Effect of surface functionalizations of multi-walled carbon nanotubes on neoplastic transformation potential in primary human lung epithelial cells

Stueckle, Todd A.; Davidson, Donna C.; Derk, Raymond C.; Wang, Peng; Friend, Sherri; Schwegler‐Berry, Diane; Zheng, Peng; Wu, Nianqiang; Castranova, Vince; Rojanasakul, Yon; Wang, Liying

doi:10.1080/17435390.2017.1332253

Cited by 21 publications

(13 citation statements)

References 56 publications

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“…To date, the investigation of the small airway epithelium as a primary responder to NP exposure has been exclusively limited to in vitro studies of model cell lines and primary cells in submerged culture, including (Ng et al , 2013, Snyder-Talkington et al , 2013, Sisler et al , 2016, Stueckle et al , 2017). Submerged culture is not optimal for differentiation of airway cells towards in vivo functionality and does not allow for representative NP deposition to occur using aerosolised material.…”

Section: Discussionmentioning

confidence: 99%

The small airway epithelium as a target for the adverse pulmonary effects of silver nanoparticle inhalation

et al. 2018

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Experimental modeling to identify specific inhalation hazards for nanomaterials has in the main focused on in vivo approaches. However, these models suffer from uncertainties surrounding species-specific differences and cellular targets for biologic response. In terms of pulmonary exposure, approaches which combine 'inhalation-like' nanoparticulate aerosol deposition with relevant human cell and tissue air-liquid interface cultures are considered an important complement to in vivo work. In this study, we utilized such a model system to build on previous results from in vivo exposures, which highlighted the small airway epithelium as a target for silver nanoparticle (AgNP) deposition. RNA-SEQ was used to characterize alterations in mRNA and miRNA within the lung. Organotypic-reconstituted 3D human primary small airway epithelial cell cultures (SmallAir) were exposed to the same spark-generated AgNP and at the same dose used in vivo, in an aerosol-exposure air-liquid interface (AE-ALI) system. Adverse effects were characterized using lactate, LDH release and alterations in mRNA and miRNA. Modest toxicological effects were paralleled by significant regulation in gene expression, reflective mainly of specific inflammatory events. Importantly, there was a level of concordance between gene expression changes observed in vitro and in vivo. We also observed a significant correlation between AgNP and mass equivalent silver ion (Ag) induced transcriptional changes in SmallAir cultures. In addition to key mechanistic information relevant for our understanding of the potential health risks associated with AgNP inhalation exposure, this work further highlights the small airway epithelium as an important target for adverse effects.

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Section: Discussionmentioning

confidence: 99%

The small airway epithelium as a target for the adverse pulmonary effects of silver nanoparticle inhalation

et al. 2018

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“…However, A549 cells are not ideal to study the lower airway epithelium, as these are carcinoma lines that are distinct from primary alveolar type II (ATII) cells, and do not transform into alveolar type I (ATI) cells. [33][34][35] Since HSAEpCs are the primary cells of the lower airway epithelium, 36 we first studied the morphology of their 2D and 3D cultures, both ALI-exposed, using H&E staining. We found that the 2D-cultured HSAEpCs formed a non-uniform layer, with occasional cell clustering ( Fig.…”

Section: Effect Of Culture Conditions On Hsaepc Morphology and Phenotypementioning

confidence: 99%

A Three-Dimensional Human Tissue-Engineered Lung Model to Study Influenza A Infection

Bhowmick

Derakhshan

Liang

et al. 2018

Tissue Engineering Part A

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Influenza A virus (IAV) claims ∼250,000-500,000 lives annually worldwide. Currently, there are a few in vitro models available to study IAV immunopathology. Monolayer cultures of cell lines and primary lung cells (two-dimensional [2D] cell culture) is the most commonly used tool, however, this system does not have the in vivo-like structure of the lung and immune responses to IAV as it lacks the three-dimensional (3D) tissue structure. To recapitulate the lung physiology in vitro, a system that contains multiple cell types within a 3D environment that allows cell movement and interaction would provide a critical tool. In this study, as a first step in designing a 3D-Human Tissue-Engineered Lung Model (3D-HTLM), we describe the 3D culture of primary human small airway epithelial cells (HSAEpCs) and determined the immunophenotype of this system in response to IAV infections. We constructed a 3D chitosan-collagen scaffold and cultured HSAEpCs on these scaffolds at air-liquid interface (ALI). These 3D cultures were compared with 2D-cultured HSAEpCs for viability, morphology, marker protein expression, and cell differentiation. Results showed that the 3D-cultured HSAEpCs at ALI yielded maximum viable cells and morphologically resembled the in vivo lower airway epithelium. There were also significant increases in aquaporin-5 and cytokeratin-14 expression for HSAEpCs cultured in 3D compared to 2D. The 3D culture system was used to study the infection of HSAEpCs with two major IAV strains, H1N1 and H3N2. The HSAEpCs showed distinct changes in marker protein expression, both at mRNA and protein levels, and the release of proinflammatory cytokines. This study is the first step in the development of the 3D-HTLM, which will have wide applicability in studying pulmonary pathophysiology and therapeutics development.

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“…Also, a lung cancer diagnosis is possible with helping 4 methods with the names of radiological, non-radiological imaging such as MRI, endoscopic, and biochemical methods [115]. As usual, diagnosis, type, and degree of lung cancer are performed by CNTs scan imaging [116,117]. But, unfortunately, too low-dose CNT scans may bring falsepositive answers about having lung cancer [118].…”

Section: Carbon Nanotubes Based Biosensorsmentioning

confidence: 99%

Gas and Biosensors Made from Metal Oxides Doped with Carbon Nanotubes

Vm¹

2021

PSBJ

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Excellent physical properties of carbon nanotubes (CNTs) are used for the manufacturing many electronic devices. The single wall version of CNTs is promising for the detection of many important gases including gases exhaled by the living organism.The most promising is the realization of gas sensors based on metal oxides doped with CNTs. Application of CNT-based sensors to breath analysis, properties of the SWCNTs gas sensors with metal nanoparticles and metal oxides, and CNTs biosensors are reviewed in this paper.

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Effect of surface functionalizations of multi-walled carbon nanotubes on neoplastic transformation potential in primary human lung epithelial cells

Cited by 21 publications

References 56 publications

The small airway epithelium as a target for the adverse pulmonary effects of silver nanoparticle inhalation

The small airway epithelium as a target for the adverse pulmonary effects of silver nanoparticle inhalation

A Three-Dimensional Human Tissue-Engineered Lung Model to Study Influenza A Infection

Gas and Biosensors Made from Metal Oxides Doped with Carbon Nanotubes

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