Toward a systematic exploration of nano-bio interactions

Bai, Xue; Liu, Fang; Liu, Yin; Li, Cong; Wang, Shenqing; Zhou, Hongyu; Wang, Wenyi; Zhu, Hao; Winkler, David A.; Yan, Bing

doi:10.1016/j.taap.2017.03.011

Cited by 51 publications

(44 citation statements)

References 107 publications

(133 reference statements)

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“…How nanomaterials interact with biological systems has become an important and complex issue in terms of both the research and regulatory options. When nanomaterials encounter biomolecules or cells, their physicochemical properties have a major impact on the degree to which the material adversely perturbs biological systems [32,33]. Nano-bio interactions may also be affected by the properties of different cell types, the biological environment, and the assay methods applied, making the issues more complicated.…”

Section: Alternative Testing Strategy For Nanomaterialsmentioning

confidence: 99%

“…Nano-bio interactions may also be affected by the properties of different cell types, the biological environment, and the assay methods applied, making the issues more complicated. A thorough understanding of the mechanisms regarding nanomaterials-induced perturbation in biological systems such as autophagy induction is critical for a more comprehensive elucidation of nanotoxicity [33,34].…”

Section: Alternative Testing Strategy For Nanomaterialsmentioning

confidence: 99%

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The Current Understanding of Autophagy in Nanomaterial Toxicity and Its Implementation in Safety Assessment-Related Alternative Testing Strategies

Chen

Liao

et al. 2020

IJMS

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Nanotechnology has rapidly promoted the development of a new generation of industrial and commercial products; however, it has also raised some concerns about human health and safety. To evaluate the toxicity of the great diversity of nanomaterials (NMs) in the traditional manner, a tremendous number of safety assessments and a very large number of animals would be required. For this reason, it is necessary to consider the use of alternative testing strategies or methods that reduce, refine, or replace (3Rs) the use of animals for assessing the toxicity of NMs. Autophagy is considered an early indicator of NM interactions with cells and has been recently recognized as an important form of cell death in nanoparticle-induced toxicity. Impairment of autophagy is related to the accelerated pathogenesis of diseases. By using mechanism-based high-throughput screening in vitro, we can predict the NMs that may lead to the generation of disease outcomes in vivo. Thus, a tiered testing strategy is suggested that includes a set of standardized assays in relevant human cell lines followed by critical validation studies carried out in animals or whole organism models such as C. elegans (Caenorhabditis elegans), zebrafish (Danio rerio), and Drosophila (Drosophila melanogaster)for improved screening of NM safety. A thorough understanding of the mechanisms by which NMs perturb biological systems, including autophagy induction, is critical for a more comprehensive elucidation of nanotoxicity. A more profound understanding of toxicity mechanisms will also facilitate the development of prevention and intervention policies against adverse outcomes induced by NMs. The development of a tiered testing strategy for NM hazard assessment not only promotes a more widespread adoption of non-rodent or 3R principles but also makes nanotoxicology testing more ethical, relevant, and cost- and time-efficient.

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Section: Alternative Testing Strategy For Nanomaterialsmentioning

confidence: 99%

Section: Alternative Testing Strategy For Nanomaterialsmentioning

confidence: 99%

The Current Understanding of Autophagy in Nanomaterial Toxicity and Its Implementation in Safety Assessment-Related Alternative Testing Strategies

Chen

Liao

et al. 2020

IJMS

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“…Integration of omics with the toxicity of a substance is called toxicogenomics and bridges molecular and cellular effects (NRC 2005;Sahu et al 2015;George et al 2010). Capturing dysfunctions at a molecular level allows omics technologies to trace adverse effects at low doses including early and subclinical effects that traditional in vitro and in vivo studies may overlook (Kawata, Osawa and Okabe 2009;Bai et al 2017). Toxicokinetics models (Figure 1, center) such as Physiologically Based Pharmaco-Kinetic models (PBPK) and Physiologically Based Dose Response (PBDR) models enable in vitro-to-in vivo and in vivo-tohuman extrapolation of observations (Judson et al 2011;Li and Reineke 2012;Raies and Bajic 2016;Carlander et al 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Although toxicity has been observed with a variety of NPs to variable extents and outcomes, how the specific physicochemical properties of different NPs and cellular properties of exposed systems relate to adverse effects is not comprehensively understood. The availability of data surrounding the interaction between biological systems and NPs is still relatively limited as compared to other chemical compounds (Bai et al 2017). Dealing with the variety of NPs physicochemical properties, routes of exposures, dosimetry, and their multiple effects on biological systems means that Machine Learning (ML) tools are particularly well suited toward the prediction of biological effects based on NPs properties (Winkler et al 2013;Marvin et al 2017;Sizochenko et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Application of Bayesian networks in determining nanoparticle-induced cellular outcomes using transcriptomics

et al. 2019

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Inroads have been made in our understanding of the risks posed to human health and the environment by nanoparticles (NPs) but this area requires continuous research and monitoring. Machine learning techniques have been applied to nanotoxicology with very encouraging results. This study deals with bridging physicochemical properties of NPs, experimental exposure conditions and in vitro characteristics with biological effects of NPs on a molecular cellular level from transcriptomics studies. The bridging is done by developing and implementing Bayesian Networks (BNs) with or without data preprocessing. The BN structures are derived either automatically or methodologically and compared. Early stage nanotoxicity measurements represent a challenge, not least when attempting to predict adverse outcomes and modeling is critical to understanding the biological effects of exposure to NPs. The preprocessed data-driven BN showed improved performance over automatically structured BN and the BN with unprocessed datasets. The prestructured BN captures inter relationships between NP properties, exposure condition and in vitro characteristics and links those with cellular effects based on statistic correlation findings. Information gain analysis showed that exposure dose, NP and cell line variables were the most influential attributes in predicting the biological effects. The BN methodology proposed in this study successfully predicts a number of toxicologically relevant cellular disrupted biological processes such as cell cycle and proliferation pathways, cell adhesion and extracellular matrix responses, DNA damage and repair mechanisms etc., with a success rate >80%. The model validation from independent data shows a robust and promising methodology for incorporating transcriptomics outcomes in a hazard and, by extension, risk assessment modeling framework by predicting affected cellular functions from experimental conditions.

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“…Recently, some progresses have been made using omics to investigate protein corona on ENM surfaces 11 , examine ENM-induced cell signaling changes 12, 13 , define the routes of ENM trafficking 14 , decipher cytotoxicity mechanisms 15 , etc . However, so far, no attempts have been made for nano-SAR assessments 16 . Since proteins and metabolites are the executors or end products of signaling pathways and multi-omics analyses offer a better view of the global biological changes 17 , we hypothesized that multi-hierarchical nano-SAR assessments could be achieved via coupling of proteomics and metabolomics analyses.…”

mentioning

confidence: 99%

Multi-hierarchical Profiling the Structure-Activity Relationships of Engineered Nanomaterials at Nano-Bio Interfaces

Cai¹,

Dong

Liu

et al. 2018

Preprint

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Increasingly raised concerns (nanotoxicity, clinical translation, etc) on nanotechnology require breakthroughs in structure-activity relationship (SAR) analyses of engineered nanomaterials (ENMs) at nano-bio interfaces. However, current nano-SAR assessments failed to disclosure sufficient information to understand ENM-induced bio-effects. Here we developed a multi-hierarchical nano-SAR assessment for a representative ENM, Fe2O3 by systematically examining cellular metabolite and protein changes. This nano-SAR profile allows visualizing the contributions of 7 basal properties of Fe2O3 to their diverse bio-effects. For instance, while surface reactivity is responsible for Fe2O3-induced cell migration, the inflammatory effects of Fe2O3 nanorods and nanoplates are determined by their aspect ratio and surface reactivity, respectively. We further discovered the detailed mechanisms, including NLRP3 inflammasome pathway and monocyte chemoattractant protein-1 involved signaling. Both effects were further validated in animal lungs. Our findings provide substantial new insights at nano-bio interfaces, which may facilitate the tailored design of ENMs to endow them with desired bio-effects.

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Toward a systematic exploration of nano-bio interactions

Cited by 51 publications

References 107 publications

The Current Understanding of Autophagy in Nanomaterial Toxicity and Its Implementation in Safety Assessment-Related Alternative Testing Strategies

The Current Understanding of Autophagy in Nanomaterial Toxicity and Its Implementation in Safety Assessment-Related Alternative Testing Strategies

Application of Bayesian networks in determining nanoparticle-induced cellular outcomes using transcriptomics

Multi-hierarchical Profiling the Structure-Activity Relationships of Engineered Nanomaterials at Nano-Bio Interfaces

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