Implementation of a Dynamic Co-Culture Model Abated Silver Nanoparticle Interactions and Nanotoxicological Outcomes In Vitro.

Nicholas J Braun,Kristen A Krupa,Maggie E Jewett,Rachel M Galaska

doi:10.3390/nano11071807

Nicholas J Braun, Kristen A Krupa + Show 2 more

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https://doi.org/10.3390/nano11071807

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Abstract

The incorporation of engineered nanoparticles (NPs) into everyday consumer goods, products, and applications has given rise to the field of nanotoxicology, which evaluates the safety of NPs within biological environments. The unique physicochemical properties of NPs have made this an insurmountable challenge, as their reactivity and variable behavior have given rise to discrepancies between standard cell-based in vitro and animal in vivo models. In this study, enhanced in vitro models were generated that retained the advantages of traditional cell cultures, but incorporated the modifications of (1) inclusion of an activated immune element and (2) the presence of physiologically-relevant dynamic flow. Following verification that the human alveolar epithelial and macrophage (A549/U937) co-culture could be successfully sustained under both static and dynamic conditions, these cultures, in addition to a standard A549 static model, were challenged with 10 nm citrate coated silver NPs (AgNPs). This work identified a reshaping of the AgNP-cellular interface and differential biological responses following exposure. The presence of dynamic flow modified cellular morphology and reduced AgNP deposition by approximately 20% over the static exposure environments. Cellular toxicity and stress endpoints, including reactive oxygen species, heat shock protein 70, and secretion of pro-inflammatory cytokines, were found to vary as a function of both cellular composition and flow conditions; with activated macrophages and fluid flow both mitigating the severity of AgNP-dependent bioeffects. This work highlights the possibility of enhanced in vitro systems to assess the safety of engineered NPs and demonstrates their effectiveness in elucidating novel NP-cellular interactions and toxicological profiles.

Highlights

Due to their distinctive physicochemical properties, nanoparticles (NPs) have been incorporated into hundreds of consumer, medical, industrial, and military products and applications
Extensive material necesnecessary as the unique physicochemical properties of characterization each NP set arewas able to dictate b sary as the unique physicochemical properties of each set are able to dictate both the transmission electron microscopy (TEM) a the nano-cellular interface and subsequent toxicological profile
As seen from TEM analysis ysis (Figure 1A) the AgNPs were spherical in morphology and of uniform size distr (Figure 1A) the AgNPs were spherical in morphology and of uniform size distribution

Summary

Introduction

Due to their distinctive physicochemical properties, nanoparticles (NPs) have been incorporated into hundreds of consumer, medical, industrial, and military products and applications. Of all the elemental compositions, silver nanoparticles (AgNPs) have been employed at greater rates than any other material [2]. Due to their robust antibacterial and antimicrobial capabilities, AgNPs have been incorporated into household appliances, bandages, textiles, bioremediation agents, and as a surface coating for electronics and medical devices [3,4]. Owing to their plasmonic properties and high conductivity, AgNPs are integrated into biological sensors, medical diagnostics, drug delivery vehicles, and photocatalysis platforms [5].

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