Exploring the effect of silver nanoparticle size and medium composition on uptake into pulmonary epithelial 16HBE14o-cells

Kettler, Katja; Krystek, Petra; Giannakou, Christina; Hendriks, A. Jan; Jong, Wim H. de

doi:10.1007/s11051-016-3493-z

Cited by 28 publications

(26 citation statements)

References 54 publications

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“…As our studies are performed on the short‐term exposure (24 h) of cells to NPs, this does not resemble the in vivo situation, where upon peritumoral administration of the NPs, the cancer cells will be exposed to the NPs for longer time periods. The 24 h exposure time has been chosen in line with literature, where cellular NP exposure is often 24 h, mainly driven by the fact that for efficient cellular NP uptake, cells should have undergone one cell cycle . As for different cell types, the cell cycle duration can differ quite a bit, a time period of 24 h is chosen as a mean value.…”

Section: Resultsmentioning

confidence: 99%

Presence of an Immune System Increases Anti‐Tumor Effect of Ag Nanoparticle Treated Mice

Manshian

Jiménez

Himmelreich

et al. 2016

Adv Healthcare Materials

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To date, most nanomedical studies rely on the use of immune-deficient mice in which the contribution of the immune system on the applied therapy is ignored. Here, the degradation of silver nanoparticles (Ag NPs) is exploited as a means to treat subcutaneous tumor models in mice. To investigate the impact of the immune system, the same tumor cell type (KLN 205 murine squamous cell carcinoma) is used in a xenograft model in NOD SCIDγ immune-deficient mice and as a syngeneic model in immune-competent DBA/2 mice. The Ag NPs are screened for their cytotoxicity on various cancer cell lines, indicating a concentration-dependent induction of oxidative stress, mitochondrial damage, and autophagy on all cell types tested. At subcytotoxic concentrations, prolonged cellular exposure to the Ag NPs results in toxicity due to NP degradation and the generation of toxic Ag ions. At subcytotoxic conditions, the NPs are found to cause inflammation in vitro. Similar results are obtained in the immune-competent mouse model, where clear inflammation is observed after treatment of the implanted tumors with Ag NPs. This inflammation leads to an ongoing antitumoral effect, which results in a significantly reduced tumor growth compared to Ag NP-treated tumors in an immune-deficient model.

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Section: Resultsmentioning

confidence: 99%

Presence of an Immune System Increases Anti‐Tumor Effect of Ag Nanoparticle Treated Mice

Manshian

Jiménez

Himmelreich

et al. 2016

Adv Healthcare Materials

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“…Accumulating evidence suggests that AgNP-mediated ER stress is responsible for cellular dysfunction and activation of the cell death pathway. We summarize the cellular effects of AgNPs in various cellular systems based on exposure doses, concentration, size of particles, type cell line used, and major outcome of each study in Table 1 [24,38,64,72,105,137,138,139,140,141,142,143,144,145,146,147,148]. …”

Section: Activation Of Signaling Molecules In Response To Agnps Inmentioning

confidence: 99%

Silver Nanoparticle-Mediated Cellular Responses in Various Cell Lines: An in Vitro Model

Zhang

Shen

Gurunathan

2016

IJMS

241

137

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Silver nanoparticles (AgNPs) have attracted increased interest and are currently used in various industries including medicine, cosmetics, textiles, electronics, and pharmaceuticals, owing to their unique physical and chemical properties, particularly as antimicrobial and anticancer agents. Recently, several studies have reported both beneficial and toxic effects of AgNPs on various prokaryotic and eukaryotic systems. To develop nanoparticles for mediated therapy, several laboratories have used a variety of cell lines under in vitro conditions to evaluate the properties, mode of action, differential responses, and mechanisms of action of AgNPs. In vitro models are simple, cost-effective, rapid, and can be used to easily assess efficacy and performance. The cytotoxicity, genotoxicity, and biocompatibility of AgNPs depend on many factors such as size, shape, surface charge, surface coating, solubility, concentration, surface functionalization, distribution of particles, mode of entry, mode of action, growth media, exposure time, and cell type. Cellular responses to AgNPs are different in each cell type and depend on the physical and chemical nature of AgNPs. This review evaluates significant contributions to the literature on biological applications of AgNPs. It begins with an introduction to AgNPs, with particular attention to their overall impact on cellular effects. The main objective of this review is to elucidate the reasons for different cell types exhibiting differential responses to nanoparticles even when they possess similar size, shape, and other parameters. Firstly, we discuss the cellular effects of AgNPs on a variety of cell lines; Secondly, we discuss the mechanisms of action of AgNPs in various cellular systems, and try to elucidate how AgNPs interact with different mammalian cell lines and produce significant effects; Finally, we discuss the cellular activation of various signaling molecules in response to AgNPs, and conclude with future perspectives on research into AgNPs.

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“…If intrinsic properties change after contact of the material to specific environments, this is considered a ‘transformation’ of the nanomaterial, and it is often irreversible. As described by Graham et al (2017), continuous physico-chemical transformations of the nanoparticles, the so-called bio-processing, are observed in biological systems. System-dependent properties are defined as properties that change easily, often reversibly, by the (nano)material during measurement (Luoto et al 1994; Potthoff et al 2015; Kettler et al 2016). The environment may be a specific product matrix, a cell culture medium, the lung-lining fluid, or blood.…”

Section: Introductionmentioning

confidence: 99%

Safety assessment of nanomaterials using an advanced decision-making framework, the DF4nanoGrouping

et al. 2017

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As presented at the 2016 TechConnect World Innovation Conference on 22–25 May 2016 in Washington DC, USA, the European Centre for Ecotoxicology and Toxicology of Chemicals (ECETOC) ‘Nano Task Force’ proposes a Decision-making framework for the grouping and testing of nanomaterials (DF4nanoGrouping) consisting of three tiers to assign nanomaterials to four main groups with possible further subgrouping to refine specific information needs. The DF4nanoGrouping covers all relevant aspects of a nanomaterial’s life cycle and biological pathways: intrinsic material properties and system-dependent properties (that depend upon the nanomaterial’s respective surroundings), biopersistence, uptake and biodistribution, and cellular and apical toxic effects. Use, release, and exposure route may be applied as ‘qualifiers’ to determine if, e.g., nanomaterials cannot be released from products, which may justify waiving of testing. The four main groups encompass (1) soluble, (2) biopersistent high aspect ratio, (3) passive, and (4) active nanomaterials. The DF4nanoGrouping foresees a stepwise evaluation of nanomaterial properties and effects with increasing biological complexity. In case studies covering carbonaceous nanomaterials, metal oxide, and metal sulfate nanomaterials, amorphous silica and organic pigments (all nanomaterials having primary particle sizes below 100 nm), the usefulness of the DF4nanoGrouping for nanomaterial hazard assessment was confirmed. The DF4nanoGrouping facilitates grouping and targeted testing of nanomaterials. It ensures that sufficient data for the risk assessment of a nanomaterial are available, and it fosters the use of non-animal methods. No studies are performed that do not provide crucial data. Thereby, the DF4nanoGrouping serves to save both animals and resources.

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Exploring the effect of silver nanoparticle size and medium composition on uptake into pulmonary epithelial 16HBE14o-cells

Cited by 28 publications

References 54 publications

Presence of an Immune System Increases Anti‐Tumor Effect of Ag Nanoparticle Treated Mice

Presence of an Immune System Increases Anti‐Tumor Effect of Ag Nanoparticle Treated Mice

Silver Nanoparticle-Mediated Cellular Responses in Various Cell Lines: An in Vitro Model

Safety assessment of nanomaterials using an advanced decision-making framework, the DF4nanoGrouping

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