matter, *DNA repair, *POISONS, *HUMAN body

Abstract

Atmospheric fine particulate matter (PM 2.5) enters the human body through respiration and poses a threat to human health. This is not only dependent on its mass concentration in the atmosphere, but also related to seasonal variations in its chemical components, which makes it important to study the cytotoxicity of PM 2.5 in different seasons. Traditional immersion exposure cannot simulate the living environment of human epithelial cells in the human body, making this method unsuitable for evaluating the inhalation toxicity of PM 2.5. In this study, a novel air-liquid interface (ALI) particulate matter exposure device (VITROCELL Cloud 12 system) was used to evaluate the toxic effects and potential mechanisms of human lung epithelial cells (A549) after exposure to seasonal PM 2.5. PM 2.5 samples from four seasons were collected and analyzed for chemical components. After 6 h of exposure to seasonal PM 2.5 , winter PM 2.5 exhibited the highest cytotoxicity among most toxicity indicators, especially apoptosis rate, reactive oxygen species (ROS), inflammatory responses and DNA damage (γ-H2AX). The effect of autumn PM 2.5 on apoptosis rate was significantly higher than that in spring, and there was no significant difference in other toxicity indicators between spring and autumn. The cytotoxicity of summer PM 2.5 was the lowest among the four seasons. It should be noted that even exposure to low doses of summer PM 2.5 leads to significant DNA damage in A459 cells. Correlation analysis results showed that water-soluble ions, metallic elements, and polycyclic aromatic hydrocarbons (PAHs) were associated with most toxicological endpoints. Inhibitors of oxidative stress and endoplasmic reticulum (ER) stress significantly inhibited cellular damage, indicating that PM 2.5 -induced cytotoxicity may be related to the generation of ROS and ER stress. In addition, PM 2.5 can induce ER stress through oxidative stress, which ultimately leads to apoptosis. [Display omitted] • Winter PM 2.5 causes more severe cytotoxicity and oxidative damage than other seasons. • Low-dose PM 2.5 acute exposure can also cause DNA damage in A549 cells. • PM 2.5 -induced cytotoxicity was associated with oxidative stress and ER stress. • PM 2.5 can induce ER stress through oxidative stress, which ultimately leads to apoptosis. [ABSTRACT FROM AUTHOR]

Published

2024

163. Diesel exhaust particle exposure exacerbates ciliary and epithelial barrier dysfunction in the multiciliated bronchial epithelium models.

Author

Park, Eunsook, Kim, Bu-Yeo, Lee, Seahyoung, Son, Kuk Hui, Bang, Jihye, Hong, Se Hyang, Lee, Joong Won, Uhm, Kyung-Ok, Kwak, Hyun-Jeong, and Lim, Hyun Joung

Subjects

RESPIRATORY organs, LUNGS, MUCOCILIARY system, EPITHELIUM, GENE expression profiling, INFLAMMATORY mediators, EPITHELIAL cells

Abstract

Airway epithelium, the first defense barrier of the respiratory system, facilitates mucociliary clearance against inflammatory stimuli, such as pathogens and particulates inhaled into the airway and lung. Inhaled particulate matter 2.5 (PM 2.5) can penetrate the alveolar region of the lung, and it can develop and exacerbate respiratory diseases. Although the pathophysiological effects of PM 2.5 in the respiratory system are well known, its impact on mucociliary clearance of airway epithelium has yet to be clearly defined. In this study, we used two different 3D in vitro airway models, namely the EpiAirway-full-thickness (FT) model and a normal human bronchial epithelial cell (NHBE)-based air-liquid interface (ALI) system, to investigate the effect of diesel exhaust particles (DEPs) belonging to PM 2.5 on mucociliary clearance. RNA-sequencing (RNA-Seq) analyses of EpiAirway-FT exposed to DEPs indicated that DEP-induced differentially expressed genes (DEGs) are related to ciliary and microtubule function and inflammatory-related pathways. The exposure to DEPs significantly decreased the number of ciliated cells and shortened ciliary length. It reduced the expression of cilium-related genes such as acetylated α-tubulin, ARL13B, DNAH5, and DNAL1 in the NHBEs cultured in the ALI system. Furthermore, DEPs significantly increased the expression of MUC5AC, whereas they decreased the expression of epithelial junction proteins, namely, ZO1, Occludin, and E-cadherin. Impairment of mucociliary clearance by DEPs significantly improved the release of epithelial-derived inflammatory and fibrotic mediators such as IL-1β, IL-6, IL-8, GM-CSF, MMP-1, VEGF, and S100A9. Taken together, it can be speculated that DEPs can cause ciliary dysfunction, hyperplasia of goblet cells, and the disruption of the epithelial barrier, resulting in the hyperproduction of lung injury mediators. Our data strongly suggest that PM2.5 exposure is directly associated with ciliary and epithelial barrier dysfunction and may exacerbate lung injury. • DEP exposure affects gene expression profiles of cilium movement and organization. • DEPs shorten cilia length and cause mucus hypersecretion. • DEPs induce inflammatory and fibrotic mediators. • DEP-mediated ciliary and epithelial barrier damage may aggravate lung injury. [ABSTRACT FROM AUTHOR]

Published

2024

164. Characterization and applicability of a novel physiologically relevant 3D-tetraculture bronchial model for in vitro assessment of respiratory sensitization.

Author

da Silva, Artur Christian Garcia, de Mendonça, Izadora Caroline Furtado, and Valadares, Marize Campos

Subjects

*ALLERGENS, *MALEIC anhydride, *RESPIRATORY allergy, *REACTIVE oxygen species, *EPITHELIAL cells, *BRONCHIAL spasm

Abstract

Chemical Respiratory Allergy (CRA) is triggered after exposure to Low Molecular Weight (LMW) sensitizers and manifests clinically as asthma and rhinitis. From a risk/toxicity assessment point of view, there are few methods, none of them validated, for evaluating the respiratory sensitization potential of chemicals once the in vivo -based models usually employed for inhalation toxicity addressment do not comprise allergenicity endpoints specifically. Based on that, we developed, characterized, and evaluated the applicability of a 3D-tetraculture airway model reconstructed with bronchial epithelial, fibroblasts, endothelial and monocytic cell lines. Moreover, we exposed the tissue to maleic anhydride (MA) aerosols to challenge the model and subsequently assessed inflammatory and functional aspects of the tissue. The reconstructed tissue presented phenotypic biomarkers compatible with human bronchial epithelium, and MA aerosol exposure triggered an increased IL-8 and IL-6 production, reactive oxygen species (ROS) formation, and apoptosis of epithelial cells. Besides, augmented IL-8 production by monocytic cells was also found, correlating with dendritic cell activation within the co-culture model after MA exposure. Our results demonstrated that the 3D-tetraculture bronchial model presents hallmarks related to human airways' structure and function. Additionally, exposure to a respiratory sensitizer induced inflammatory and functional alterations in the reconstructed tissue, rendering it a valuable tool for exploring the mechanistic framework of chemically induced respiratory sensitization. [ABSTRACT FROM AUTHOR]

Published

2024

165. Perfusion culture maintained with an air-liquid interface to stimulate epithelial cell organization in renal organoids in vitro

Author

Sachiko Sekiya, Tetsutaro Kikuchi, and Tatsuya Shimizu

Subjects

Renal organoid, Perfusion culture, Air-liquid interface, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Abstract Background Organoids derived from induced pluripotent stem (iPS) or embryonic stem (ES) cells have been evaluated as in vitro models of development and disease. However, maintaining these cells under long-term static culture conditions is difficult because of nutrition shortages and waste accumulation. To overcome these issues, perfusion culture systems are required for organoid technology. A system with a stable microenvironment, nutrient availability, and waste removal will accelerate organoid generation. The aim of this study was to develop a novel perfusion system for renal organoids by maintaining the air-liquid interface with a device fabricated using a 3D printer. Results Our results revealed slow flow at the organoid cultivation area based on microbead movement on the membrane, which depended on the perfusion rate under the membrane. Moreover, the perfused culture medium below the organoids via a porous membrane diffused throughout the organoids, maintaining the air-liquid interface. The diffusion rates within organoids were increased according to the flow rate of the culture medium under the membrane. The perfused culture medium also stimulated cytoskeletal and basement membrane re-organization associated with promotion tubular formation under 2.5 μL/min flow culture. In contrast, tubules in organoids were diminished at a flow rate of 10 μL/min. Conclusions Our liquid-air interface perfusion system accelerated organization of the renal organoids. These results suggest that suitable perfusion conditions can accelerate organization of epithelial cells and tissues in renal organoids in vitro.

Published

2019

166. Azithromycin induces epidermal differentiation and multivesicular bodies in airway epithelia

Author

Ari Jon Arason, Jon Petur Joelsson, Bryndis Valdimarsdottir, Snaevar Sigurdsson, Alexander Gudjonsson, Skarphedinn Halldorsson, Freyr Johannsson, Ottar Rolfsson, Fredrik Lehmann, Saevar Ingthorsson, Paulina Cherek, Gudmundur H. Gudmundsson, Fridrik R. Gardarsson, Clive P. Page, Olafur Baldursson, Thorarinn Gudjonsson, and Jennifer A. Kricker

Subjects

Azithromycin, Air-liquid interface, Gene expression, Airway, Epithelia, Epidermal differentiation, Diseases of the respiratory system, RC705-779

Abstract

Abstract Background Azithromycin (Azm) is a macrolide recognized for its disease-modifying effects and reduction in exacerbation of chronic airway diseases. It is not clear whether the beneficial effects of Azm are due to its anti-microbial activity or other pharmacological actions. We have shown that Azm affects the integrity of the bronchial epithelial barrier measured by increased transepithelial electrical resistance. To better understand these effects of Azm on bronchial epithelia we have investigated global changes in gene expression. Methods VA10 bronchial epithelial cells were treated with Azm and cultivated in air-liquid interface conditions for up to 22 days. RNA was isolated at days 4, 10 and 22 and analyzed using high-throughput RNA sequencing. qPCR and immunostaining were used to confirm key findings from bioinformatic analyses. Detailed assessment of cellular changes was done using microscopy, followed by characterization of the lipidomic profiles of the multivesicular bodies present. Results Bioinformatic analysis revealed that after 10 days of treatment genes encoding effectors of sterol and cholesterol metabolism were prominent. Interestingly, expression of genes associated with epidermal barrier differentiation, KRT1, CRNN, SPINK5 and DSG1, increased significantly at day 22. Together with immunostaining, these results suggest an epidermal differentiation pattern. We also found that Azm induced the formation of multivesicular and lamellar bodies in two different airway epithelial cell lines. Lipidomic analysis revealed that Azm was entrapped in multivesicular bodies linked to different types of lipids, most notably palmitate and stearate. Furthermore, targeted analysis of lipid species showed accumulation of phosphatidylcholines, as well as ceramide derivatives. Conclusions Taken together, we demonstrate how Azm might confer its barrier enhancing effects, via activation of epidermal characteristics and changes to intracellular lipid dynamics. These effects of Azm could explain the unexpected clinical benefit observed during Azm-treatment of patients with various lung diseases affecting barrier function.

Published

2019

167. In vitro exposure of a 3D-tetraculture representative for the alveolar barrier at the air-liquid interface to silver particles and nanowires

Author

Ionel Fizeșan, Sébastien Cambier, Elisa Moschini, Aline Chary, Inge Nelissen, Johanna Ziebel, Jean-Nicolas Audinot, Tom Wirtz, Marcin Kruszewski, Anca Pop, Béla Kiss, Tommaso Serchi, Felicia Loghin, and Arno C. Gutleb

Subjects

Air-liquid interface, Tetra-culture, Silver nanoparticles, Silver nanowires, Inflammation, Toxicology. Poisons, RA1190-1270, Industrial hygiene. Industrial welfare, HD7260-7780.8

Abstract

Abstract Background The present study aimed to evaluate the potential differences in the biological effects of two types of spherical silver particles of 20 and 200 nm (Ag20 and Ag200), and of PVP-coated silver nanowires (AgNWs) with a diameter of 50 nm and length up to 50 μm, using a complex 3D model representative for the alveolar barrier cultured at air-liquid interface (ALI). The alveolar model was exposed to 0.05, 0.5 and 5 μg/cm2 of test compounds at ALI using a state-of-the-art exposure system (Vitrocell™Cloud System). Endpoints related to the oxidative stress induction, anti-oxidant defence mechanisms, pro-inflammatory responses and cellular death were selected to evaluate the biocompatibility of silver particles and nanowires (AgNMs) and to further ascribe particular biological effects to the different morphologic properties between the three types of AgNMs evaluated. Results Significant cytotoxic effect was observed for all three types of AgNMs at the highest tested doses. The increased mRNA levels of the pro-apoptotic gene CASP7 suggests that apoptosis may occur after exposure to AgNWs. All three types of AgNMs increased the mRNA level of the anti-oxidant enzyme HMOX-1 and of the metal-binding anti-oxidant metallothioneins (MTs), with AgNWs being the most potent inducer. Even though all types of AgNMs induced the nuclear translocation of NF-kB, only AgNWs increased the mRNA level of pro-inflammatory mediators. The pro-inflammatory response elicited by AgNWs was further confirmed by the increased secretion of the 10 evaluated interleukins. Conclusion In the current study, we demonstrated that the direct exposure of a complex tetra-culture alveolar model to different types of AgNMs at ALI induces shape- and size-specific biological responses. From the three AgNMs tested, AgNWs were the most potent in inducing biological alterations. Starting from 50 ng/cm2, a dose representative for an acute exposure in a high exposure occupational setting, AgNWs induced prominent changes indicative for a pro-inflammatory response. Even though the acute responses towards a dose representative for a full-lifetime exposure were also evaluated, chronic exposure scenarios at low dose are still unquestionably needed to reveal the human health impact of AgNMs during realistic conditions.

Published

2019

168. Impacts of cellulase deactivation at the moving air–liquid interface on cellulose conversions at low enzyme loadings

Author

Samarthya Bhagia, Charles E. Wyman, and Rajeev Kumar

Subjects

Cellulose, Cellulase, Deactivation, Hydrolysis, Air–liquid interface, Gas–liquid interface, Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract Background We recently confirmed that the deactivation of T. reesei cellulases at the air–liquid interface reduces microcrystalline cellulose conversion at low enzyme loadings in shaken flasks. It is one of the main causes for lowering of cellulose conversions at low enzyme loadings. However, supplementing cellulases with small quantities of surface-active additives in shaken flasks can increase cellulose conversions at low enzyme loadings. It was also shown that cellulose conversions at low enzyme loadings can be increased in unshaken flasks if the reactions are carried for a longer time. This study further explores these recent findings to better understand the impact of air–liquid interfacial phenomena on enzymatic hydrolysis of cellulose contained in Avicel, Sigmacell, α-cellulose, cotton linters, and filter paper. The impacts of solids and enzyme loadings, supplementation with nonionic surfactant Tween 20 and xylanases, and application of different types of mixing and reactor designs on cellulose hydrolysis were also evaluated. Results Avicel cellulose conversions at high solid loading were more than doubled by minimizing loss of cellulases to the air–liquid interface. Maximum cellulose conversions were high for surface-active supplemented shaken flasks or unshaken flasks because of low cellulase deactivation at the air–liquid interface. The nonionic surfactant Tween 20 was unable to completely prevent cellulase deactivation in shaken flasks and only reduced cellulose conversions at unreasonably high concentrations. Conclusions High dynamic interfacial areas created through baffles in reactor vessels, low volumes in high-capacity vessels, or high shaking speeds severely limited cellulose conversions at low enzyme loadings. Precipitation of cellulases due to aggregation at the air–liquid interface caused their continuous deactivation in shaken flasks and severely limited solubilization of cellulose.

Published

2019

169. Gene Expression Profiling of Mono- and Co-Culture Models of the Respiratory Tract Exposed to Crystalline Quartz under Submerged and Air-Liquid Interface Conditions

Author

Alexandra Friesen, Susanne Fritsch-Decker, Matthias Hufnagel, Sonja Mülhopt, Dieter Stapf, Carsten Weiss, and Andrea Hartwig

Subjects

quartz, pulmonary toxicity, air-liquid interface, co-culture, transcriptional toxicity profile, gene expression, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

In vitro lung cell models like air-liquid interface (ALI) and 3D cell cultures have advanced greatly in recent years, being especially valuable for testing advanced materials (e.g., nanomaterials, fibrous substances) when considering inhalative exposure. Within this study, we established submerged and ALI cell culture models utilizing A549 cells as mono-cultures and co-cultures with differentiated THP-1 (dTHP-1), as well as mono-cultures of dTHP-1. After ALI and submerged exposures towards α-quartz particles (Min-U-Sil5), with depositions ranging from 15 to 60 µg/cm2, comparison was made with respect to their transcriptional cellular responses employing high-throughput RT-qPCR. A significant dose- and time-dependent induction of genes coding for inflammatory proteins, e.g., IL-1A, IL-1B, IL-6, IL-8, and CCL22, as well as genes associated with oxidative stress response such as SOD2, was observed, even more pronounced in co-cultures. Changes in the expression of similar genes were more pronounced under submerged conditions when compared to ALI exposure in the case of A549 mono-cultures. Hereby, the activation of the NF-κB signaling pathway and the NLRP3 inflammasome seem to play an important role. Regarding genotoxicity, neither DNA strand breaks in ALI cultivated cells nor a transcriptional response to DNA damage were observed. Altogether, the toxicological responses depended considerably on the cell culture model and exposure scenario, relevant to be considered to improve toxicological risk assessment.

Published

2022

170. Advanced Respiratory Models for Hazard Assessment of Nanomaterials—Performance of Mono-, Co- and Tricultures

Author

Laura Maria Azzurra Camassa, Elisabeth Elje, Espen Mariussen, Eleonora Marta Longhin, Maria Dusinska, Shan Zienolddiny-Narui, and Elise Rundén-Pran

Subjects

3D lung model, air–liquid interface, nanotoxicology, NM-300K, tricultures, Chemistry, QD1-999

Abstract

Advanced in vitro models are needed to support next-generation risk assessment (NGRA), moving from hazard assessment based mainly on animal studies to the application of new alternative methods (NAMs). Advanced models must be tested for hazard assessment of nanomaterials (NMs). The aim of this study was to perform an interlaboratory trial across two laboratories to test the robustness of and optimize a 3D lung model of human epithelial A549 cells cultivated at the air–liquid interface (ALI). Potential change in sensitivity in hazard identification when adding complexity, going from monocultures to co- and tricultures, was tested by including human endothelial cells EA.hy926 and differentiated monocytes dTHP-1. All models were exposed to NM-300K in an aerosol exposure system (VITROCELL® cloud-chamber). Cyto- and genotoxicity were measured by AlamarBlue and comet assay. Cellular uptake was investigated with transmission electron microscopy. The models were characterized by confocal microscopy and barrier function tested. We demonstrated that this advanced lung model is applicable for hazard assessment of NMs. The results point to a change in sensitivity of the model by adding complexity and to the importance of detailed protocols for robustness and reproducibility of advanced in vitro models.

Published

2022

171. Comparing α-Quartz-Induced Cytotoxicity and Interleukin-8 Release in Pulmonary Mono- and Co-Cultures Exposed under Submerged and Air-Liquid Interface Conditions

Author

Alexandra Friesen, Susanne Fritsch-Decker, Matthias Hufnagel, Sonja Mülhopt, Dieter Stapf, Andrea Hartwig, and Carsten Weiss

Subjects

quartz, pulmonary toxicity, air-liquid interface, co-culture, cytotoxicity, inflammation, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The occupational exposure to particles such as crystalline quartz and its impact on the respiratory tract have been studied extensively in recent years. For hazard assessment, the development of physiologically more relevant in-vitro models, i.e., air-liquid interface (ALI) cell cultures, has greatly progressed. Within this study, pulmonary culture models employing A549 and differentiated THP-1 cells as mono-and co-cultures were investigated. The different cultures were exposed to α-quartz particles (Min-U-Sil5) with doses ranging from 15 to 66 µg/cm2 under submerged and ALI conditions and cytotoxicity as well as cytokine release were analyzed. No cytotoxicity was observed after ALI exposure. Contrarily, Min-U-Sil5 was cytotoxic at the highest dose in both submerged mono- and co-cultures. A concentration-dependent release of interleukin-8 was shown for both exposure types, which was overall stronger in co-cultures. Our findings showed considerable differences in the toxicological responses between ALI and submerged exposure and between mono- and co-cultures. A substantial influence of the presence or absence of serum in cell culture media was noted as well. Within this study, the submerged culture was revealed to be more sensitive. This shows the importance of considering different culture and exposure models and highlights the relevance of communication between different cell types for toxicological investigations.

Published

2022

172. Protective Abilities of an Inhaled DPI Formulation Based on Sodium Hyaluronate against Environmental Hazards Targeting the Upper Respiratory Tract

Author

Juhura G. Almazi, Dina M. Silva, Valentina Trotta, Walter Fiore, Hui X. Ong, and Daniela Traini

Subjects

dry powder inhaler, barrier, protection, air-liquid interface, sodium hyaluronate, Pharmacy and materia medica, RS1-441

Abstract

The exposure of lung epithelium to environmental hazards is linked to several chronic respiratory diseases. We assessed the ability of an inhaled dry powder (DPI) medical device product (PolmonYDEFENCE/DYFESATM, SOFAR SpA, Trezzano Rosa, Italy), using a formulation of sodium hyaluronate (Na-Hya) as the key ingredient as a defensive barrier to protect the upper respiratory tract. Specifically, it was evaluated if the presence of the barrier formed by sodium hyaluronate present on the cells, reducing direct contact of the urban dust (UD) with the surface of cells can protect them in an indirect manner by the inflammatory and oxidative process started in the presence of the UD. Cytotoxicity and the protection capability against the oxidative stress of the product were tested in vitro using Calu-3 cells exposure to UD as a trigger for oxidative stress. Inflammation and wound healing were assessed using an air-liquid interface (ALI) culture model of the Calu-3 cells. Deposition studies of the formulation were conducted using a modified Anderson cascade impactor (ACI) and the monodose PillHaler® dry powder inhaler (DPI) device, Na-Hya was detected and quantified using high-performance-liquid-chromatography (HPLC). Solubilised PolmonYDEFENCE/DYFESATM gives protection against oxidative stress in Calu-3 cells in the short term (2 h) without any cytotoxic effects. ALI culture experiments, testing the barrier-forming (non-solubilised) capabilities of PolmonYDEFENCE/DYFESATM, showed that the barrier layer reduced inflammation triggered by UD and the time for wound closure compared to Na-Hya alone. Deposition experiments using the ACI and the PillHaler® DPI device showed that the majority of the product was deposited in the upper part of the respiratory tract. Finally, the protective effect of the product was efficacious for up to 24 h without affecting mucus production. We demonstrated the potential of PolmonYDEFENCE/DYFESATM as a preventative barrier against UD, which may aid in protecting the upper respiratory tract against environmental hazards and help with chronic respiratory diseases.

Published

2022

173. Intracellular accumulation dynamics and fate of zinc ions in alveolar epithelial cells exposed to airborne ZnO nanoparticles at the air–liquid interface

Author

Orr, Galya [Pacific Northwest National Lab. (PNNL), Richland, WA (United States). Environmental Molecular Sciences Lab.]

Published

2013

174. A Custom-Made Device for Reproducibly Depositing Pre-metered Doses of Nebulized Drugs on Pulmonary Cells in vitro

Author

Justus C. Horstmann, Chelsea R. Thorn, Patrick Carius, Florian Graef, Xabier Murgia, Cristiane de Souza Carvalho-Wodarz, and Claus-Michael Lehr

Subjects

inhalation, aerosol, pulmonary drug delivery, epithelial cells, air–liquid interface, Biotechnology, TP248.13-248.65

Abstract

The deposition of pre-metered doses (i.e., defined before and not after exposition) at the air–liquid interface of viable pulmonary epithelial cells remains an important but challenging task for developing aerosol medicines. While some devices allow quantification of the deposited dose after or during the experiment, e.g., gravimetrically, there is still no generally accepted way to deposit small pre-metered doses of aerosolized drugs or pharmaceutical formulations, e.g., nanomedicines. Here, we describe a straightforward custom-made device, allowing connection to commercially available nebulizers with standard cell culture plates. Designed to tightly fit into the approximately 12-mm opening of either a 12-well Transwell® insert or a single 24-well plate, a defined dose of an aerosolized liquid can be directly deposited precisely and reproducibly (4.8% deviation) at the air–liquid interface (ALI) of pulmonary cell cultures. The deposited dose can be controlled by the volume of the nebulized solution, which may vary in a range from 20 to 200 μl. The entire nebulization-deposition maneuver is completed after 30 s and is spatially homogenous. After phosphate-buffered saline (PBS) deposition, the viability and barrier properties transepithelial electrical resistance (TEER) of human bronchial epithelial Calu-3 cells were not negatively affected. Straightforward in manufacture and use, the device enables reproducible deposition of metered doses of aerosolized drugs to study the interactions with pulmonary cell cultures grown at ALI conditions.

Published

2021

175. Toxicological effects of zinc oxide nanoparticle exposure: an in vitro comparison between dry aerosol air-liquid interface and submerged exposure systems.

Author

Lovén, Karin, Dobric, Julia, Bölükbas, Deniz A., Kåredal, Monica, Tas, Sinem, Rissler, Jenny, Wagner, Darcy E., and Isaxon, Christina

Subjects

*AEROSOLS, *OCCUPATIONAL exposure, *TITANIUM dioxide nanoparticles, *CELL suspensions, *TOXICITY testing, *MICROBIOLOGICAL aerosols, *EPITHELIAL cells, *ZINC oxide

Abstract

Engineered nanomaterials (ENMs) are increasingly produced and used today, but health risks due to their occupational airborne exposure are incompletely understood. Traditionally, nanoparticle (NP) toxicity is tested by introducing NPs to cells through suspension in the growth media, but this does not mimic respiratory exposures. Different methods to introduce aerosolized NPs to cells cultured at the air-liquid-interface (ALI) have been developed, but require specialized equipment and are associated with higher cost and time. Therefore, it is important to determine whether aerosolized setups induce different cellular responses to NPs than traditional ones, which could provide new insights into toxicological responses of NP exposure. This study evaluates the response of human alveolar epithelial cells (A549) to zinc oxide (ZnO) NPs after dry aerosol exposure in the Nano Aerosol Chamber for In Vitro Toxicity (NACIVT) system as compared to conventional, suspension-based exposure: cells at ALI or submerged. Similar to other studies using nebulization of ZnO NPs, we found that dry aerosol exposure of ZnO NPs via the NACIVT system induced different cellular responses as compared to conventional methods. ZnO NPs delivered at 1.0 µg/cm2 in the NACIVT system, mimicking occupational exposure, induced significant increases in metabolic activity and release of the cytokines IL-8 and MCP-1, but no differences were observed using traditional exposures. While factors associated with the method of exposure, such as differing NP aggregation, may contribute toward the different cellular responses observed, our results further encourage the use of more physiologically realistic exposure systems for evaluating airborne ENM toxicity. [ABSTRACT FROM AUTHOR]

Published

2021

176. Assessment of Benchmark Dose in BEAS-2B Cells by Evaluating the Cell Relative Viability with Particulates in Motorcycle Exhaust via the Air-liquid Interface Exposure.

Author

YU, Tao, ZHANG, Xue Yan, LI, Shu Fei, ZHOU, Yu Mei, LI, Bin, WANG, Zhong Xu, DAI, Yu Fei, ADAMSON, Sherleen Xue-Fu, ZHENG, Yu Xin, and BIN, Ping

Subjects

CELL survival, MOTORCYCLES, MOTORCYCLING, EPITHELIAL cells, SURFACE area, OCHRATOXINS

Abstract

This study aimed to use an air–liquid interface (ALI) exposure system to simulate the inhalation exposure of motorcycle exhaust particulates (MEPs) and then investigate the benchmark dose (BMD) of MEPs by evaluating cell relative viability (CRV) in lung epithelial BEAS-2B cells. The MEPs dose was characterized by measuring the number concentration (NC), surface area concentration (SAC), and mass concentration (MC). BEAS-2B cells were exposed to MEPs at different concentrations via ALI and CRV was determined using Cell Counting Kit (CCK-8) assay. BMD software was applied to calculate BMD and the lower limit of benchmark dose (BMDL) according to Akaike Information Coefficient (AIC), with P-value based on Hill, Linear, Polynomial, and Power model. Our results reveal that BMD of NC and SAC were estimated by the best-fitting Hill model, while MC was estimated by Polynomial model. The BMDL for CRV following ALI exposure to MEPs were as follows: 364.2#/cm3 for NC; 0.662 × 107 nm2/cm3 for SAC; and 0.278 μg/m3 for MC. These results indicate that MEPs exposure via ALI system induces a dose-dependent decrease of CRV and provides the potential exposure threshold of MEPs in a lung cell model. [ABSTRACT FROM AUTHOR]

Published

2021

177. Responsiveness of human bronchial fibroblasts and epithelial cells from asthmatic and non-asthmatic donors to the transforming growth factor-β1 in epithelial-mesenchymal trophic unit model.

Author

Paw, Milena, Wnuk, Dawid, Jakieła, Bogdan, Bochenek, Grażyna, Sładek, Krzysztof, Madeja, Zbigniew, and Michalik, Marta

Subjects

*TRANSFORMING growth factors, *BRONCHIAL spasm, *EPITHELIAL cells, *FIBROBLASTS, *EPITHELIAL cell culture, *EPITHELIAL-mesenchymal transition, *EIGENFUNCTIONS

Abstract

Background: The asthma-related airway wall remodeling is associated i.a. with a damage of bronchial epithelium and subepithelial fibrosis. Functional interactions between human bronchial epithelial cells and human bronchial fibroblasts are known as the epithelial-mesenchymal trophic unit (EMTU) and are necessary for a proper functioning of lung tissue. However, a high concentration of the transforming growth factor-β1 (TGF-β1) in the asthmatic bronchi drives the structural disintegrity of epithelium with the epithelial-to-mesenchymal transition (EMT) of the bronchial epithelial cells, and of subepithelial fibrosis with the fibroblast-to-myofibroblast transition (FMT) of the bronchial fibroblasts. Since previous reports indicate different intrinsic properties of the human bronchial epithelial cells and human bronchial fibroblasts which affect their EMT/FMT potential beetween cells derived from asthmatic and non-asthmatic patients, cultured separatelly in vitro, we were interested to see whether corresponding effects could be obtained in a co-culture of the bronchial epithelial cells and bronchial fibroblasts. In this study, we investigate the effects of the TGF-β1 on the EMT markers of the bronchial epithelial cells cultured in the air-liquid-interface and effectiveness of FMT in the bronchial fibroblast populations in the EMTU models. Results: Our results show that the asthmatic co-cultures are more sensitive to the TGF-β1 than the non-asthmatic ones, which is associated with a higher potential of the asthmatic bronchial cells for a profibrotic response, analogously to be observed in '2D' cultures. They also indicate a noticeable impact of human bronchial epithelial cells on the TGF-β1-induced FMT, stronger in the asthmatic bronchial fibroblast populations in comparison to the non-asthmatic ones. Moreover, our results suggest the protective effects of fibroblasts on the structure of the TGF-β1–exposed mucociliary differentiated bronchial epithelial cells and their EMT potential. Conclusions: Our data are the first to demonstrate a protective effect of the human bronchial fibroblasts on the properties of the human bronchial epithelial cells, which suggests that intrinsic properties of not only epithelium but also subepithelial fibroblasts affect a proper condition and function of the EMTU in both normal and asthmatic individuals. [ABSTRACT FROM AUTHOR]

Published

2021

178. Oxygenation as a driving factor in epithelial differentiation at the air–liquid interface.

Author

Kouthouridis, Sonya, Goepp, Julie, Martini, Carolina, Matthes, Elizabeth, Hanrahan, John W, and Moraes, Christopher

Subjects

EPITHELIAL cells, OXYGENATION (Chemistry), PHENOTYPES, PARAMETERS (Statistics), MONOMOLECULAR films

Abstract

Culture at the air–liquid interface is broadly accepted as necessary for differentiation of cultured epithelial cells towards an in vivo-like phenotype. However, air–liquid interface cultures are expensive, laborious and challenging to scale for increased throughput applications. Deconstructing the microenvironmental parameters that drive these differentiation processes could circumvent these limitations, and here we hypothesize that reduced oxygenation due to diffusion limitations in liquid media limits differentiation in submerged cultures; and that this phenotype can be rescued by recreating normoxic conditions at the epithelial monolayer, even under submerged conditions. Guided by computational models, hyperoxygenation of atmospheric conditions was applied to manipulate oxygenation at the monolayer surface. The impact of this rescue condition was confirmed by assessing protein expression of hypoxia-sensitive markers. Differentiation of primary human bronchial epithelial cells isolated from healthy patients was then assessed in air–liquid interface, submerged and hyperoxygenated submerged culture conditions. Markers of differentiation, including epithelial layer thickness, tight junction formation, ciliated surface area and functional capacity for mucociliary clearance, were assessed and found to improve significantly in hyperoxygenated submerged cultures, beyond standard air–liquid interface or submerged culture conditions. These results demonstrate that an air–liquid interface is not necessary to produce highly differentiated epithelial structures, and that increased availability of oxygen and nutrient media can be leveraged as important strategies to improve epithelial differentiation for applications in respiratory toxicology and therapeutic development. [ABSTRACT FROM AUTHOR]

Published

2021

179. Pulmonary Surfactant and Drug Delivery: An Interface-Assisted Carrier to Deliver Surfactant Protein SP-D Into the Airways

Author

Cristina García-Mouton, Alberto Hidalgo, Raquel Arroyo, Mercedes Echaide, Antonio Cruz, and Jesús Pérez-Gil

Subjects

pulmonary surfactant, interfacial delivery, respiratory drug delivery, air-liquid interface, lipid-protein interaction, Biotechnology, TP248.13-248.65

Abstract

This work is focused on the potential use of pulmonary surfactant to deliver full-length recombinant human surfactant protein SP-D (rhSP-D) using the respiratory air-liquid interface as a shuttle. Surfactant protein D (SP-D) is a collectin protein present in the pulmonary surfactant (PS) system, involved in innate immune defense and surfactant homeostasis. It has been recently suggested as a potential therapeutic to alleviate inflammatory responses and lung diseases in preterm infants suffering from respiratory distress syndrome (RDS) or bronchopulmonary dysplasia (BPD). However, none of the current clinical surfactants used for surfactant replacement therapy (SRT) to treat RDS contain SP-D. The interaction of SP-D with surfactant components, the potential of PS as a respiratory drug delivery system and the possibility to produce recombinant versions of human SP-D, brings the possibility of delivering clinical surfactants supplemented with SP-D. Here, we used an in vitro setup that somehow emulates the respiratory air-liquid interface to explore this novel approach. It consists in two different compartments connected with a hydrated paper bridge forming a continuous interface. We firstly analyzed the adsorption and spreading of rhSP-D alone from one compartment to another over the air-liquid interface, observing low interfacial activity. Then, we studied the interfacial spreading of the protein co-administered with PS, both at different time periods or as a mixed formulation, and which oligomeric forms of rhSP-D better traveled associated with PS. The results presented here demonstrated that PS may transport rhSP-D long distances over air-liquid interfaces, either as a mixed formulation or separately in a close window time, opening the doors to empower the current clinical surfactants and SRT.

Published

2021

180. Aerosol–Cell Exposure System Applied to Semi-Adherent Cells for Aerosolization of Lung Surfactant and Nanoparticles Followed by High Quality RNA Extraction

Author

Mélanie M. Leroux, Romain Hocquel, Kevin Bourge, Boštjan Kokot, Hana Kokot, Tilen Koklič, Janez Štrancar, Yaobo Ding, Pramod Kumar, Otmar Schmid, Bertrand H. Rihn, Luc Ferrari, and Olivier Joubert

Subjects

air–liquid interface, nanoparticles, VITROCELL® Cloud System, RNA extraction, macrophages, surfactant, Chemistry, QD1-999

Abstract

Nanoparticle toxicity assessments have moved closer to physiological conditions while trying to avoid the use of animal models. An example of new in vitro exposure techniques developed is the exposure of cultured cells at the air–liquid interface (ALI), particularly in the case of respiratory airways. While the commercially available VITROCELL® Cloud System has been applied for the delivery of aerosolized substances to adherent cells under ALI conditions, it has not yet been tested on lung surfactant and semi-adherent cells such as alveolar macrophages, which are playing a pivotal role in the nanoparticle-induced immune response. Objectives: In this work, we developed a comprehensive methodology for coating semi-adherent lung cells cultured at the ALI with aerosolized surfactant and subsequent dose-controlled exposure to nanoparticles (NPs). This protocol is optimized for subsequent transcriptomic studies. Methods: Semi-adherent rat alveolar macrophages NR8383 were grown at the ALI and coated with lung surfactant through nebulization using the VITROCELL® Cloud 6 System before being exposed to TiO2 NM105 NPs. After NP exposures, RNA was extracted and its quantity and quality were measured. Results: The VITROCELL® Cloud system allowed for uniform and ultrathin coating of cells with aerosolized surfactant mimicking physiological conditions in the lung. While nebulization of 57 μL of 30 mg/mL TiO2 and 114 μL of 15 mg/mL TiO2 nanoparticles yielded identical cell delivered dose, the reproducibility of dose as well as the quality of RNA extracted were better for 114 μL.

Published

2022

181. Preliminary Study on the Development of In Vitro Human Respiratory Epithelium Using Collagen Type I Scaffold as a Potential Model for Future Tracheal Tissue Engineering.

Author

Lokanathan, Yogeswaran, Fauzi, Mh Busra, Che Man, Rohaina, Rashidbenam, Zahra, Bin Saim, Aminuddin, Binti Hj Idrus, Ruszymah, Mohd Yunus, Mohd Heikal, and Galli, Carlo

Subjects

TISSUE engineering, COLLAGEN, SCANNING electron microscopes, EPITHELIAL cells, ENDOTRACHEAL tubes

Abstract

Pathological conditions of the tracheal epithelium, such as postoperative injuries and chronic conditions, often compromise the functionality of the respiratory epithelium. Although replacement of the respiratory epithelium using various types of tracheal transplantation has been attempted, there is no predictable and dependable replacement method that holds for safe and practicable long-term use. Therefore, we used a tissue engineering approach for ex vivo regeneration of the respiratory epithelium (RE) construct. Collagen type I was isolated from sheep tendon and it was fabricated in a three-dimensional (3D) scaffold format. Isolated human respiratory epithelial cells (RECs) and fibroblasts from nasal turbinate were co-cultured on the 3D scaffold for 48 h, and epithelium maturation was allowed for another 14 days in an air–liquid interface culture system. The scanning electron microscope results revealed a fabricated porous-structure 3D collagen scaffold. The scaffold was found to be biocompatible with RECs and fibroblasts and allows cells attachment, proliferation, and migration. Immunohistochemical analysis showed that the seeded RECs and fibroblasts were positive for expression of cytokeratin 14 and collagen type I markers, respectively, indicating that the scaffold supports the native phenotype of seeded cells over a period of 14 days. Although a longer maturation period is needed for ciliogenesis to occur in RECs, the findings suggest that the tissue-engineered RE construct is a potential candidate for direct use in tracheal epithelium replacement or tracheal tube reengineering. [ABSTRACT FROM AUTHOR]

Published

2021

182. The Interface Motion and Hydrodynamic Shear of the Liquid Slosh in Syringes.

Author

Zhang, Yuchen, Han, Dingding, Dou, Zhongwang, Veilleux, Jean-Christophe, Shi, Galen H., Collins, David S., Vlachos, Pavlos P., and Ardekani, Arezoo M.

Subjects

*SLOSHING (Hydrodynamics), *SYRINGES, *AIR gap (Engineering), *INTERFACE dynamics, *CONTACT angle, *SURFACE tension, *AIR flow

Abstract

Purpose: Interface motion and hydrodynamic shear of the liquid slosh during the insertion of syringes upon autoinjector activation may damage the protein drug molecules. Experimentally validated computational fluid dynamics simulations are used in this study to investigate the interfacial motion and hydrodynamic shear due to acceleration and deceleration of syringes. The goal is to explore the role of fluid viscosity, air gap size, syringe acceleration, syringe tilt angle, liquid-wall contact angle, surface tension and fill volume on the interface dynamics caused by autoinjector activation. Methods: A simplified autoinjector platform submerged in water is built to record the syringe and liquid motion without obstruction of view. The syringe kinematics is imported to the simulations based on OpenFOAM InterIsoFoam solver, which is used to study the effects of various physical parameters. Results: The simulations agree with experiments on the air-liquid interface profile and interface area. The interfacial area and the volume of fluid subject to high strain rate decrease with the solution viscosity, increase with the air gap height, syringe velocity, tilt angle and syringe wall hydrophobicity, and hardly change with the surface tension and liquid column height. The hydrodynamic shear mainly occurs near the syringe wall and entrained bubbles. Conclusion: For a given dose of drug solution, the syringe with smaller radius and larger length will generate less liquid slosh. Reducing the air volume and syringe wall hydrophobicity are also helpful to reduce interface area and effective shear. The interface motion is reduced when the syringe axis is aligned with the gravitational direction. [ABSTRACT FROM AUTHOR]

Published

2021

183. Development of a dynamic in vitro stretch model of the alveolar interface with aerosol delivery.

Author

Cei, Daniele, Doryab, Ali, Lenz, Anke‐Gabriele, Schröppel, Andreas, Mayer, Paula, Burgstaller, Gerald, Nossa, Roberta, Ahluwalia, Arti, and Schmid, Otmar

Abstract

We describe the engineering design, computational modeling, and empirical performance of a moving air–liquid interface (MALI) bioreactor for the study of aerosol deposition on cells cultured on an elastic, porous membrane which mimics both air–liquid interface exposure conditions and mechanoelastic motion of lung tissue during breathing. The device consists of two chambers separated by a cell layer cultured on a porous, flexible membrane. The lower (basolateral) chamber is perfused with cell culture medium simulating blood circulation. The upper (apical) chamber representing the air compartment of the lung is interfaced to an aerosol generator and a pressure actuation system. By cycling the pressure in the apical chamber between 0 and 7 kPa, the membrane can mimic the periodic mechanical strain of the alveolar wall. Focusing on the engineering aspects of the system, we show that membrane strain can be monitored by measuring changes in pressure resulting from the movement of media in the basolateral chamber. Moreover, liquid aerosol deposition at a high dose delivery rate (>1 µl cm−2 min−1) is highly efficient (ca. 51.5%) and can be accurately modeled using finite element methods. Finally, we show that lung epithelial cells can be mechanically stimulated under air–liquid interface and stretch‐conditions without loss of viability. The MALI bioreactor could be used to study the effects of aerosol on alveolar cells cultured at the air–liquid interface in a biodynamic environment or for toxicological or therapeutic applications. [ABSTRACT FROM AUTHOR]

Published

2021

184. New insights into antibubble formation by single drop impact on a same-liquid pool.

Author

Niroula A and Nazir A

Abstract

Hypothesis: Secondary drops (SDs) generated when falling drops impact a same-liquid bath can potentially generate antibubbles. Different mechanisms of antibubble formation can be identified and their size and formation probability (P Ab ) can be predicted., Experiments: Surfactant solutions were dropped from various heights using a highly stable pulseless microfluidic pump in a same-liquid bath. The impact was recorded using a high-speed camera. The formation of SDs and antibubbles as well as their sizes were evaluated considering the falling-drop height (H FD ) and dimensionless parameters., Findings: This study reports new mechanisms for antibubble formation from SDs. A decrease in the surface tension yielded a thinner central jet, thereby yielding more SDs. Larger values of the H FD , impact velocity (U), and Weber number (We) increased the SD size and decreased the SD count; the increase in size increased the antibubble size. The number of SDs correlated with the formation of two distinct antibubbles or a single (coalesced) antibubble. The plots for P Ab versus H FD , U, and We exhibited two distinct peaks. A moderate increase in the surfactant concentration enhanced P Ab in the first regime, whereas an excessive concentration limited antibubble formation. Artificial neural modeling can successfully predict antibubble formation. These findings provide valuable insights for the research on controlled antibubble generation., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

185. Versatile micro-electrode array to monitor human iPSC derived 3D neural tissues at air-liquid interface.

Author

Stoppini L, Heuschkel MO, Loussert-Fonta C, Gomez Baisac L, and Roux A

Abstract

Engineered 3D neural tissues made of neurons and glial cells derived from human induced pluripotent stem cells (hiPSC) are among the most promising tools in drug discovery and neurotoxicology. They represent a cheaper, faster, and more ethical alternative to in vivo animal testing that will likely close the gap between in vitro animal models and human clinical trials. Micro-Electrode Array (MEA) technology is known to provide an assessment of compound effects on neural 2D cell cultures and acute tissue preparations by real-time, non-invasive, and long-lasting electrophysiological monitoring of spontaneous and evoked neuronal activity. Nevertheless, the use of engineered 3D neural tissues in combination with MEA biochips still involves series of constraints, such as drastically limited diffusion of oxygen and nutrients within tissues mainly due to the lack of vascularization. Therefore, 3D neural tissues are extremely sensitive to experimental conditions and require an adequately designed interface that provides optimal tissue survival conditions. A well-suited technique to overcome this issue is the combination of the Air-Liquid Interface (ALI) tissue culture method with the MEA technology. We have developed a full 3D neural tissue culture process and a data acquisition system composed of high-end electronics and novel MEA biochips based on porous, flexible, thin-film membranes integrating recording electrodes, named as "Strip-MEA," to allow the maintenance of an ALI around the 3D neural tissues. The main motivation of the porous MEA biochips development was the possibility to monitor and to study the electrical activity of 3D neural tissues under different recording configurations, (i) the Strip-MEA can be placed below a tissue, (ii) or by taking advantage of the ALI, be directly placed on top of the tissue, or finally, (iii) it can be embedded into a larger neural tissue generated by the fusion of two (or more) tissues placed on both sides of the Strip-MEA allowing the recording from its inner part. This paper presents the recording and analyses of spontaneous activity from the three positioning configurations of the Strip-MEAs. Obtained results are discussed with the perspective of developing in vitro models of brain diseases and/or impairment of neural network functioning., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Stoppini, Heuschkel, Loussert-Fonta, Gomez Baisac and Roux.)

Published

2024

186. Interleukin-13 Treatment of Living Lung Tissue Model Alters the Metabolome and Proteome-A Nano-DESI MS Metabolomics and Shotgun Proteomics Study.

Author

Tóth G, Golubova A, Falk A, Lind SB, Nicholas M, and Lanekoff I

Subjects

Humans, Mass Spectrometry methods, Epithelial Cells metabolism, Epithelial Cells drug effects, Asthma metabolism, Asthma drug therapy, Interleukin-13 metabolism, Lung metabolism, Proteomics methods, Metabolomics methods, Metabolome drug effects, Proteome metabolism

Abstract

Asthma is a chronic respiratory disease with one of the largest numbers of cases in the world; thus, constant investigation and technical development are needed to unravel the underlying biochemical mechanisms. In this study, we aimed to develop a nano-DESI MS method for the in vivo characterization of the cellular metabolome. Using air-liquid interface (ALI) cell layers, we studied the role of Interleukin-13 (IL-13) on differentiated lung epithelial cells acting as a lung tissue model. We demonstrate the feasibility of nano-DESI MS for the in vivo monitoring of basal-apical molecular transport, and the subsequent endogenous metabolic response, for the first time. Conserving the integrity of the ALI lung-cell layer enabled us to perform temporally resolved metabolomic characterization followed by "bottom-up" proteomics on the same population of cells. Metabolic remodeling was observed upon histamine and corticosteroid treatment of the IL-13-exposed lung cell monolayers, in correlation with alterations in the proteomic profile. This proof of principle study demonstrates the utility of in vivo nano-DESI MS for characterizing ALI tissue layers, and the new markers identified in our study provide a good starting point for future, larger-scale studies.

Published

2024

187. Toxicological responses of A549 and HCE-T cells exposed to fine particulate matter at the air-liquid interface.

Author

Chen W, Ge P, Deng M, Liu X, Lu Z, Yan Z, Chen M, and Wang J

Subjects

Humans, A549 Cells, DNA Damage, Reactive Oxygen Species metabolism, Apoptosis drug effects, Epithelial Cells drug effects, Particulate Matter toxicity, Cell Survival drug effects, Air Pollutants toxicity

Abstract

Fine particulate matter (PM 2.5 ) can enter the human body in various ways and have adverse effects on human health. Human lungs and eyes are exposed to the air for a long time and are the first to be exposed to PM 2.5 . The "liquid immersion exposure method" has some limitations that prevent it from fully reflecting the toxic effects of particulate matter on the human body. In this study, the collected PM 2.5 samples were chemically analyzed. An air-liquid interface (ALI) model with a high correlation to the in vivo environment was established based on human lung epithelial cells (A549) and immortalized human corneal epithelial cells (HCE-T). The VITROCELL Cloud 12 system was used to distribute PM 2.5 on the cells evenly. After exposure for 6 h and 24 h, cell viability, apoptosis rate, reactive oxygen species (ROS) level, expression of inflammatory factors, and deoxyribonucleic acid (DNA) damage were measured. The results demonstrated significant dose- and time-dependent effects of PM 2.5 on cell viability, cell apoptosis, ROS generation, and DNA damage at the ALI, while the inflammatory factors showed dose-dependent effects only. It should be noted that even short exposure to low doses of PM 2.5 can cause cell DNA double-strand breaks and increased expression of γ-H2AX, indicating significant genotoxicity of PM 2.5 . Increased abundance of ROS in cells plays a crucial role in the cytotoxicity induced by PM 2.5 exposure These findings emphasize the significant cellular damage and genotoxicity that may result from short-term exposure to low levels of PM 2.5 ., (© 2024. The Author(s).)

Published

2024

188. Modular air-liquid interface aerosol exposure system (MALIES) to study toxicity of nanoparticle aerosols in 3D-cultured A549 cells in vitro.

Author

Küstner MJ, Eckstein D, Brauer D, Mai P, Hampl J, Weise F, Schuhmann B, Hause G, Glahn F, Foth H, and Schober A

Subjects

Humans, A549 Cells, Cells, Cultured, Cell Line, Aerosols, Respiratory Aerosols and Droplets, Nanoparticles toxicity

Abstract

We present a novel lung aerosol exposure system named MALIES (modular air-liquid interface exposure system), which allows three-dimensional cultivation of lung epithelial cells in alveolar-like scaffolds (MatriGrids ® ) and exposure to nanoparticle aerosols. MALIES consists of multiple modular units for aerosol generation, and can be rapidly assembled and commissioned. The MALIES system was proven for its ability to reliably produce a dose-dependent toxicity in A549 cells using CuSO 4 aerosol. Cytotoxic effects of BaSO 4 - and TiO 2 -nanoparticles were investigated using MALIES with the human lung tumor cell line A549 cultured at the air-liquid interface. Experiments with concentrations of up to 5.93 × 10 5 (BaSO 4 ) and 1.49 × 10 6 (TiO 2 ) particles/cm 3 , resulting in deposited masses of up to 26.6 and 74.0 µg/cm 2 were performed using two identical aerosol exposure systems in two different laboratories. LDH, resazurin reduction and total glutathione were measured. A549 cells grown on MatriGrids ® form a ZO-1- and E-Cadherin-positive epithelial barrier and produce mucin and surfactant protein. BaSO 4 -NP in a deposited mass of up to 26.6 µg/cm 2 resulted in mild, reversible damage (~ 10% decrease in viability) to lung epithelium 24 h after exposure. TiO 2 -NP in a deposited mass of up to 74.0 µg/cm 2 did not induce any cytotoxicity in A549 cells 24 h and 72 h after exposure, with the exception of a 1.7 fold increase in the low exposure group in laboratory 1. These results are consistent with previous studies showing no significant damage to lung epithelium by short-term treatment with low concentrations of nanoscale BaSO 4 and TiO 2 in in vitro experiments., (© 2024. The Author(s).)

Published

2024

189. Development of an in vitro human alveolar epithelial air-liquid interface model using a small molecule inhibitor cocktail.

Author

Tanabe I, Ishimori K, and Ishikawa S

Subjects

Humans, Cell Differentiation, Pulmonary Alveoli metabolism, Surface-Active Agents metabolism

Abstract

Background: The alveolar epithelium is exposed to numerous stimuli, such as chemicals, viruses, and bacteria that cause a variety of pulmonary diseases through inhalation. Alveolar epithelial cells (AECs) cultured in vitro are a valuable tool for studying the impacts of these stimuli and developing therapies for associated diseases. However, maintaining the proliferative capacity of AECs in vitro is challenging. In this study, we used a cocktail of three small molecule inhibitors to cultivate AECs: Y-27632, A-83-01, and CHIR99021 (YAC). These inhibitors reportedly maintain the proliferative capacity of several types of stem/progenitor cells., Results: Primary human AECs cultured in medium containing YAC proliferated for more than 50 days (over nine passages) under submerged conditions. YAC-treated AECs were subsequently cultured at the air-liquid interface (ALI) to promote differentiation. YAC-treated AECs on ALI day 7 formed a monolayer of epithelial tissue with strong expression of the surfactant protein-encoding genes SFTPA1, SFTPB, SFTPC, and SFTPD, which are markers for type II AECs (AECIIs). Immunohistochemical analysis revealed that paraffin sections of YAC-treated AECs on ALI day 7 were mainly composed of cells expressing surfactant protein B and prosurfactant protein C., Conclusions: Our results indicate that YAC-containing medium could be useful for expansion of AECIIs, which are recognized as local stem/progenitor cells, in the alveoli., (© 2024. The Author(s).)

Published

2024

190. A gel-coated air-liquid-interface culture system with tunable substrate stiffness matching healthy and diseased lung tissues.

Author

He ZJ, Chu C, Dickson R, Okuda K, and Cai LH

Subjects

Humans, Epithelial Cells, Lung, Hydrogels, Cells, Cultured, Airway Remodeling, Lung Diseases

Abstract

Since its invention in the late 1980s, the air-liquid-interface (ALI) culture system has been the standard in vitro model for studying human airway biology and pulmonary diseases. However, in a conventional ALI system, cells are cultured on a porous plastic membrane that is much stiffer than human airway tissues. Here, we develop a gel-ALI culture system by simply coating the plastic membrane with a thin layer of hydrogel with tunable stiffness matching that of healthy and fibrotic airway tissues. We determine the optimum gel thickness that does not impair the transport of nutrients and biomolecules essential to cell growth. We show that the gel-ALI system allows human bronchial epithelial cells (HBECs) to proliferate and differentiate into pseudostratified epithelium. Furthermore, we discover that HBECs migrate significantly faster on hydrogel substrates with stiffness matching that of fibrotic lung tissues, highlighting the importance of mechanical cues in human airway remodeling. The developed gel-ALI system provides a facile approach to studying the effects of mechanical cues in human airway biology and in modeling pulmonary diseases. NEW & NOTEWORTHY In a conventional ALI system, cells are cultured on a plastic membrane that is much stiffer than human airway tissues. We develop a gel-ALI system by coating the plastic membrane with a thin layer of hydrogel with tunable stiffness matching that of healthy and fibrotic airway tissues. We discover that human bronchial epithelial cells migrate significantly faster on hydrogel substrates with pathological stiffness, highlighting the importance of mechanical cues in human airway remodeling.

Published

2024

191. Influenza virus‐mediated suppression of bronchial Chitinase‐3‐like 1 secretion promotes secondary pneumococcal infection.

Author

Karwelat, Diana, Schmeck, Bernd, Ringel, Marc, Benedikter, Birke J., Hübner, Kathleen, Beinborn, Isabell, Maisner, Andrea, Schulte, Leon N., and Vollmeister, Evelyn

Abstract

Infections of the lung are among the leading causes of death worldwide. Despite the preactivation of innate defense programs during viral infection, secondary bacterial infection substantially elevates morbidity and mortality rates. Particularly problematic are co‐infections with influenza A virus (IAV) and the major bacterial pathogen Streptococcus pneumoniae. However, the molecular processes underlying the severe course of such co‐infections are not fully understood. Previously, the absence of secreted glycoprotein Chitinase‐3‐like 1 (CHI3L1) was shown to increase pneumococcal replication in mice. We therefore hypothesized that an IAV preinfection decreases CHI3L1 levels to promote pneumococcal infection. Indeed, in an air‐liquid interface model of primary human bronchial epithelial cells (hBECs), IAV preinfection interfered with apical but not basolateral CHI3L1 release. Confocal time‐lapse microscopy revealed that the gradual loss of apical CHI3L1 localization during co‐infection with influenza and S. pneumoniae coincided with the disappearance of goblet as well as ciliated cells and increased S. pneumoniae replication. Importantly, extracellular restoration of CHI3L1 levels using recombinant protein significantly reduced bacterial load in influenza preinfected bronchial models. Thus, recombinant CHI3L1 may provide a novel therapeutic means to lower morbidity and mortality associated with post‐influenza pneumococcal infections. [ABSTRACT FROM AUTHOR]

Published

2020

192. Air–liquid interface cultures trigger a metabolic shift in intestinal epithelial cells (IPEC-1)

Author

Stollmeier, Martin, Kahlert, Stefan, Zuschratter, Werner, Oster, Michael, Wimmers, Klaus, Isermann, Berend, Rothkötter, Hermann-Josef, and Nossol, Constanze

Subjects

Medical Laboratory Technology, Histology, Glucose, HIF-1α, Lactate, ALI, Microarray, Metabolism, ATP, Air–liquid interface, IPEC, Cell Biology, Molecular Biology

Abstract

An improved oxygen availability in air–liquid interface (ALI) cultures of enterocytes of the small intestine seems to be primarily responsible for morphological, metabolic, and functional changes. Intestinal porcine epithelial cells 1 (IPEC-1) are less investigated and are rarely used as model for intestinal barrier but showed a profound change of cell shape during ALI cultivation. We aim to answer the following question: Are the observed morphological effects accompanied by changes in metabolic function? A microarray analysis of submerged culture (SMC) and ALI cultures identified 830 significantly regulated genes. Subsequent functional clustering revealed alterations in 31 pathways, with the highest number of regulated genes in metabolic pathways, carbon metabolism, glycolysis, and hypoxia-inducible factor (HIF) signaling. Furthermore, HIF-1α as a mediator of a metabolic switch between glycolysis and oxidative phosphorylation showed a trend of increased mRNA levels in ALI in contrast to a reduced nuclear HIF-1α content in the nucleus. Candidate genes of oxidative phosphorylation such as a mitochondrial marker exhibited enhanced mRNA levels, which was confirmed by western blot analysis. Cytochrome C oxidase (COX) subunit 5B protein was decreased in ALI, although mRNA level was increased. The oxidation of ferrocytochrome C to ferricytochrome C was used for detection of cytochrome C oxidase activity of isolated mitochondria and resulted in a trend of higher activity in ALI. Furthermore, quantification of glucose and lactate concentrations in cell culture medium revealed significantly reduced glucose levels and decreased lactate production in ALI. To evaluate energy metabolism, we measured cellular adenosine triphosphate (ATP) aggregation in homogenized cell suspensions showing similar levels. However, application of the uncoupling agent FCCP reduced ATP levels in ALI but not in SMC. In contrast, blocking with 2-desoxy-d-glucose (2DG) significantly reduced ATP content in ALI and SMC. These results indicate a metabolic shift in IPEC-1 cultured under ALI conditions enhancing oxidative phosphorylation and suppressing glycolysis.

Published

2023

193. Assessing the in vitro toxicity of airborne (nano)particles to the human respiratory system: from basic to advanced models

Author

Maria João Bessa, Fátima Brandão, Fernanda Rosário, Luciana Moreira, Ana Teresa Reis, Vanessa Valdiglesias, Blanca Laffon, Sónia Fraga, and João Paulo Teixeira

Subjects

In vitro, Health, Toxicology and Mutagenesis, Toxicity testing, Nanoparticles, Submerged cultures, Respiratory models, Toxicology, Air-liquid interface

Abstract

[Abstract] Several studies have been conducted to address the potential adverse health risks attributed to exposure to nanoscale materials. While in vivo studies are fundamental for identifying the relationship between dose and occurrence of adverse effects, in vitro model systems provide important information regarding the mechanism(s) of action at the molecular level. With a special focus on exposure to inhaled (nano)particulate material toxicity assessment, this review provides an overview of the available human respiratory models and exposure systems for in vitro testing, advantages, limitations, and existing investigations using models of different complexity. A brief overview of the human respiratory system, pathway and fate of inhaled (nano)particles is also presented. The work was supported by the Fundação para a Ciência e a Tecnologia [POCI-01-0145-FEDER-029651, SFRH/BPD/122112/2016,PTDC/MED‐TOX/31162/2017, DL-57/INSA-06/2018,SFRH/BD/101060/2014,SFRH/BD/120646/2016,SIINN/0004/2014,UIDB/04750/2020, LA/P/0064/2020]; Spanish Ministry of Education, Culture and Sport [BEAGAL18/00142]; Spanish Ministry of Science and Innovation [PID2020-114908GA-I00] Portugal. Fundação para a Ciência e a Tecnologia; POCI-01-0145-FEDER-029651 Portugal. Fundação para a Ciência e a Tecnologia; SFRH/BPD/122112/2016 Portugal. Fundação para a Ciência e a Tecnologia; PTDC/MED‐TOX/31162/2017 Portugal. Fundação para a Ciência e a Tecnologia; DL-57/INSA-06/2018 Portugal. Fundação para a Ciência e a Tecnologia; SFRH/BD/101060/2014 Portugal. Fundação para a Ciência e a Tecnologia; SFRH/BD/120646/2016 Portugal. Fundação para a Ciência e a Tecnologia; SIINN/0004/2014 Portugal. Fundação para a Ciência e a Tecnologia; UIDB/04750/2020 Portugal. Fundação para a Ciência e a Tecnologia; LA/P/0064/2020

Published

2023

194. Consecutive Hypoxia Decreases Expression of NOTCH3, HEY1, CC10, and FOXJ1 via NKX2-1 Downregulation and Intermittent Hypoxia-Reoxygenation Increases Expression of BMP4, NOTCH1, MKI67, OCT4, and MUC5AC via HIF1A Upregulation in Human Bronchial Epithelial Cells

Author

Yung-Yu Yang, Chao-Ju Lin, Cheng-Chin Wang, Chieh-Min Chen, Wen-Jen Kao, and Yi-Hui Chen

Subjects

air-liquid interface, apoptosis, differentiation, FOXJ1, human bronchial epithelial cells, MUC5AC, Biology (General), QH301-705.5

Abstract

Previous studies have shown that the experimental models of hypoxia-reoxygenation (H/R) mimics the physiological conditions of ischemia-reperfusion and induce oxidative stress and injury in various types of organs, tissues, and cells, both in vivo and in vitro, including human lung adenocarcinoma epithelial cells. Nonetheless, it had not been reported whether H/R affected proliferation, apoptosis, and expression of stem/progenitor cell markers in the bronchial epithelial cells. In this study, we investigated differential effects of consecutive hypoxia and intermittent 24/24-h cycles of H/R on human bronchial epithelial (HBE) cells derived from the same-race and age-matched healthy subjects (i.e., NHBE) and subjects with chronic obstructive pulmonary disease (COPD) (i.e., DHBE). To analyze gene/protein expression during differentiation, both the NHBE and DHBE cells at the 2nd passage were cultured at the air-liquid interface (ALI) in the differentiation medium under normoxia for 3 days, followed by either culturing under hypoxia (1% O2) for consecutively 9 days and then returning to normoxia for another 9 days, or culturing under 24/24-h cycles of H/R (i.e., 24 h of 1% O2 followed by 24 h of 21% O2, repetitively) for 18 days in total, so that all differentiating HBE cells were exposed to hypoxia for a total of 9 days. In both the normal and diseased HBE cells, intermittent H/R significantly increased HIF1A, BMP4, NOTCH1, MKI67, OCT4, and MUC5AC expression, while consecutive hypoxia significantly decreased NKX2-1, NOTCH3, HEY1, CC10, and FOXJ1 expression. Inhibition of HIF1A or NKX2-1 expression by siRNA transfection respectively decreased BMP4/NOTCH1/MKI67/OCT4/MUC5AC and NOTCH3/HEY1/CC10/FOXJ1 expression in the HBE cells cultured under intermittent H/R to the same levels under normoxia. Overexpression of NKX2-1 via cDNA transfection caused more than 2.8-fold increases in NOTCH3, HEY1, and FOXJ1 mRNA levels in the HBE cells cultured under consecutive hypoxia compared to the levels under normoxia. Taken together, our results show for the first time that consecutive hypoxia decreased expression of the co-regulated gene module NOTCH3/HEY1/CC10 and the ciliogenesis-inducing transcription factor gene FOXJ1 via NKX2-1 mRNA downregulation, while intermittent H/R increased expression of the co-regulated gene module BMP4/NOTCH1/MKI67/OCT4 and the predominant airway mucin gene MUC5AC via HIF1A mRNA upregulation.

Published

2020

195. Utilizing Organoid and Air-Liquid Interface Models as a Screening Method in the Development of New Host Defense Peptides

Author

Ka-Yee Grace Choi, Bing Catherine Wu, Amy Huei-Yi Lee, Beverlie Baquir, and Robert E. W. Hancock

Subjects

host-defense peptide, organoid, air-liquid interface, disease model, drug screening, antimicrobial resistant organisms, Microbiology, QR1-502

Abstract

Host defense peptides (HDPs), also known as antimicrobial peptides, are naturally occurring polypeptides (~12–50 residues) composed of cationic and hydrophobic amino acids that adopt an amphipathic conformation upon folding usually after contact with membranes. HDPs have a variety of biological activities including immunomodulatory, anti-inflammatory, anti-bacterial, and anti-biofilm functions. Although HDPs have the potential to address the global threat of antibiotic resistance and to treat immune and inflammatory disorders, they have yet to achieve this promise. Indeed, there are several challenges associated with bringing peptide-based drug candidates from the lab bench to clinical practice, including identifying appropriate indications, stability, toxicity, and cost. These challenges can be addressed in part by the development of innate defense regulator (IDR) peptides and peptidomimetics, which are synthetic derivatives of HDPs with similar or better efficacy, increased stability, and reduced toxicity and cost of the original HDP. However, one of the largest gaps between basic research and clinical application is the validity and translatability of conventional model systems, such as cell lines and animal models, for screening HDPs and their derivatives as potential drug therapies. Indeed, such translation has often relied on animal models, which have only limited validity. Here we discuss the recent development of human organoids for disease modeling and drug screening, assisted by the use of omics analyses. Organoids, developed from primary cells, cell lines, or human pluripotent stem cells, are three-dimensional, self-organizing structures that closely resemble their corresponding in vivo organs with regards to immune responses, tissue organization, and physiological properties; thus, organoids represent a reliable method for studying efficacy, formulation, toxicity and to some extent drug stability and pharmacodynamics. The use of patient-derived organoids enables the study of patient-specific efficacy, toxicogenomics and drug response predictions. We outline how organoids and omics data analysis can be leveraged to aid in the clinical translation of IDR peptides.

Published

2020

196. Rhinovirus Induces Basolateral Release of IL-17C in Highly Differentiated Airway Epithelial Cells

Author

Kyla C. Jamieson, Shahina Wiehler, Aubrey N. Michi, and David Proud

Subjects

rhinovirus, air-liquid interface, airway epithelium, IL-17C, well-differentiated, basolateral secretion, Microbiology, QR1-502

Abstract

Human rhinovirus (HRV) is a major trigger of acute exacerbations of both asthma and chronic obstructive pulmonary disease. The airway epithelium is the primary site of HRV infection, and responds by releasing proinflammatory and antimicrobial cytokines. Epithelial cells release IL-17C in response to exposure to bacterial, viral, and fungal pathogens. We previously demonstrated a role for HRV in IL-17C production from undifferentiated epithelial cells, and showed that IL-17C could play a role in neutrophil recruitment. To extend these observations, highly differentiated human bronchial epithelial cells (HBE) were infected apically with HRV to assess the effect of dose, time, viral replication, and strain on the IL-17C response. Cellular lysates, and basolateral and apical secretions were analyzed for IL-17C and CXCL1 protein release following HRV or IL-17C stimulation. Upon HRV infection, IL-17C protein was exclusively released basolaterally in a dose-, time-, and viral replication-dependent manner. Several strains of rhinovirus were capable of inducing IL-17C release. Enriched columnar epithelial cell populations contained significantly higher viral titer, and expressed significantly more IL-17C mRNA than enriched basal cell populations. In addition, the kinetic profile of IL-17C release following HRV treatment closely mimics viral shedding kinetics, further implicating the role of rhinovirus replication in IL-17C production. Basolateral treatment of HBEs with IL-17C resulted in a dose-dependent increase in basolateral CXCL1 production. In summary, replicating rhinovirus drives basolateral IL-17C protein release from both apical and basal epithelial cells, which may then act in an autocrine/paracrine manner to promote basolateral CXCL1 protein release.

Published

2020

197. New Design of a Sample Cell for Neutron Reflectometry in Liquid–Liquid Systems and Its Application for Studying Structures at Air–Liquid and Liquid–Liquid Interfaces

Author

Kazuhiro Akutsu-Suyama, Norifumi L. Yamada, Yuki Ueda, Ryuhei Motokawa, and Hirokazu Narita

Subjects

neutron reflectometry, liquid–liquid interface, air–liquid interface, adsorption structure, sodium dodecyl sulfate, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Knowledge of interfacial structures in liquid–liquid systems is imperative, especially for improving two-phase biological and chemical reactions. Therefore, we developed a new sample cell for neutron reflectometry (NR), which enables us to observe the layer structure around the interface, and investigated the adsorption behavior of a typical surfactant, sodium dodecyl sulfate (SDS), on the toluene-d8-D2O interface under the new experimental conditions. The new cell was characterized by placing the PTFE frame at the bottom to produce a smooth interface and downsized compared to the conventional cell. The obtained NR profiles were readily analyzable and we determined a slight difference in the SDS adsorption layer structure at the interface between the toluene-d8-D2O and air-D2O systems. This could be owing to the difference in the adsorption behavior of the SDS molecules depending on the interfacial conditions.

Published

2022

198. Development and characterization of a polarized human endometrial cell epithelia in an air–liquid interface state

Author

Dandan Li, Hui Li, Ying Wang, Ahmed Eldomany, Jing Wu, Chao Yuan, Jing Xue, Juan Shi, Yuanyuan Jia, Chunfang Ha, Shuxia Han, Xiaoming Liu, Jiali Yang, and Dan Liu

Subjects

Endometrium, Epithelial cells, Stem cells, Air–liquid interface, Estrogen, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Human endometrial epithelia undergo injury repair and regeneration with the menstrual cycle; however, mechanisms underpinning the roles of endometrial epithelial cells in endometrial lesions and regeneration remain incompletely understood, mainly owing to the difficulty in the isolation and expansion of primary endometrial epithelial cells and the lack of reliable models for in vitro and in vivo studies. In this report, we sought to improve methods for the isolation and expansion of human endometrial epithelial cells with a Rho-associated protein kinase (ROCK) inhibitor–modified medium and subsequently characterize endometrial epithelium generated with primary cells cultured in an air–liquid interface (ALI) state. Immunocytochemistry staining revealed the expression of epithelial cellular adhesion molecule (EpCam) and stage-specific embryonic antigen-1 (SSEA-1) but a lack of CD13 in endometrial epithelial cells. Meanwhile, a large number of proliferative Ki67+ cells were observed in isolated epithelial cells. Importantly, the EpCam+/CD13− cells were capable of forming spheroids, a characteristic of epithelial stem/progenitor cells. Interestingly, these cells also exhibited a capacity to reconstitute epithelial layers in an ALI state. Morphological analysis revealed mucosal secretion of differentiated epithelial cells with cilia and microvilli in ALI epithelial cells as determined by electronic microscopy. Immunoblotting assay further demonstrated the expression of endometrial epithelial cell markers keratin 17/19 and EpCam and stem cell marker OCT3/4 but not stromal cell marker Vimentin protein and CD13 in cell expansions. Furthermore, molecular analysis also showed that the exposure of cells to estrogen elevated the expression of estrogen receptor and progesterone receptors in ALI cultures. Our results shed light on the possibility of expanding sufficient numbers of endometrial epithelial cells for stem cell biology studies, and they provide a feasible and alternative model that can recapitulate the characteristics and physiology of endometrial epithelium in vivo.

Published

2018

199. Establishment and comparison of air-liquid interface culture systems for primary and immortalized swine tracheal epithelial cells

Author

Haiyan Wang, Lina He, Beibei Liu, Yanyan Feng, Hao Zhou, Zhenzhen Zhang, Yuzi Wu, Jia Wang, Yuan Gan, Ting Yuan, Meng Wu, Xing Xie, and Zhixin Feng

Subjects

Air-liquid interface, Immortalized swine tracheal epithelial cell line, Primary swine tracheal epithelial cells, Differentiation, comparison, Cytology, QH573-671

Abstract

Abstract Background Air-liquid interface (Ali) systems allow the establishment of a culture environment more representative of that in vivo than other culture systems. They are useful for performing mechanistic studies of respiratory epithelial cells as drug permeation barriers and can be used to study the interactions between hosts and respiratory pathogens. However, there have been few studies concerning Ali cultures of primary swine tracheal epithelial cells (STECs) and an immortalized STEC line, and the differences between these two systems remain poorly defined. Results In this study, we established Ali culture systems for primary STECs and for immortalized STEC line, and we systematically compared the differentiation capacities and immunological functions of these systems for the first time. Under Ali culture conditions, immortalized STEC line and primary STECs could survive for at least forty days, formed tight junctions and differentiated into stratified cells. They both possessed complete abilities to produce mucin and inflammatory cytokines and develop cilia. However, in contrast to primary STECs, which had a heterogeneous morphology, Ali-cultured immortalized STEC line appeared to be a homogenous population. The formation of tight junctions in Ali-cultured primary STECs was superior to that in immortalized STEC line. In addition, cilia in Ali-cultured immortalized STEC line were more pronounced, but their duration of expression was shorter than in primary STECs. Conclusions Ali-cultured primary STECs and immortalized STEC line systems possessing complete abilities to undergo ciliary differentiation and inflammatory cytokine production were established for the first time in this study, and several differences in morphology and the formation of tight junctions and cilia were observed between these two systems. These two systems will be important tools for drug screening studies, as well as for detailed analyses of the interactions between hosts and respiratory pathogens.

Published

2018

200. Predicting the in vivo pulmonary toxicity induced by acute exposure to poorly soluble nanomaterials by using advanced in vitro methods

Author

Thomas Loret, Françoise Rogerieux, Bénédicte Trouiller, Anne Braun, Christophe Egles, and Ghislaine Lacroix

Subjects

Poorly soluble nanomaterials, Acute exposure, Pulmonary toxicity, Alternative toxicity testing, Air-liquid interface, In vivo - in vitro comparison, Toxicology. Poisons, RA1190-1270, Industrial hygiene. Industrial welfare, HD7260-7780.8

Abstract

Abstract Background Animal models remain at that time a reference tool to predict potential pulmonary adverse effects of nanomaterials in humans. However, in a context of reduction of the number of animals used in experimentation, there is a need for reliable alternatives. In vitro models using lung cells represent relevant alternatives to assess potential nanomaterial acute toxicity by inhalation, particularly since advanced in vitro methods and models have been developed. Nevertheless, the ability of in vitro experiments to replace animal experimentation for predicting potential acute pulmonary toxicity in human still needs to be carefully assessed. The aim of the study was to evaluate the differences existing between the in vivo and the in vitro approaches for the prediction of nanomaterial toxicity and to find advanced methods to enhance in vitro predictivity. For this purpose, rats or pneumocytes in co-culture with macrophages were exposed to the same poorly soluble and poorly toxic TiO2 and CeO2 nanomaterials, by the respiratory route in vivo or using more or less advanced methodologies in vitro. After 24 h of exposure, biological responses were assessed focusing on pro-inflammatory effects and quantitative comparisons were performed between the in vivo and in vitro methods, using compatible dose metrics. Results For each dose metric used (mass/alveolar surface or mass/macrophage), we observed that the most realistic in vitro exposure method, the air-liquid interface method, was the most predictive of in vivo effects regarding biological activation levels. We also noted less differences between in vivo and in vitro results when doses were normalized by the number of macrophages rather than by the alveolar surface. Lastly, although we observed similarities in the nanomaterial ranking using in vivo and in vitro approaches, the quality of the data-set was insufficient to provide clear ranking comparisons. Conclusions We showed that advanced methods could be used to enhance in vitro experiments ability to predict potential acute pulmonary toxicity in vivo. Moreover, we showed that the timing of the dose delivery could be controlled to enhance the predictivity. Further studies should be necessary to assess if air-liquid interface provide more reliable ranking of nanomaterials than submerged methods.

Published

2018